Title of Invention	A METHOD OF WELDING A WORKPIECE AND WELDING APPARATUS THEREOF
Abstract	ORIGINAL ABSTRACT A METHOD OF WELDING A WORKPIECE AND WELDING APPARATUS THEREOF A method of welding a workpiece (WP) the method comprising: advancing a self-shielding electrode (E) from a welding device toward a workpiece (WP); and employing a short arc welding process to weld the workpiece (WP) using the advancing self-shielded electrode (E), wherein the weld has a yield strength of atleast 70 ksi characterized by, applying a waveform (210) across the self-shielding electrode (E) and workpiece (WP) over a time-period (212a, 212a), the waveform comprising a melting pulse (212) and where the melting pulse (212) is followed by a low current transfer cycle (214) and wherein the waveform is positive for a time period (212a, 212a) having a first duration and the amplitude of the positive portion of the 9 waveform is higher than the amplitude of the negative portion of the waveform, or, the waveform is positive for a second duration and the amplitude for a positive portion of the waveform is less than an amplitude of the negative portion of the waveform, and controlling the melting pulse by measuring a duration time between said melting pulse and a short circuit during said transfer cycle (214), setting a desired time for said duration, creating a corrective signal by comparing said measured duration and said set desired time, and adjusting a parameter if said melting pulse based upon said corrective signal. Ref: Figs. 2 and 3 42

Title of Invention

A METHOD OF WELDING A WORKPIECE AND WELDING APPARATUS THEREOF

Abstract

ORIGINAL ABSTRACT A METHOD OF WELDING A WORKPIECE AND WELDING APPARATUS THEREOF A method of welding a workpiece (WP) the method comprising: advancing a self-shielding electrode (E) from a welding device toward a workpiece (WP); and employing a short arc welding process to weld the workpiece (WP) using the advancing self-shielded electrode (E), wherein the weld has a yield strength of atleast 70 ksi characterized by, applying a waveform (210) across the self-shielding electrode (E) and workpiece (WP) over a time-period (212a, 212a), the waveform comprising a melting pulse (212) and where the melting pulse (212) is followed by a low current transfer cycle (214) and wherein the waveform is positive for a time period (212a, 212a) having a first duration and the amplitude of the positive portion of the 9 waveform is higher than the amplitude of the negative portion of the waveform, or, the waveform is positive for a second duration and the amplitude for a positive portion of the waveform is less than an amplitude of the negative portion of the waveform, and controlling the melting pulse by measuring a duration time between said melting pulse and a short circuit during said transfer cycle (214), setting a desired time for said duration, creating a corrective signal by comparing said measured duration and said set desired time, and adjusting a parameter if said melting pulse based upon said corrective signal. Ref: Figs. 2 and 3 42

Full Text	This invention relates to a method of welding a workpiece and welding apparatus thereof. PRIORITY 5 The present application is a continuation-in-part of U.S. Application No. 10/834,141, filed April 29, 2004; a continuation-in-part of U.S. Application No. 10/959,587, filed October 6, 2004; a continuation-in-part of U.S. Application No. 11/263,064, filed October 31, 2005; and a continuation-inpart of U.S. Application No. 11/336,506, filed January 20, 2006, the entire disclosures of which are incorporated herein by reference. • 10 FIELD OF THE INVENTION The present invention relates to the art of electric arc welding and more particularly to an improved short arc welding system, methods of welding with self-shielding flux cored arc welding (FCAW-S) electrodes, and the composition of the electrodes. BACKGROUND 15 Presently, there are no conmiercial solutions or methods for semi-automatically, circumferentially, welding high strength pipes and pipelines with a gas-less or self-shielding welding process. This is because the traditional technologies used for gas-less or self-shielding welding " applications have in high strength welding applications. In using gas-less or self-shielding welding electrodes various chemicals are used in the electrode 20 to react with the oxygen and nitrogen in the atmosphere to keep these components out of the weld. These chemicals are used in such a quantity so as to sufficiently prevent the oxygen or nitrogen from deteriorating the weld quality. However, while these chemicals, such as titanium and aluminum, make the welds stronger, they also have the adverse effects of making the welds brittle. This brittleness prevents gas-less or self-shielding welding methods from being used in many high strength welding - 2 - 25 applications, such as pipeline welding, in which it is often required that the weld strength be sufficient to satisfy the requirements for welding American Petroleum Institute (API) Grade X-80 line pipe, or higher. Further, although there exists methods for meeting these weld requirements using gas-shielded welding methods, these methods also have drawbacks which make them less than desirable. Namely, current methods and systems for welding high strength pipes and pipelines (along with other applications) 30 using gas-shielding methods require costly and time consuming set ups to protect the welding area from the atmosphere and elements. This is particularly the case in pipeline applications, where the welds are g^ often taking place outside in difficult environmental conditions. INCORPORATION BY REFERENCE The present invention involves using a short arc welding process employing a self-shielding cored 35 electrode which is capable of satisfying the requirements for welding American Petroleum Institute (API) Grade X-80 line pipe, or higher. There is a synergistic relationship when combining the welding process and the flux cored electrode of the present invention. Thus, the present invention combines controlling the energy input along with the microstructure control of the weld metal deposited to achieve highstrength and toughness. Specifically, an exemplary embodiment of the present invention can achieve over 40 550 MPa yield strength and 690 MPa tensile strength, and a Charpy V-Notch (CVN) toughness of over w 60 Joules at -20 degrees C. Short-circuit arc welding systems, techniques, and associated concepts, as well as pipe welding methods and apparatuses are generally set forth in the following United States patents, the contents of which are hereby incorporated by reference as background information: Parks 4,717,807; Parks 45 4,954,691; Parker 5,676,857; Stava 5,742,029; Stava 5,961,863; Parker 5,981,906; Nicholson 6,093,906; Stava 6,160,241; Stava 6,172,333; Nicholson 6,204,478; Stava 6,215,100; Houston 6,472,634; and Stava 6,501,049. 3 The electric arc welding field uses a variety of welding processes between the end of a consumable advancing electrode and a workpiece, which workpiece may include two or more 50 components to be welded together. An embodiment of the present invention relates to the short arc process where the advancing electrode is melted by the heat of the arc during a current pulse and then, after the molten metal forms into a ball by surface tension action, the molten metal ball is transferred to the workpiece by a short circuit action. The short circuit occurs when the advancing wire moves the ball I into contact with the molten metal puddle on the workpiece, which short is sensed by a plunge in the 55 welding voltage. Thereafter, the short circuit is broken and the short arc welding process is repeated. The present invention is an improvement in short arc welding and is performed by using a power source where the profile of the welding waveform is controlled by a waveform generator operating a pulse width modulator of a high switching speed inverter, as disclosed in several patents by assignee,, such £is shown in Parks 4,866,247; Blankenship 5,278,390; and, Houston 6,472,634, each of which is hereby 60 incorporated by reference. These three patents illustrate the type of high switching speed power source employed for practicing an exemplary embodiment of the present invention and are incorporated herein as background technology. A waveform of the waveform generator is stored in memory as a state table, which table is selected and outputted to the waveform generator in accordance with standard technology pioneered by The Lincoln Electric Company of Cleveland, Ohio. Such selection of a table for creating ^ r 65 the waveform profile in the waveform generator is disclosed in several prior art patents, such as the previously mentioned Blankenship 5,278,390. Consequently, a power source used in practicing the present invention is now commonly known and constitutes background technology used in the present invention. An aspect of the short arc welding system of the present invention employs a circuit to determine the total energy of the melting pulse forming the molten metal ball of the advancing electrode, 70 such as described in Parks 4,866,247. The total energy of the melting pulse is sensed by a watt meter having an integrated output over the time of the melting pulse. This technology is incorporated by reference herein since it is employed in one aspect of the present invention. After a short has been created 4 in a short arc welding system, the short is cleared by a subsequent increase in the welding current. Such procedure is well known in short arc welding systems and is described generally in Ihde 6,617,549 and in 75 Parks 4,866,247. Consequently, the technology described in Ihde 6,617,549 is also incorporated herein as background technology. An exemplary embodiment of the present invention is a modification of a standard AC pulse welding system known in the welding industry. A prior pending application of assignee describes standard pulse welding, both DC and AC, with an energy measurement circuit or program for a high frequency switching power source of the type used in practicing an exemplary AC 80 short circuit implementation of the present invention. Although not necessary for understanding the present invention or practicing the present invention, this prior application, which is Serial No. 11/103,040 filed April 11, 2005, is incorporated by reference herein. The present invention relates to a cored electrode and a short arc welding system, and method, for controlling the melting pulse of the system for depositing a special cored electrode so no shielding gas is 85 needed, which is capable of satisfying the requirements for welding American Petroleum Institute (API) Grade X-80 line pipe, or higher. The system and method maintains a desired time between the pulse and the actual short circuit. This time is controlled by a feedback loop involving a desired timing of the short circuit and the pulse, so that the size of the ball of the pulse is varied to maintain a consistent short circuit timing. This process is a substantial improvement of other short arc control arrangements, such as 90 disclosed in Pijls 4,020,320 using two power sources. A first source maintains a constant size melting pulse and there is a fixed time between the short circuit and the subsequent clearing pulse. There is no feedback between the pulsed timing and a parameter of the melting pulse, as employed in the present invention. A desired time is maintained between the end of the melting pulse and the short circuit event. By fixing the desired time using a feedback loop concept, arc stability is improved. This invention is 95 applicable to a DC process, as shown in Pijls 4,020,320, but is primarily advantageous when using an AC short arc welding system. Consequently, Pijls 4,020,320 is incorporated by reference herein as 5 I background technology showing a control circuit for a DC short arc system wherein two unrelated timings are maintained constant without a closed loop control of the melting pulse. The present invention fiirther involves a welding method employing a flux cored, i.e. self- 100 shielding, electrode or welding wire. Details of arc welding electrodes or wires and specifically, cored electrodes for welding are provided in U.S. Patents 5,369,244; 5,365,036; 5,233,160; 5,225,661; 5,132,514; 5,120,931; 5,091,628; 5,055,655; 5,015,823; 5,003,155; 4,833,296; 4,723,061; 4,717,536; 4,551,610; and 4,186,293; all of which are hereby incorporated by reference. W Also, prior applications filed September 8, 2003 as Serial No. 10/655,685; filed April 29, 2004 as 105 Serial No. 10/834,141; filed October 6, 2004 as Serial No. 10/959,587; and filed October 31, 2005 as Serial No. 11/263,064 are each incorporated by reference as background, non-prior art technology. SUMMARY OF THE PRESENT INVENTION The present invention is directed to a system and method for addressing the problems discussed above and providing a system and method which is capable of creating a weld which satisfies the 110 requirements for welding American Petroleum Institute (API) Grade X-80 line pipe, or higher. Specifically, an exemplary embodiment of the present invention can achieve over 550 MPa yield strength ^ and 690 MPa tensile strength, and a Charpy V-Notch (CVN) toughness of over 60 Joules at -20 degrees C. The system and method of the present invention controls the welding arc through a specialized 115 power source to minimize the arc length coupled with the use of a cored, i.e. self-shielded, electrode to achieve the desired welding attributes. The use of the short arc minimizes the contamination fi-om the atmosphere in the weld pool, thus improving toughness, while at the same time being more resistant to porosity during welding. Further, the use of the short arc length allows for the use of a self-shielding electrode, according to an embodiment of the present invention, which contains a composition according 120 to an aspect of the present invention, discussed fiirther below. Additionally, with the present invention, 6 there is no need to use additional shielding gas to achieve a weld which satisfies the requirements for welding American Petroleum Institute (API) Grade X-80 line pipe, or higher, and/or over 550 MPa yield strength and 690 MPa tensile strength, and a Charpy V-Notch (CVN) toughness of over 60 Joules at -20 degrees C. 125 In accordance with a first aspect of the present invention as it relates to the method, the melting pulse of the short arc waveform is controlled interactively by a feedback loop and not by fixing constant values of the melting pulse. The time between the end of the melting pulse and the short circuit is ^ maintained by reactively changing parameters of the melting pulse in a short arc welding system. In one exemplary embodiment of the invention the system is an AC system, but can be used in a DC system of 130 the type generally described in Pijls 4,020,320. Manipulation of the short arc waveform is facilitated by using a single power source having the waveform controlled by a waveform generator operating the pulse width modulator of a high switching speed inverter, such as disclosed in Houston 6,472,634. One advantage realized by implementation of the present invention is an improvement over short arc welding using two separate power sources, as shown in the prior art. 135 In accordance with another embodiment of the first aspect of the present invention, the short arc welding system is an AC system wherein the melting pulse has a negative polarity. To maintain a ^ ^ constant molten metal bead, there is a joule threshold switch to shift the power supply to a low level positive current so the molten metal on the end of the advancing electrode forms into a ball and then short circuits against the workpiece weld puddle. In an embodiment, this AC waveform is controlled by a 140 waveform generator controlling the profile of the individual current segments of the waveform and determining the polarity of the waveform segments. In the prior art, a joule threshold switch was used to provide a constant energy to the melting pulse. In accordance with an embodiment of the present invention, there is a timer to measure the time for the electrode to short after the melting pulse. A feedback loop is employed to maintain a consistent time between the mehing pulse and the short circuit 145 event. This control of time stabilizes the arc and the shorting cycle. In one embodiment of the present 7 invention, the time between the melting pulse and the short is about 1.0 ms. Depending upon the electrode size and deposition rate, the time between the melting pulse and the short circuit event may be adjusted to a fixed value in the general range of 0.5 ms to 2.0 ms. Control of the timing is typically applicable to AC short arc welding; however, the same concept is applicable to straight DC positive 150 polarity. In both instances, the advancing wire with molten metal formed by the melting pulse is held at a low quiescent positive current facilitating the formation of a ball preparatory to the short circuit event. In either implementation of the invention, the joules or other parameter of the melting pulse is controlled by a feedback loop conditioned to maintain a preset time to the short circuit event. The AC implementation of the first aspect of the present invention is usefiil for tubular electrodes 155 of the flux cored type and one embodiment is implimented with a flux core electrode with alloy ingredients in the core according to an aspect of the present invention, discussed further below. Control of the melting cycle of a flux cored electrode based upon feedback from the short circuit time is a very precise procedure to maintain stability of the AC short circuit welding process. In view of the foregoing, an embodiment the present invention may be used to weld pipe with a cored, i.e. self-shielding, electrode 160 according to an embodiment of the present invention. The welding current for such electrode, when using a method of the present invention, is below the threshold current for spray welding. Thus, the metal ^ ^ transfer to the pipe joint must involve some type of short circuit, and in an embodiment of the present invention will involve a globular short circuit transfer of the type to which the present invention is directed. Improving the weld stability by using AC short arc welding still may result in instability of the 165 arc. This instability has been overcome by implementing the present invention. Thus, the present invention is particularly applicable to AC short arc welding of a pipe joint using a self-shielding cored electrode, so that the weld strength satisfies the requirements for welding American Petroleum Institute (API) Grade X-80 line pipe, or higher. In accordance with an embodiment of the present invention, there is provided a welding system 170 for performing a short arc welding process between an advancing wire electrode and a workpiece, where 8 I the system comprises a power source with a controller for creating a current pulse introducing energy into the electrode to melt the end of the electrode and a low current quiescent metal transfer section allowing the melted metal on the end of the electrode to be deposited into the weld puddle of the workpiece. During the low current metal transfer section, the molten metal short circuits against the molten metal 175 puddle. A timer measures the actual time between the end of the melting pulse and the short circuit event. A device is used to set a desired time between the pulse and short circuit event and a circuit is used to create a corrective signal based upon the difference between the actual time and the desired time. This corrective signal is used to control a given parameter of the melting pulse, such as the total energy introduced into the wire during the melting pulse. 180 In accordance with an exemplary embodiment of the first aspect of the present invention, the short arc welding process is an AC process wherein the melting pulse is performed with a negative current and the quiescent low current metal transfer section of the waveform is at a positive polarity. The AC version of the present invention is applicable for welding with a flux cored electrode in several environments, such as the root pass of a pipe welding joint. 185 In accordance with another aspect of the power source of the present invention, the controller of the short arc welding system includes a circuit to create a short circuit clearing pulse after the short ^k circuit. In this embodiment of the power source a waveform generator determines the polarity and profile of the welding waveform at any given time. The welding system of the present invention is used to maintain the time between the melting pulse and the short at a fixed value, which fixed value is in the 190 general range 0.5-2.0 ms and, in another embodiment is approximately 1.0 ms. In accordance with another aspect of the power source or method performed by the power source, the short arc system is performed DC positive with both the melting pulse and the quiescent section being positive and followed by a short circuit positive clearing pulse. This implementation of the present invention does not involve a polarity change from the waveform generator during the processing of the 9 • I 195 waveform to practice the short arc welding process. The short arc welding system is AC and there is a circuit to control the current pulse for causing the actual time between the melting pulse and short circuit so it is the same as the desired time. This embodiment of the present invention maintains a constant time, as does other embodiments of the present invention. One embodiment of the present invention controls the energy of the melting pulse to control the 200 time between the melting pulse and the ultimate short circuit event. Yet another aspect of the first aspect of the invention is the provision of a method for controlling Wf the melting pulse of a short arc welding process so that the process has a selected time between the melting pulse and the short circuit event. The parameter controlled by this method is the total energy of the melting pulse. This embodiment of the present invention may be used in the root pass of a circular 205 open root pipe joint using a flux cored electrode. A second aspect of the invention relates at least in part, to utilizing a relatively short arc length during AC welding as obtained by the described short arc method, which results in contamination of the weld fi-om the atmosphere being significantly reduced. This embodiment of the invention also utilizes a particular flux alloy system, which when used in an electrode along with this aspect of the invention, can 210 achieve beneficial results. The flux/alloy system of the cored electrode enables and promotes a short arc ^ length. Combining these aspects in accordance with an embodiment of the present invention, provides a synergistic phenomenon which produces a sound and tough weld metal with strength of over 60 to 70 ksi, and in another embodiment have a yield strength of at least 80 ksi, thus providing a weld which satisfies the requirements for welding American Petroleum Institute (API) Grade X-80 line pipe, or higher. 215 Further, an exemplary embodiment of the present invention can achieve over 550 MPa yield strength and 690 MPa tensile strength, and a Charpy V-Notch (CVN) toughness of over 60 Joules at -20 degrees C. Moreover, alloys, as used in embodiments of the present invention, allow use of thiimer pipes and there is no need for shielding gas in the pipe welding area. 10 I Waveform technology, as pioneered by The Lincoln Electric Company of Cleveland, Ohio, has 220 been modified for use in AC welding with flux cored electrodes. Cored electrodes allow the welding operation to be more precisely controlled with the alloy of the weld bead being tailored to the desired mechanical characteristics for the bead and with the position of the welding operation being less limited. However, to provide arc stability and appropriate melting temperatures and rates, the actual control of the waveform for the AC process is quite complicated. Contamination of the weld metal during arc welding 225 is still a problem using AC welding for cored electrodes. Contaminants, in the weld metal after the welding operation can cause porosity, cracking and other types of defects in the weld metal. Consequently, a major challenge confronting designers of arc welding processes has been to develop techniques for excluding elements, such as contaminants from the atmosphere, from the arc environment or for neutralizing the potentially harmfiil effects of such impurities. The potential source of 230 contamination, includes the materials that comprise the welding electrode, impurities in the workpiece itself and ambient atmosphere. Cored electrodes may contain "killing" agents, such as aluminum, magnesium, zirconium and titanium which agents combine chemically with potential contaminates to prevent them from forming porosity and harmfiil inclusion in the weld metal. The present invention involves the use of an elecfrode composition that reduces the tendency of a cored electrode to allow 235 inclusion of contaminants in the weld metal. The method also reduces the amount of material required as W a "killing" agent. Specifically, the present invention provides a self-shielded flux cored arc welding (FCAW-S) electrode particularly adapted for forming welds having reduced levels of contaminants using an AC waveform. The electrode has an alloy/flux system comprising from about 35 to about 55% barium 240 fluoride, from about 2 to about 12% lithium fluoride, from about 0 to about 15% lithium oxide, from about 0 to about 15% barium oxide, from about 5 to about 20% iron oxide, and up to about 25% of a deoxidation and denitriding agent. This agent can be selected from aluminum, magnesium, titanium, zirconium, and combinations thereof 11 The present invention provides a method of arc welding using a self-shielded flux cored electrode 245 that utilizes a particular alloy/flux system. The method comprises applying a first negative voltage between an electrode and a substrate to cause at least partial melting of the electrode proximate the substrate. The method also comprises applying a positive voltage between the electrode and the substrate to promote formation of a flowable mass of material from the electrode. The method flirther comprises monitoring for occurrence of an electrical short between the electrode and the substrate through the 250 flowable mass. The method further comprises upon detecting an electrical short, applying a second negative voltage between the electrode and the substrate. And, the method comprises increasing the magnitude of the second negative voltage, to thereby clear the electrical short and form a weld on the substrate from the flowable mass. The self-shielded flux cored electrode can comprise from about 35 to about 55% barium fluoride, from about 2 to about 12% lithium fluoride, from about 2 to about 15% 255 lithium oxide, from about 5 to about 20% iron oxide, and up to about 25% of a deoxidation and denitriding agent selected from the group consisting of aluminum, magnesium, titanium, zirconium, and combinations thereof An object of the present invention is the provision of a short arc welding system, which system j controls the spacing of the short circuit events during the process, especially when the process is ^^260 performed in the AC mode, to provide a weld which satisfies the requirements for welding at least American Petroleum Institute (API) Grade X-80 line pipe. Another object of the present invention is the provision of a method for short arc welding, which method controls the melting pulse based upon the time between the melting pulse and short so this time remains fixed at a desired value. 265 Yet another object of the present invention is the provision of an improved electrode composition, and particularly an electrode fill composition which is particularly adapted for use in combination with the novel short arc welding system and method. 12 A further object of the present invention is to provide a synergistic system comprising a short arc process and flux cored electrode to stabilize the arc at the shortest possible arc length. Thus, the 270 contamination from the atmosphere is minimized. The combination of an alloy system and a weld process allows the arc to be stable at such short arc lengths and result in a sound and tough weld metal. One embodiment of the invention can provide a weld, without the use of gas-shielding, having a yield strength of at least 80 ksi, thus providing a weld which satisfies the requirements for welding American Petroleum Institute (API) Grade X-80 line pipe, or higher. Further, an exemplary embodiment of the 275 present invention can achieve over 550 MPa yield strength and 690 MPa tensile strength, and a Charpy VNotch (CVN) toughness of over 60 Joules at -20 degrees C. These and other objects and advantages will become apparent from the following description taken together with the accompanying drawings. BRIEF DESCRIPTION OF DRAWINGS 280 The advantages, nature and various additional features of the invention will appear more fully upon consideration of the illustrative embodiment of the invention which is schematically set forth in the figures, in which: ^ FIGURE 1 is a block diagram of a short arc welding system used in an exemplary embodimerit of the present invention; 285 FIGURE 1A is an enlarged cross-sectional view taken generally along line lA-1 A of FIGURE 1; FIGURE 2 is a series of side elevational views showing the stages I-IV in a short arc welding process; FIGURE 3 is a combined current and voltage waveform graph showing the waveform implementing an embodiment of the present invention as disclosed in FIGURE 4 for the various stages as 290 shown in FIGURE 2; 13 I FIGURE 4 is a flow chart block diagram illustrating a modification of the system in FIGURE 1 to perform the embodiment of the present invention; FIGURES 5 and 6 are flow chart block diagrams of a portion of the welding system shown in FIGURE I for implementing two further embodiments of the present invention 295 FIGURES 7 and 8 are partial flow chart block diagrams of the welding system as shown in FIGURE 1 combining the embodiment of the present invention shown in FIGURE 4 with a combined waveform control from the embodiments of the invention shown in FIGURES 5 and 6, respectively; FIGURE 9 is a current waveform for the DC positive implementation of the present invention; FIGURE 10 is a schematic elevational view showing the invention used in the root pass or 300 tacking pass of a pipe welding joint; FIGURE 11 is a side elevational view with a block diagram illustrating the use of a representative welding system and an electrode; FIGURE 12 is an enlarged cross-sectioned pictorial view taken generally along line 12-12 of FIGURE 11, depicting the electrode in greater detail; ^^305 FIGURE 13 is an enlarged, schematic view representing a cored electrode where the sheath and core are melted at different rates; FIGURE 14 is a view similar to FIGURE 13 illustrating a disadvantage of a failure to employ a tailored waveform for welding with cored electrodes; FIGURE 15 is a view similar to FIGURES 13 and 14; 310 FIGURE 16 is a partial, side elevational view illustrating a cored electrode in accordance with an embodiment of the present invention and showing the arc length, which length is minimized by use of the present invention; 14 FIGURE 17 shows the influence of wave balance and DC offset on weld metal nitrogen recovery in an example of the present invention; and 315 FIGURE 18 depicts the joint design of an example weld performed in accordance with an exemplary embodiment of the present invention. EXEMPLARY EMBODIMENTS OF THE INVENTION In the electric arc welding industry, short arc welding is a common practice and involves the four stages I, II, III and IV as schematically disclosed in FIGURE 2. The power source for performing short 320 arc welding can be a transformer based power source; however, in accordance with an exemplary embodiment of the present invention, system A, shown in FIGURE 1, utilizes a high switching speed inverter based power source B having an AC supply across lines 10, 14, or a three phase supply, directed to inverter 14 creating a first DC signal across lines 14a, 14b. In accordance with standard architecture, boost or buck converter 20 is used in power source B for correcting the input power factor by creating a 325 controlled second DC signal across output lines 22, 24. High switching speed inverter 30 converts the second DC signal across lines 22, 24 to a waveform created by a large number of current pulses across output leads 32, 34. In accordance with an exemplary embodiment of the present invention, the waveform across leads 32, 34 is either DC positive or AC; therefore, inverter 30 has an output stage, not ^ shown, that dictates the polarity of the profiled waveform across leads 32, 34. These lead^ are connected 330 to electrode E and workpiece WP, respectively. In accordance with standard short arc technology, electrode E is an advancing end of wire W supplied through contact tip 42 Irom supply spool or drum 40. Thus, wire W is driven toward workpiece WP at a given WFS as a controlled waveform having the desired polarity is created across the gap between electrode E and workpiece WP. In an embodiment of the invention, the wire W is a flux cored wire schematically illustrated in FIGURE lA and shown to 335 include an outer low carbon steel sheath 50 surrounding an internal flux core 52 having a fluxing agent 15 and normally including alloying particles, also known as a self-shielded wire or electrode. An embodiment of the electrode will be discussed in more detail below. Shunt 60 drives feedback current device 62 so the voltage signal on line 64 is representative of the instantaneous arc current of the welding process. In a like manner, device 70 creates a signal on 340 output line 72 representative of the instantaneous voltage of the welding process. Controller C of inverter 30 is a digital device, such as a DSP or microprocessor, that performs ftinctions schematically illustrated in generally analog architecture. As a central component of controller C a waveform generator 100 ^ ^ processes a specific waveform from a state table stored in memory unit 102 and selected according to the desired welding process by device or circuit 104. Upon selecting the desired short arc welding process a 345 select signal 104a is directed to memory unit 102 so that the state table defining the attributes and parameters of the desired short arc welding waveform is loaded into waveform generator 100 as indicated by line 102a. Generator 100 outputs the profile of the waveform at any given time on output line 100a with the desired polarity indicated by the logic on line 100b. Illustrated power source B controlled by digital controller C is of the current control feedback type wherein the current representative voltage on 350 line 64 is combined with the waveform profile signal on line 100a by error amplifier 110 having an output signal on line 110a to control pulse width modulator 112 in accordance with standard waveform control technology. The output signal on line 112a controls the shape of the waveform across lines 32, 34 and the polarity of the particular waveform profile being implemented is set by the logic on line 100b. In this manner, waveform generator 100 controls pulse width modulator 112 to have pulses in line 112a 355 controlling the high fi-equency operation of inverter 30. This inverter switching frequency is generally greater than 18 kHz and preferably greater than about 40 kHz. As so far described, power source B with controller C operates in accordance with standard technology pioneered by The Lincoln Electric Company of Cleveland, Ohio. Controller C is digital, but illustrated in analog format. To implement a short arc welding process, it is necessary for controller C to receive feedback information regarding a 360 short circuit condition between electrode E and workpiece WP. This feature of controller C is 16 schematically illustrated as a short circuit detector 120 that creates a logic on line 122 to announce the existence of a short circuit event SC to waveform generator 100. Thus, the generator is informed when there is a short circuit and implements a waveform in accordance with processing a short circuit as accomplished in any short arc welding process. As so far described, controller C is standard technology, 365 with the exception of controlling a polarity switch at the output of inverter 30 by the logic on line 100b. To practice the invention, controller C is provided with a circuit 150 for controlling the melting pulse preparatory to the short circuit. Circuit 150 is digital, but schematically illustrated in analog ^ architecture. The functions are implemented by the digital processor of controller C to control the energy of the melting pulse. Such energy control circuitry is described in prior copending application Serial No. 370 11/103,040 filed by applicant on April 11, 2005. This prior application is incorporated by reference herein not as prior art, but as related technology. As shown in the prior application, the energy of the melting pulse of a pulsed welding waveform can be controlled by circuit 150 including multiplier 152 for multiplying the instantaneous signal on lines 64, 72 to provide a signal on line 154 representing the instantaneous watts of the welding process. The wattage signal or line 154 is accumulated by a standard I 375 integrator 156 as described in Parks 4,866,247. Integration of the watt signal on line 154 is controlled by \| waveform generator 100 that creates a pulse start command shown as block 160 to correspond to the start of the melting pulse indicated by logic on line 162. The starting point is the time ti when the melting pulse is started by waveform generator 100. Output signal on line 164 starts integration of the watt signal on line 154 by integrator 156. The integration process is stopped by a logic on line 170 produced by 380 activation of stop pulse device or circuit 172 upon receipt of logic on input line 172a. Logic on line 172a toggles device 172 to change the logic in output lines 172a and 172c. The logic on line 172c Informs the waveform generator that the melting pulse is to stop to change the profile on output line 100a. At the same time, the signal on line 172b toggles reset device or circuit 174 to change the logic on line 170 to stop integration of the instantaneous watt signal. The digital number on output line 156a is loaded into 385 digital register 180 having an output 182 representing the total energy of a given melting pulse in the 17 i short art welding process. This total energy signal is compared with a desired energy level stored in register 190 to provide a digital number or signal on line 192. Comparator 194 compares the actual energy for a given pulse represented by a number on line 182 with a desired energy level indicated by the number on line 192. The relationship between the actual energy and the desired energy controls the logic 390 on line 172a. When the signal from line 182 equals the signal on line 192, comparator 194 changes the logic on line 172a to stop the pulse as indicated by device or circuit 172. This stops integration and stops the melting pulse being created by waveform generator 100. Circuit 150 is employed for performing an exemplary embodiment of the present invention which changes the reference or desired energy for the melting pulse by changing the number on line 192 through adjustment of circuit 200. The pulse is 395 stopped when the adjusted energy or energy threshold is reached as determined by the number signal on line 182 as compared to the signal on line 192. In an embodiment of the present invention, the power source and method used adjusts circuit 200 to change the reference energy for performing a short arc welding process by changing the melting pulse. Short arc welding system A using power source B with digital controller C is operated by 400 adjusting circuit 200 to perform the waveform shown in FIGURE 3. AC current waveform 200 has a negative melting pulse 212 represented by stage I in FIGURE 2 where the melting pulse produces molten metal 220 on the end of electrode E. The level of current in pulse 212 is below current needed for spray arc so there is a transfer by a short. The time ti starts the Joule measurement, as explained later. The pulse has a start position 212a at time ti and a stop position 212b at time t2. Following the melting pulse, 405 in accordance with standard practice, there is a positive low current quiescent transfer section 214, as represented by stage II of FIGURE 2. In this stage, the molten metal 220 on the end of advancing electrode E is formed into a ball by surface tension action awaiting a short circuit which occurs at time t3 and is shown as stage III. Consequently, the time between t2 and h is the time between the end of the melting pulse and the short circuit event, which time is indicated by the logic on line 122 as shown in 410 FIGURE 1. After stage II, a current pinch action shown as neck 222 separates the molten metal 220 from I J puddle 224. This electrical pinching action shown in stage IV is accelerated in accordance with standard practice by a negative short circuit pulse 216 having a first current section 216a with a steep slope and followed by a second current section 216b with a more gradual slope. Ultimately, the shorted metal separates and the SC logic on line 122 shifts to start the next current pulse at time ti indicated by a 415 transition section 218. Waveform 210 is an AC waveform having a negative melting pulse 212, a low current quiescent section 214 and a clearance pulse 216 transitioning into the next negative pulse 212 at time ti. The corresponding voltage has a waveform 230 with negative section 232, a low level positive section 234 that plunges at short 236 and is followed by a negative voltage section 238 that transitions at section 240 into the next melting pulse voltage 232. The total cycle time is from ti to the next ti and the 420 positive transfer 214 has a time less than 20% of the total cycle time. This prevents stubbing. The present invention involves a power source and method for controlling waveform 210 by waveform generator 100 of controller C so the time between the end of melting pulse 212 at t2 and the time of the actual short event t3 is constant based upon adjustment of circuit 200. This time delay adjustment, in an exemplary embodirnent, is accomplished by the circuit 250 shown in FIGURE 4. In this 425 circuit, the time between the melting pulse and at time t2 and the short circuit at time ta is set to a desired level between 0.5 to 2.0 ms. In one embodiment, the set desired time delay is 1.0 ms, which is the level of the signal on line 254. Thus, the numerical number on line 254 is the desired time t2 to h. The actual time between t2 and h is determined by timer 260 which is started at time t2 and stopped at time h. The timer is reset for the next measurement by an appropriate time indicated as ts which can be adjusted to be 430 located at various positions after ts. which position is illustrated to be during the melting pulse in FIGURE 3. The number on line 262 is the actual time between t2 and tj. This actual time is stored in register 270 which is reset at any appropriate time such as time t2. Thus, the digital data on line 272 is the actual measured time between t2 and .ts. This time is compared to the desired time on line 254. Any error amplifier can be used to digitally process the relationship of actual time to the set time. The process is 435 schematically illustrated as a summing junction 280 and digital filter 282 having an output 284 for 19 adjusting circuit 200. The difference between the desired time and the actual time is an error signal in line 284 which increases or decreases the desired total energy of circuit 200. The desired total energy is periodically updated at an appropriate time indicated as t2 by an update circuit 290. Thus, at all times the signal in line 192 of FIGURE 1 is the desired total energy for pulse 212 of the short arc process. This 440 total energy is adjusted by any difference between time t2 and time ts so the energy of pulse 212 maintains a constant or desired time delay for the upcoming short circuit. This time control stabilizes the short arc welding process of system A. ^ In FIGURE 4, an exemplary embodiment of the power source is implemented by changing the energy threshold for the melting pulse to change the timing between the pulse and the short event. This 445 time can also be changed by voltage or power of the melting pulse as schematically illustrated in FIGURES 5 and 6. In both of these embodiments, the time of the melting pulse ti to ti is maintained fixed as indicated by block 300. During this constant time melting pulse, the voltage or power is changed to control the time between the pulse and the short circuit event. In FIGURE 5, the number on output line 284 fi-om filter 282 controls feedback loop 310 to adjust the voltage of the melting pulse, as indicated by 450 the numerical data on line 312. To adjust the power for controlling the delay time of the short circuit i event, the number on output line 284 is used to adjust feedback loop 320, which is compared to the ^ instantaneous power on line 154 by waveform generator 100. The change in power is a numerical value on line 322 which is compared to the digital number on line 154 for controlling the power of the melting pulse. Thus, in embodiments of the present invention, the total energy of the waveform, the voltage of the 455 waveform or the power of the waveform is adjusted to maintain a constant time between tj to ts to stabilize the arc and control the short circuit events of system A shown in FIGURE 1. In accordance with another embodiment of the power source, the energy adjustment of melting pulse 212 is combined with the two modifications of the present invention illustrated in FIGURES 5 and 6. Such combination controls are shown in FIGURES 7 and 8 wherein prior summing junction 280 and 460 digital filter 282 are illustrated as combined in analog error amplifier 330. The component or program 20 has output 332 with a logic for stopping the melting pulse when the threshold energy has been reached, as indicated by the logic on line 182. Thus, the total energy of the pulse is controlled together with the pulse voltage control circuit 310 in FIGURE 7 and the pulse power control 320 as shown in FIGURE 8. Output 312 is combined with output 172c for controlling the waveform profile in line 100a of generator 100. In a 465 like manner, the energy level is controlled by logic on line 172c in combination with the digital information on output line 322 of power pulse control circuit 320. Other combinations of parameters can be used to control melting pulse 212 to assure an accurate control of the time between the melting pulse and the short circuit event.' Such other parameters are within the skill of the art in controlling a waveform generator by closed feedback loops. 470 In an exemplary embodiment of the present invention, the process is an AC process, as shown in FIGURE 4; however, DC positive waveform 400 can be used as shown in FIGURE 9. Melting purse 402 has a high positive current 402a until the pulse is terminated at time t2. The current, in the DC positive mode, is limited to a level below that needed for spray arc so the metal is not detached without shorting. This concept defines the short arc welding process. Then the waveform transitions into a low level j 475 positive current section 404 awaiting the short at time ts. This low level positive current is used in an exemplary embodiment of the present invention and terminates at time ts. Thereafter, short clearing pulse ^ 410 is created by the waveform generator. Pulse 410 has high ramp area 412 and a stepped area 414 to bring the current back up to the high current level 402a. Various illustrated embodiments of the present invention can be used in implementing the positive current waveform 400; however, the logic on line 480 100b for controlling the polarity of the output waveform on lines 32, 34 is not necessary. An exemplary embodiment of the power source is in pipe welding operation using a flux cored electrode as schematically represented in FIGURE lA. Such pipe welding operation is schematically illustrated in FIGURE 10 wherein pipe sections 420, 422 define an open root 424. The present invention as shown in FIGURE 4 controls the waveform on wire W as it moves through contact tip 42 to open root 485 424 of the pipe joint. FIGURE 10 shows a particular embodiment using the present invention for welding 21 i the root pass of a pipe joint to tack the pipe sections together for subsequent joining with standard welding techniques. In certain embodiments, the power sources and/or welding operations according to the present invention exhibit one or more of the following aspects. The current density is generally less than that 490 required for spray welding since the primary mode of metal transfer is short circuit welding. As in many short circuit processes, a pinch current is established depending upon the wire diameter, for example for a 5/64 inch flux cored wire, a current of 625 amps can be used. Generally, the positive current tends to set ^ ^ the arc length. If the positive current is allowed to reach the same level as the negative current arc length, even for half a millisecond, the positive current arc will reach a non-desirable length. Generally, positive 495 side control current is in the range of from about 50 amps to about 125 amps, and in one embodiment is about 75 amps. The negative portion of the wave shape can either be a constant power or voltage with a slope of from about 5 to 15 percent current. Typically, welding can be performed at about 60 hertz, 10 percent positive. Since the positive current is set at a relatively low level, the portion that the wave shape is positive is typically less than 20 percent. 500 FIGURES 11 and 12 schematically illustrate a waveform technology welder and/or welding system 510, and a cored electrode 530. The welding system comprises a welder 510 having a torch 520 ^ for directing an electrode 530 toward workpiece W. The welding system 510 includes a three phase input power supply LI, L2, and L3, which is rectified through rectifier 550, 560, and a power source 540. The power source 540 provides an output, and specifically, an AC waveform as described in U.S. application 505 Serial No. 11/263,064, filed October 31, 2005, previously incorporated by reference. An arc AC is created between the end of electrode 530 and workpiece W. The electrode is a cored electrode with a sheath 600 and an internal filled core 610. The core includes flux ingredients, such as represented by particles 610a. The purpose of these ingredients 610a is to (a) shield the molten weld metal from atmospheric contamination by covering the molten metal with stag, (b) combine chemically with any 510 atmospheric contaminants such that their negative impact on the weld quality is minimized and/or (c) 22 generate arc shielding gases. In accordance with standard practice, core 610 also includes alloying ingredients, referred to as particles 610b, together with other miscellaneous particles 610c that are combined to provide the fill of core 610. In prior applications, to optimize the welding operation, it has been necessary to use solid wire with an external shielding gas. However, in order to produce a weld with 515 specific mechanical and metallurgical properties, specific alloys are required, which can be difficult to obtain in the form of a solid wire. Further, gas shielding is not always a feasible alternative due to access to gas or difficulty to achieve adequate shielding due to windy conditions, accessibility to clean gas mixtures and difficult terrains. It is, therefore, advantageous to use a self shielding cored electrode, so that the environment does not affect the welding, as in the present invention. 520 A common problem caused when using cored electrodes without control of the welding waveform profile is illustrated in FIGURE 13. The welding process melts sheath 600 to provide a portion of molten metal 630 melted upwardly around the electrode, as indicated by melted upper end 640. Thus, the sheath of the electrode is melted more rapidly than the core. This causes a molten metal material to exist at the output end of electrode 530 without protective gas or chemical reaction created by melting of 525 the internal constituents of core 610. Thus, arc AC melts the metal of electrode 610 in an unprotected atmosphere. The necessary shielding for the molten metal is formed when the sheath and core are melted at the same rate. The problem of melting the molten metal more rapidly than the core is fiirther indicated by the pictorial representation of FIGURE 14. Molten metal 650 Irom sheath 600 has already joined workpiece W before the core 610 has had an opportunity to be melted. Thus, the core 610 can not 530 provide the necessary shielding for the welding process. FIGURES 13 and 14 show the reason why AC welding using cored electrodes has not been used for off-shore pipeline welding and other pipeline welding. However, an AC waveform can be utilized to control the heat input when using a cored electrode. By controlling the precise profile for the AC waveform used in the welding process, sheath 600 535 and core 610 can be made to melt at approximately the same rate. The failure to adequately coordinate 23 the melting of the sheath with the melting of the core is one reason why a shielding gas SG, as shown in FIGURE 15 may be used. The advantage of controlling the profile of the AC waveform is that external shielding gas SG, may be avoided. Although control of the AC waveform can lead to significant advantages, as previously noted, in 540 order to provide arc stability and appropriate melting temperatures and rates, the actual control of the AC waveform, is quite complicated. And, even with the use of sophisticated AC waveforms, contamination of the weld is possible. Contamination of welds formed by using sophisticated AC waveforms, is still ^ possible, even if shielding gas is used. Accordingly, in a preferred aspect of the present invention, certain \| electrode compositions are provided that, when used in conjunction with AC waveforms, can form strong, 545 tough, and durable welds, without significant contamination problems, and without the degree of control otherwise required for the AC waveforms. When welding by the method or power source, of the present invention, with a cored electrode, it is desired to have the sheath and core melt at the same rate. This operation promotes homogeneous mixing of certain core materials with the outer sheath, such that the mixture of molten materials 550 chemically resists the effects of atmospheric contamination. Alloying elements required to produce desired weld metal mechanical and metallurgical characteristics are uniformly distributed in the weld t^ metal. In addition, the protective benefits derived from slag and/or gas-forming constituents are optimized. As previously noted, this situation is illustrated in FIGURE 15. In contrast, FIGURE 14 illustrates a situation where the sheath has melted more rapidly than the core. In this deleterious situation, 555 molten metal 650 from sheath 500 has already joined workpiece W before core 610 has had an opportunity to be melted. Metal 650 has not been protected from the effects of atmospheric contamination to the degree that it would have been if the unmelted core constituents had actually been melted. Additionally, alloying elements needed to achieve desired mechanical and metallurgical characteristics may be missing from molten metal 650. 24 560 As previously indicated, an electric welder of the type using waveform technology can be used for AC welding using a cored electrode, such as electrode shown in FIGURE 16. Such electrode includes an outer steel sheath 710 surrounding core 720 formed of particulate material, including alloying metals and slag or flux materials. By having internal flux or slag materials, there is no need for external shielding gas during the welding operation. By including alloying material in core 720, the puddle of 565 weld metal 740 on workpiece 730 can be modified to have exact alloy constituents. This is an advantage and reason for using cored electrodes, instead of solid welding wire where alloying must be accomplished by the actual constituent of the welding wire. Adjustment of alloying for the weld metal is quite difficult when using solid welding wire. Therefore, it is advantageous in high quality welding to employ a cored, i.e. self-shielded electrode. Arc AR melts sheath 710 and melts constituents or fill in core 720 at a rate 570 which can be controlled to be essentially the same. Contamination in weld metal 740, such as hydrogen, nitrogen and oxygen can cause porosity problems, cracking and other types of physical defects in the weld metal. Thus, it is a challenge to design the welding process to exclude contaminates from the molten weld metal. It is common to use "killing" agents, typically silicon, aluminum, titanium and/or zirconium which will combine chemically with potential contaminates to prevent them from forming 575 porosity or harmfiil inclusions in the weld metal. Furthermore, "scavengers" may also be added to react with hydrogen containing a species in order to remove hydrogen from the weld. In order to deposit ^ ^ consistently sound weld metal 740, it has often been necessary to add such killing agents in quantities that are themselves detrimental to properties of the weld metal, such as ductility and low temperature toughness. Thus, it is desirable to reduce the exposure of the molten metal in arc AR to prevent 580 contamination of the metal passing from electrode 700 to workpiece 730 so the killing agents can be minimized. The electrode compositions, of the present invention, when used in AC welding, produce desirable welds that are durable, tough, and which are not susceptible to problems otherwise associated with the use of conventional electrode compositions. The electrode compositions of the present invention 25 585 may be used in conjunction with AC waveforms where the positive and negative shapes of the AC waveform are modified to reduce the overall arc length LA. In this maimer, there is less exposure to the atmosphere and less time during which the metal is molten. A detailed description of the AC waveforms and related welding processes, for which the present invention electrode compositions are designed, is set forth in U.S. application Serial No., 11/263,064, filed October 31, 2005, previously incorporated by 590 reference. Indeed, by reducing the arc length, the temperature of the molten metal can be reduced as it travels from the electrode 700 to weld metal puddle 740. Typically, when using a welder that can perform an AC welding process with different shapes for the negative and positive sections, AC welding with cored electrodes can be used effectively in the field. Parameters of the positive and negative portions of the alternating waveform can be independently adjusted to compensate for and optimize the 595 melting of both sheath 710 and cored 720 for selected electrode 700. More specifically, an embodiment of the present invention involves the combination of an electrode and an AC welding wherein the positive and negative sections of the waveform are individually adjusted to accomplish the objective of a low arc length and reduce contamination. Using this strategy, the electrode composition of the present invention, particularly because it is self-shielding, can provide 600 significant advantages. The electrodes are used without shielding gas and depending upon the particular ^ application, can rely on deoxidizing and denitriding agents in the core for additional protection from atmospheric contamination. Thus, an embodiment of the present invention provides a synergistic system of a welding method with a unique set of alloying and flux components in the core of a FCAW-S electrode. As noted, a cored 605 electrode is a continuously fed tubular metal sheath with a core of powdered flux and/or alloying ingredients. These may include fluxing elements, deoxidizing and denitriding agents, and alloying materials, as well as elements that increase toughness and strength, improve corrosion resistance, and stabilize the arc. Typical core materials may include aluminum, calcium, carbon, chromium, iron, manganese, and other elements and materials. While flux cored electrodes are more widely used, metal- 26 610 cored products are useflil for adjusting the filler metal composition when welding alloy steels. The powders in metal-cored electrodes generally are metal and alloy powders, rather than compounds, producing only small islands of slag on the face of the weld. By contrast, flux cored electrodes produce an extensive slag cover during welding, which supports and shapes the bead. The alloy/flux system, of the present invention, comprises particular amounts of a barium source, 615 particular amounts of a lithium source, lithium oxide, iron oxide, and optional amounts of calcium oxide, silicon oxide, and manganese oxide. One or more fluoride, oxide and/or carbonate salts of barium can be g^ used for the barium source. And, one or more fluoride and/or carbonate salts of lithium can be used for the lithium source. The alloy/flux system is included in the electrode fill. The electrode fill generally constitutes fi-om about 18 to about 24% of the electrode. An exemplary embodiment of the alloy/flux 620 system comprises: fi"om about 35 to about 55% barium fluoride as the barium source, from about 2 to about 12% lithium fluoride as the lithium source, fi-om about 0 to about 8% barium carbonate as a secondary barium source, fi-om about 0 to about 8% lithium carbonate as the secondary lithium source, ^^25 fi-om about 0 to about 15% of lithium oxide, fi"om about 0 to about 15% of barium oxide, fi"om about 5 to about 20% of iron oxide, fi-om about 0 to about 5% of calcium oxide, fi-om about 0 to about 5% of silicon oxide, 630 fi-om about 0 to about 5% of manganese oxide, and 27 up to about 25% of aluminum, magnesium, titanium, zirconium, or combinations tiiereof, for deoxidation and denitriding and the remaining metallics optionally including iron, nickel, manganese, silicon, or combinations thereof All percentages expressed herein are percentages by weight unless noted otherwise. In an embodiment, the electrode fill composition comprises from about 35 to about 55% 635 barium fluoride, from about 2 to about 12% lithium fluoride, from about 0 to about 15% lithium oxide, from about 0 to about 15% barium oxide, from about 5 to about 20% iron oxide, and up to about 25% of a deoxidizing and denitriding agent as previously noted. In other embodiments, the previously noted electrode fill composition can also include from about 0 to about 8% barium carbonate. In yet another embodiment, the elecfrode fill composition may additionally include from about 0 to about 8% lithium 640 carbonate. In yet another embodiment, the fill composition can include from about 0 to about 5% calcium oxide. In yet a fiirther embodiment, the electrode fill composition can include from about 0 to about 5% silicon oxide. And, in another embodiment, the electrode fill composition can comprise from about 0 to about 5% manganese oxide. Other embodiments include the use of one or more of these agents, i.e. the barium carbonate, lithium carbonate, calcium oxide, silicon oxide, manganese oxide, and combinations 645 thereof An exemplary embodiment of the method, of the present invention, comprises applying a first negative voltage between an electrode and a substrate to cause at least partial melting of the electrode near the subsfrate. The method also comprises applying a positive voltage between the elecfrode and the substrate to promote formation of a flowable mass of material from the electrode. The method fiirther 650 comprises monitoring for occurrence of an electrical short between the electrode and the substrate through the flowable mass. The method further comprises upon detecting an electrical short, applying a second negative voltage between the elecfrode and the substrate. And, the method comprises increasing the magnitude of the second negative voltage, to thereby clear the electrical short and form a weld on the substrate from the flowable mass. The composition of the electrode fill in a flux cored electrode 655 comprises from about 35 to about 55% barium fluoride, from about 2 to about 12% lithium fluoride, from 28 about 0 to about 15% lithium oxide, from about 0 to about 15% barium oxide, from about 5 to about 20% iron oxide, and up to about 25% of a deoxidation and denitriding agent selected from the group consisting of aluminum, magnesium, titanium, zirconium, and combinations thereof In other embodiments, additional agents can be incorporated in the electrode fill. For instance, from about 0 to about 8% barium 660 carbonate can be included. Another embodiment of the electrode fill composition includes from about 0 to about 8% lithium carbonate. Yet another embodiment includes from about 0 to .about 5% calcium oxide. Another embodiment includes from about 0 to about 5% silicon oxide. And, yet another embodiment includes from about 0 to about 5% manganese oxide. In yet a fiirther embodiment, one or ^ more of these agents can be added or otherwise included in the electrode fill composition. For example, 665 the elecfrode fill can also comprise, in addition to the previously noted proportions of barium fluoride, lithium fluoride, lithium oxide, barium oxide, iron oxide, and one or more particular deoxidation and denitriding agents from about 0 to about 8% barium carbonate, from about 0 to about 8% lithium carbonate, from about 0 to about 5% calcium oxide, from about 0 to about 5% silicon oxide, and from about 0 to about 5% manganese oxide. 670 The flux/alloy system is modified from traditional flux/alloy systems used for FCAW-S elecfrodes to achieve the short arc length and to weld at low heat inputs that result from the unique waveforms used in this process. The short arc length and the stable arc is a result of the combination of the alloy and flux system and the unique characteristics of the waveform. In essence, both the welding consumable and the process are optimized in tandem to achieve the final weld product requirements. 675 In certain embodiments, the present invention provides methods of forming weld metals having attractive properties. Generally, these methods involve providing a welding wire or electrode having a core with the previously described composition. In an embodiment, the welding wire or electrode is used free of shielding gas, or rather agents that form such a gas. The methods also include an operation in which the wire or electrode is moved toward the region of interest, such as a joint formed between two 680 sections of pipe. In an additional embodiment, such movement is made at a controlled feed speed. The 29 i i method also includes creating a welding current to melt the wire or electrode by an arc between the wire and the pipe sections to thereby form a molten metal bead in the joint. The method also includes transferring the melted wire to the molten metal bead by a succession of short circuit events. The method is particularly well suited for application to welding of a joint between two sections of pipe formed from a ! 685 metal having a yield strength of at least about 70 ksi and a thickness less than about 0.75 inches. In a further embodiment, the invention can provide a weld, without the use of gas-shielding, having a yield strength of at least 80 ksi, thus providing a weld which satisfies the requirements for welding at least American Petroleum Institute (API) Grade X-80 line pipe. Further, an exemplary embodiment of the ^ present invention can achieve over 550 MPa yield strength and 690 MPa tensile strength, and a Charpy V- 690 Notch (CVN) toughness of over 60 Joules at -20 degrees C. However, it will be appreciated that the present invention can be used in applications on pipes having thicknesses greater than or less than 0.75 inches. In one embodiment, the resulting bead that is I formed generally has a tensile strength greater than 70 ksi and in certain applications, greater than about 90 ksi. In particular aspects, the melting current can be negative. If the melting current is negative, the 695 metal transferring operation can be performed by a positive current. The metal transferring can however, be performed by a positive current independent of the melting current. When performing the previously described method, in one embodiment the average arc length is less than 0.30 inches, and in a fiirther embodiment is less than 0.20 inches, and in another embodiment is less than 0.10 inches. In an embodiment of the previously described method, the rate of the short circuit events is automatically 700 controlled. The rate of short circuit events is generally from about 40 to about 100 cycles per second. In other embodiments, the previously described concepts, i.e. using the power sources and control techniques in combination with the elecfrode compositions noted herein, can be utilized to produce a weld metal having a minimum Charpy V-Notch toughness of 60J at -20°C. Similarly, the methods can be used to produce a weld metal having a minimum Charpy V-Notch toughness of 40J at -40°C. And, the 705 methods can be used to produce a weld metal having a tensile strength exceeding 90 ksi. Thus, thin pipe 30 of less than about 0.75 inches can be used with the resultant savings. No shielding gas is needed, so the cost of on site gas is eliminated, or greatly reduced. The present application can be utilized in a wide array of applications. The system, process, and/or compositions described herein are particularly adapted for use in welding at least X80 pipe (the 710 designation X80 being in accordance with the API 5L:2000 industry specification) with self-shielded flux core wire. However, the present invention can be utilized in conjunction with other pipe grades. The present invention can also be utilized in "root pass" or tack welding operations performed on pipes. The ^ present invention can be utilized to melt greater amounts of welding wire with less arc force as compared to currently known practices of using a buried short arc for the initial welding pass. Yet another 715 application for the present invention is in robotic welding applications for high speed welding of thin gauge metals. EXAMPLE The following discussion is directed to an example of the present invention. The present invention is not limited to the embodiment and results discussed below, but the following discussion is 720 provided to demonstrate the results achievable from an exemplary embodiment of the present invention. A series of test welds were made using an embodiment of the present invention, in which a selfshielded, flux cored electrode was used in a short arc welding process. In some tests a 0.062 inch diameter Lincoln Innershield NR-233 was used. The welds were made at a constant wire feed speed and travel speed. The welds were bead on plate welds, having three passes side-by-side, then two passes side- 725 by-side in a second layer on top of the first three passes. The plate surfaces were shot blasted prior to welding to remove scale and dirt. The weld metal layer in the second layer was analyzed for nitrogen content. Because no nitrogen was intentionally incorporated in the electrodes used, the following analysis was (Conducted under the assumption that the nitrogen in the weld metal came from the ambient atmosphere. f I I I I I t\730 Further, the welding power supply was constructed to produce alternating current with variable waveforms, and the following characteristics of the AC waveform were varied: "waveform balance" - the waveform balance is the percentage of the AC cycle time when the electrode polarity is positive; and "DC offset" - the DC offset is the measure of the degree to which the amplitudes of the positive 735 and negative portions of the waveform are unequal. A DC offset of-20 indicates that the amplitude of the positive portion of the waveform was 19.4 volts, while the negative portion is 23 volts. Further, +20 ^ indicates the reverse, i.e.-23 volts positive and 19.4 volts negative. FIG. 17 depicts the influence of wave balance and DC offset on weld metal nitrogen recovery in an example weld performed by an example of the claimed invention. As shovm in FIG. 17, the large data 740 point at 0% wave balance, 0.029% nitrogen recovery, is the result for the weld made with DC- current. The two welds made at 10% wave balance, +20 DC offset, and the two made at 50% wave balance, -20 DC offset had significantly lower nitrogen recoveries than the DC- weld. Additionally, during testing it was noted that nitrogen recoveries higher than that observed with DC- were observed with other combinations of wave balance and DC offset. 745 Further, in additional embodiments the AC waveform can also be manipulated to control levels of oxygen and hydrogen in the weld metal. Reducing overall levels of contamination reduces the need for killing, scavenging, or geometry-modifying or solubility-limiting agents. Thus, alloy levels in the selfshielding electrode can be optimized to achieve optimum physical properties in the weld metal. The following Tables provide weld data and specifications of a weld example performed in 750 accordance with an embodiment of the present invention. In this example, a Pipeliner® electrode, from The Lincoln Electric Company, Cleveland Ohio, was used in the 5G position according to the procedures set forth below in Table 1. Additionally, FIG. 18 depicts a weld joint design structure corresponding with the data shown in the Tables below. The metal welded 181 was API Grade X-80 having a 17 mm 32 thickness and the weld structure was as shown in FIG. 18. Further, as shown in FIG. 18, the weld passes 755 are shown as passes #1 through #9. Table 2 shows the mechanical test results of the weld performed in accordance with Table 1. Finally, Table 3 shows the weld deposit chemistry of the example set forth in Table 1. Table 1 - Welding Procedures: Pass 1 (Root) I 0.045" Pipeliner® 70S-G (ER70S-G) I Semi-automatic 155A, 17.5 V DC+ Vertical-down WFS 4.1 m/min (160 in/min) • 100% CO2 I STTII: 400A Peak, 60A Back, 0 Tail I Pass 2-9 (Hot-Cap) 2.0 mm Pipeliner® M2M80 (FCAW-S) Semi-automatic 2OOA 21V Vertical-down ^^g 2.3 to 2.5 m/min (90 to 100 in/min) Position 5G Horizontal Fixed Heat Input (avg.) 1.4kJ/mm I 35 kJ/in Preheat/Interpass 65.56/121.1 °C 150/250 °F Pipe API 5L X80 DSAW (Napa) Rpo.2 (YSo.2%) 608 MPa 88.1 ksi Diameter x Wall \| 915 x17 mm \| 36 x 0.667 in \| Table 2: Mechanical Test Results (weld metal - as welded): I Tensile (ASTM E8) All weld metal, 6.35 mm (0.25 in) dia. I Rpo.2 (YSo.2%) average 656 MPa 95 ksi min-max 649-662 MPa 94-96 ksi R„(UTS) average 725 MPa 105 ksi min-max 718-731 MPa 104-106 ksi A5(Elong.) average 25% 25% min-max \| 25-26% \ 25-26% Charpy V-Notch (ASTM E23) Mid-wall, 10mm x 10mm -20°C (-4°F) Average I 97J \ 75 ft-lb min-max 83-117 J 64-91 ft-lb -29°C (-20°F) Average 59J 46 ft-lb min-max 35-77 J 27-60 ft-lb 33 -40°C (-40°F) Average I 411 \ 32 ft-lb ' 1 min-max 34-46 J 26-36 ft-lb Table 3: Weld Deposit Chemistry (SPJ): Chemistry (ASTME350) I Element % C 0.026 Mn 3.43 Si 0.10 P 0.010 • S 0.009 Ni 0.77 Cr 0.03 Mo 0.01 B 0.0022 Ti 0.010 V 0.02 Nb 0.016 Al \ L06 I The above example is intended to merely exemplary of an embodiment of the present invention, and is not intended to limit the scope of the present invention in any way. In an embodiment of the present invention the short arc welding device is a welding device which employs a welding gun to continuously advance the electrode toward the workpiece to be welded. This is ^ similar to a MIG welding process. However, as indicated above, the process is a gas-less process using self-shielding flux-cored electrodes. Further, the method of welding using the short arc welding system and the disclosed electrode is a welding method similar to MIG welding, in that the electrode is continuously advanced through a welding gun. Moreover, fiirther to the discussions above, in fiirther embodiments of the present invention, the welding device can be an engine driven machine or a fuel cell, or battery base, driven machine. Additionally, the present invention may also be employed with automatic or robotic welding machines. 34 The present invention has been described with certain embodiments and applications. These can be combined and interchanged without departing from the scope of the invention as defined in the appended claims. The systems, methods, electrodes and combinations thereof as defined in these appended claims are incorporated by reference herein as if part of the description of the novel features of the synergistic invention. • 35 I " 1 f ^ g I/We claim: "^'^ ^'^^ "* ^ / NA^ I 1. A method of welding a workpiece (WP) the method comprising: advancing a self-shielding electrode (E) from a welding device toward a workpiece (WP); and employing a short arc welding process to weld the workpiece (WP) using the advancing selfshielded electrode (E), wherein the weld has a yield strength of atleast 70 ksi characterized by, applying a waveform (210) across the self-shielding electrode (E) and workpiece (WP) over a time-period (212a, 212a), the waveform comprising a melting pulse (212) and where the melting pulse (212) is followed by a low current transfer cycle (214) and wherein the waveform is positive for a time period (212a, 212a) having a first duration and the amplitude of the positive portion of the waveform is higher than the amplitude of the negative portion of the waveform, or, the waveform is positive for a second duration and the amplitude for a positive portion of the waveform is less than an amplitude of the negative portion of the waveform, and controlling the melting pulse by measuring a duration time between said melting pulse and a short circuit during said transfer cycle (214), setting a desired time for said duration, creating a corrective signal by comparing said measured duration and said set desired time, and adjusting a parameter if said melting pulse based upon said corrective signal. 2. The method as claimed in claim 1, wherein the electrode is a flux cored self-shielding electrode. 36 2. The method as claimed in claim 1, wherein the electrode is advanced through a welding gun toward the workpiece. 4. The method as claimed in claim 1, wherein the yield strength is at least 80 ksi. 5. The method as claimed in claim 1, wherein the weld has a tensile strength of at least 70 ksi. 6. The method as claimed in claim 1, wherein the weld has a tensile strength of at least 90 ksi. 7. The method as claimed in claim 1, wherein the weld has a Charpy V-Notch toughness of at least 60J at -20 degrees. 8. The method as claimed in claim 1, wherein the weld has a Charpy V-Notch toughness of at least 40J at -40 degrees. ^ ^ 9. The method as claimed in claim 1, wherein the weld satisfies the requirements for welding at least American Petroleum Institute Grade X-80 pipe. 10. The method as claimed in claim 1, wherein the self-shielding electrode is a self-shielded flux cored arc welding wire. 11. The method as claimed in claim 1, comprising: 37 controlling a melting pulse of the short arc welding process, where the melting pulse is followed by a low current transfer cycle, by measuring a duration time between said melting pulse and a short circuit during said transfer cycle; setting a desired time for said duration; creating a corrective signal by comparing said measured duration and said set desired time; and adjusting a parameter of said melting pulse based upon said corrective signal. • 12. The method as claimed in claim 1, wherein an average arc length during said short arc welding process is up to 0.3 inches. 13. The method as claimed in claim 1, wherein an average arc length during said short arc welding process is up to 0.2 inches. 14. The method as claimed in claim 1, wherein an average arc length during said short arc welding process is up to 0.1 inches. 15. A welding apparatus; comprising: a short arc welding system which advances an electrode toward a workpiece to be welded;wherein said electrode is a self-shielding electrode; and wherein said short arc welding system is controlled such that said weld has a yield strength of at least 70 ksi characterized in that, 38 the short art welding system comprises a controller (C) arranged to apply a waveform (210) across the electrode (E)and workpiece (WP) over a time period (212a, 212a) the waveform comprising a melting pulse (212) created by a waveform generator (100) of the short arc welding system, where the melting pulse is followed by a low current transfer cycle (214) and wherein the waveform is positive for a time period (212a, 212a) having a first duration and the amplitude of the positive portion of the waveform is higher than the amplitude of the negative portion of the waveform, or, the waveform is positive for a second duration and the amplitude for a positive portion of the waveform is less than an amplitude of the negative portion of the waveform, and fiarther provided • with a circuit (150) for controlling the melting pulse, a timer (260) for measuring a duration time between said melting pulse and a short circuit during said transfer cycle, and an adjusting circuit (200) for creating a corrective signal by comparing said measured duration time and a set desired time and for adjusting a parameter of said melting pulse based upon said corrective signal. ^ 16. A welding apparatus; comprising: a short arc welding system which advances an electrode toward a workpiece to be welded;wherein said electrode is a self-shielding electrode; and wherein the weld satisfies the requirements for welding at least American Petroleum Institute Grade X-80 pipe. characterized in that, the short art welding system comprises a controller (C) arranged to apply a waveform (210) across the electrode (E)and workpiece (WP) over a time period (212a, 212a) the waveform comprising a melting pulse (212) created by a waveform generator (100) of the short arc welding system, where the melting pulse is followed by a low current transfer cycle (214) and wherein the waveform is positive for a time period (212a, 212a) having a first duration 39 I and the amplitude of the positive portion of the waveform is higher than the amplitude of the negative portion of the waveform, or, the waveform is positive for a second duration and the amplitude for a positive portion of the waveform is less than an amplitude of the negative portion of the waveform, and further provided with a circuit (150) for controlling the melting pulse, a timer (260) for measuring a duration time between said melting pulse and a short circuit during said transfer cycle, and an adjusting circuit (200) for creating a corrective signal by comparing said measured duration 9 time and a set desired time and for adjusting a parameter of said melting pulse based upon said corrective signal. 17. A welding apparatus; comprising: a short arc welding system which advances an electrode toward a workpiece to be welded;wherein said electrode is a self-shielding electrode; and wherein the weld has a Charpy V-Notch toughness of at least 60 J at -20 degrees. characterized in that, the short art welding system comprises a controller (C) arranged to apply a waveform (210) across the electrode (E)and workpiece (WP) over a time period (212a, 212a) the waveform comprising a melting pulse (212) created by a waveform generator (100) of the short arc welding system, where the melting pulse is followed by a low current transfer cycle (214) and wherein the waveform is positive for a time period (212a, 212a) having a first duration and the amplitude of the positive portion of the waveform is higher than the amplitude of the negative portion of the waveform, or, the waveform is positive for a second duration and the amplitude for a positive portion of the waveform is less than an amplitude of the negative portion of the waveform, and further provided with a circuit (150) for controlling the melting pulse, • 40 a timer (260) for measuring a duration time between said melting pulse and a short circuit during said transfer cycle, and an adjusting circuit (200) for creating a corrective signal by comparing said measured duration time and a set desired time and for adjusting a parameter of said melting pulse based upon said corrective signal. Dated: this 28.07.06 ^ yJcU^J^ [R. MAHESH] OF REMFRY & SAGAR ^ ATTORNEY FOR THE APPLICANT[S] 41

Full Text

This invention relates to a method of welding a workpiece and welding apparatus thereof.
PRIORITY
5 The present application is a continuation-in-part of U.S. Application No. 10/834,141, filed April
29, 2004; a continuation-in-part of U.S. Application No. 10/959,587, filed October 6, 2004; a
continuation-in-part of U.S. Application No. 11/263,064, filed October 31, 2005; and a continuation-inpart
of U.S. Application No. 11/336,506, filed January 20, 2006, the entire disclosures of which are
incorporated herein by reference.
•
10 FIELD OF THE INVENTION
The present invention relates to the art of electric arc welding and more particularly to an
improved short arc welding system, methods of welding with self-shielding flux cored arc welding
(FCAW-S) electrodes, and the composition of the electrodes.
BACKGROUND
15 Presently, there are no conmiercial solutions or methods for semi-automatically,
circumferentially, welding high strength pipes and pipelines with a gas-less or self-shielding welding
process. This is because the traditional technologies used for gas-less or self-shielding welding
" applications have in high strength welding applications.
In using gas-less or self-shielding welding electrodes various chemicals are used in the electrode
20 to react with the oxygen and nitrogen in the atmosphere to keep these components out of the weld. These
chemicals are used in such a quantity so as to sufficiently prevent the oxygen or nitrogen from
deteriorating the weld quality. However, while these chemicals, such as titanium and aluminum, make
the welds stronger, they also have the adverse effects of making the welds brittle. This brittleness
prevents gas-less or self-shielding welding methods from being used in many high strength welding
- 2 -
25 applications, such as pipeline welding, in which it is often required that the weld strength be sufficient to
satisfy the requirements for welding American Petroleum Institute (API) Grade X-80 line pipe, or higher.
Further, although there exists methods for meeting these weld requirements using gas-shielded
welding methods, these methods also have drawbacks which make them less than desirable. Namely,
current methods and systems for welding high strength pipes and pipelines (along with other applications)
30 using gas-shielding methods require costly and time consuming set ups to protect the welding area from
the atmosphere and elements. This is particularly the case in pipeline applications, where the welds are
g^ often taking place outside in difficult environmental conditions.
INCORPORATION BY REFERENCE
The present invention involves using a short arc welding process employing a self-shielding cored
35 electrode which is capable of satisfying the requirements for welding American Petroleum Institute (API)
Grade X-80 line pipe, or higher. There is a synergistic relationship when combining the welding process
and the flux cored electrode of the present invention. Thus, the present invention combines controlling
the energy input along with the microstructure control of the weld metal deposited to achieve highstrength
and toughness. Specifically, an exemplary embodiment of the present invention can achieve over
40 550 MPa yield strength and 690 MPa tensile strength, and a Charpy V-Notch (CVN) toughness of over
w 60 Joules at -20 degrees C.
Short-circuit arc welding systems, techniques, and associated concepts, as well as pipe welding
methods and apparatuses are generally set forth in the following United States patents, the contents of
which are hereby incorporated by reference as background information: Parks 4,717,807; Parks
45 4,954,691; Parker 5,676,857; Stava 5,742,029; Stava 5,961,863; Parker 5,981,906; Nicholson 6,093,906;
Stava 6,160,241; Stava 6,172,333; Nicholson 6,204,478; Stava 6,215,100; Houston 6,472,634; and Stava
6,501,049.
3
The electric arc welding field uses a variety of welding processes between the end of a
consumable advancing electrode and a workpiece, which workpiece may include two or more
50 components to be welded together. An embodiment of the present invention relates to the short arc
process where the advancing electrode is melted by the heat of the arc during a current pulse and then,
after the molten metal forms into a ball by surface tension action, the molten metal ball is transferred to
the workpiece by a short circuit action. The short circuit occurs when the advancing wire moves the ball
I
into contact with the molten metal puddle on the workpiece, which short is sensed by a plunge in the
55 welding voltage. Thereafter, the short circuit is broken and the short arc welding process is repeated. The
present invention is an improvement in short arc welding and is performed by using a power source where
the profile of the welding waveform is controlled by a waveform generator operating a pulse width
modulator of a high switching speed inverter, as disclosed in several patents by assignee,, such £is shown
in Parks 4,866,247; Blankenship 5,278,390; and, Houston 6,472,634, each of which is hereby
60 incorporated by reference. These three patents illustrate the type of high switching speed power source
employed for practicing an exemplary embodiment of the present invention and are incorporated herein as
background technology. A waveform of the waveform generator is stored in memory as a state table,
which table is selected and outputted to the waveform generator in accordance with standard technology
pioneered by The Lincoln Electric Company of Cleveland, Ohio. Such selection of a table for creating
^ r 65 the waveform profile in the waveform generator is disclosed in several prior art patents, such as the
previously mentioned Blankenship 5,278,390. Consequently, a power source used in practicing the
present invention is now commonly known and constitutes background technology used in the present
invention. An aspect of the short arc welding system of the present invention employs a circuit to
determine the total energy of the melting pulse forming the molten metal ball of the advancing electrode,
70 such as described in Parks 4,866,247. The total energy of the melting pulse is sensed by a watt meter
having an integrated output over the time of the melting pulse. This technology is incorporated by
reference herein since it is employed in one aspect of the present invention. After a short has been created
4
in a short arc welding system, the short is cleared by a subsequent increase in the welding current. Such
procedure is well known in short arc welding systems and is described generally in Ihde 6,617,549 and in
75 Parks 4,866,247. Consequently, the technology described in Ihde 6,617,549 is also incorporated herein as
background technology. An exemplary embodiment of the present invention is a modification of a
standard AC pulse welding system known in the welding industry. A prior pending application of
assignee describes standard pulse welding, both DC and AC, with an energy measurement circuit or
program for a high frequency switching power source of the type used in practicing an exemplary AC
80 short circuit implementation of the present invention. Although not necessary for understanding the
present invention or practicing the present invention, this prior application, which is Serial No.
11/103,040 filed April 11, 2005, is incorporated by reference herein.
The present invention relates to a cored electrode and a short arc welding system, and method, for
controlling the melting pulse of the system for depositing a special cored electrode so no shielding gas is
85 needed, which is capable of satisfying the requirements for welding American Petroleum Institute (API)
Grade X-80 line pipe, or higher. The system and method maintains a desired time between the pulse and
the actual short circuit. This time is controlled by a feedback loop involving a desired timing of the short
circuit and the pulse, so that the size of the ball of the pulse is varied to maintain a consistent short circuit
timing. This process is a substantial improvement of other short arc control arrangements, such as
90 disclosed in Pijls 4,020,320 using two power sources. A first source maintains a constant size melting
pulse and there is a fixed time between the short circuit and the subsequent clearing pulse. There is no
feedback between the pulsed timing and a parameter of the melting pulse, as employed in the present
invention. A desired time is maintained between the end of the melting pulse and the short circuit event.
By fixing the desired time using a feedback loop concept, arc stability is improved. This invention is
95 applicable to a DC process, as shown in Pijls 4,020,320, but is primarily advantageous when using an AC
short arc welding system. Consequently, Pijls 4,020,320 is incorporated by reference herein as
5
I
background technology showing a control circuit for a DC short arc system wherein two unrelated
timings are maintained constant without a closed loop control of the melting pulse.
The present invention fiirther involves a welding method employing a flux cored, i.e. self-
100 shielding, electrode or welding wire. Details of arc welding electrodes or wires and specifically, cored
electrodes for welding are provided in U.S. Patents 5,369,244; 5,365,036; 5,233,160; 5,225,661;
5,132,514; 5,120,931; 5,091,628; 5,055,655; 5,015,823; 5,003,155; 4,833,296; 4,723,061; 4,717,536;
4,551,610; and 4,186,293; all of which are hereby incorporated by reference.
W Also, prior applications filed September 8, 2003 as Serial No. 10/655,685; filed April 29, 2004 as
105 Serial No. 10/834,141; filed October 6, 2004 as Serial No. 10/959,587; and filed October 31, 2005 as
Serial No. 11/263,064 are each incorporated by reference as background, non-prior art technology.
SUMMARY OF THE PRESENT INVENTION
The present invention is directed to a system and method for addressing the problems discussed
above and providing a system and method which is capable of creating a weld which satisfies the
110 requirements for welding American Petroleum Institute (API) Grade X-80 line pipe, or higher.
Specifically, an exemplary embodiment of the present invention can achieve over 550 MPa yield strength
^ and 690 MPa tensile strength, and a Charpy V-Notch (CVN) toughness of over 60 Joules at -20 degrees
C.
The system and method of the present invention controls the welding arc through a specialized
115 power source to minimize the arc length coupled with the use of a cored, i.e. self-shielded, electrode to
achieve the desired welding attributes. The use of the short arc minimizes the contamination fi-om the
atmosphere in the weld pool, thus improving toughness, while at the same time being more resistant to
porosity during welding. Further, the use of the short arc length allows for the use of a self-shielding
electrode, according to an embodiment of the present invention, which contains a composition according
120 to an aspect of the present invention, discussed fiirther below. Additionally, with the present invention,
6
there is no need to use additional shielding gas to achieve a weld which satisfies the requirements for
welding American Petroleum Institute (API) Grade X-80 line pipe, or higher, and/or over 550 MPa yield
strength and 690 MPa tensile strength, and a Charpy V-Notch (CVN) toughness of over 60 Joules at -20
degrees C.
125 In accordance with a first aspect of the present invention as it relates to the method, the melting
pulse of the short arc waveform is controlled interactively by a feedback loop and not by fixing constant
values of the melting pulse. The time between the end of the melting pulse and the short circuit is
^ maintained by reactively changing parameters of the melting pulse in a short arc welding system. In one
exemplary embodiment of the invention the system is an AC system, but can be used in a DC system of
130 the type generally described in Pijls 4,020,320. Manipulation of the short arc waveform is facilitated by
using a single power source having the waveform controlled by a waveform generator operating the pulse
width modulator of a high switching speed inverter, such as disclosed in Houston 6,472,634. One
advantage realized by implementation of the present invention is an improvement over short arc welding
using two separate power sources, as shown in the prior art.
135 In accordance with another embodiment of the first aspect of the present invention, the short arc
welding system is an AC system wherein the melting pulse has a negative polarity. To maintain a
^ ^ constant molten metal bead, there is a joule threshold switch to shift the power supply to a low level
positive current so the molten metal on the end of the advancing electrode forms into a ball and then short
circuits against the workpiece weld puddle. In an embodiment, this AC waveform is controlled by a
140 waveform generator controlling the profile of the individual current segments of the waveform and
determining the polarity of the waveform segments. In the prior art, a joule threshold switch was used to
provide a constant energy to the melting pulse. In accordance with an embodiment of the present
invention, there is a timer to measure the time for the electrode to short after the melting pulse. A
feedback loop is employed to maintain a consistent time between the mehing pulse and the short circuit
145 event. This control of time stabilizes the arc and the shorting cycle. In one embodiment of the present
7
invention, the time between the melting pulse and the short is about 1.0 ms. Depending upon the
electrode size and deposition rate, the time between the melting pulse and the short circuit event may be
adjusted to a fixed value in the general range of 0.5 ms to 2.0 ms. Control of the timing is typically
applicable to AC short arc welding; however, the same concept is applicable to straight DC positive
150 polarity. In both instances, the advancing wire with molten metal formed by the melting pulse is held at a
low quiescent positive current facilitating the formation of a ball preparatory to the short circuit event. In
either implementation of the invention, the joules or other parameter of the melting pulse is controlled by
a feedback loop conditioned to maintain a preset time to the short circuit event.
The AC implementation of the first aspect of the present invention is usefiil for tubular electrodes
155 of the flux cored type and one embodiment is implimented with a flux core electrode with alloy
ingredients in the core according to an aspect of the present invention, discussed further below. Control
of the melting cycle of a flux cored electrode based upon feedback from the short circuit time is a very
precise procedure to maintain stability of the AC short circuit welding process. In view of the foregoing,
an embodiment the present invention may be used to weld pipe with a cored, i.e. self-shielding, electrode
160 according to an embodiment of the present invention. The welding current for such electrode, when using
a method of the present invention, is below the threshold current for spray welding. Thus, the metal
^ ^ transfer to the pipe joint must involve some type of short circuit, and in an embodiment of the present
invention will involve a globular short circuit transfer of the type to which the present invention is
directed. Improving the weld stability by using AC short arc welding still may result in instability of the
165 arc. This instability has been overcome by implementing the present invention. Thus, the present
invention is particularly applicable to AC short arc welding of a pipe joint using a self-shielding cored
electrode, so that the weld strength satisfies the requirements for welding American Petroleum Institute
(API) Grade X-80 line pipe, or higher.
In accordance with an embodiment of the present invention, there is provided a welding system
170 for performing a short arc welding process between an advancing wire electrode and a workpiece, where
8
I
the system comprises a power source with a controller for creating a current pulse introducing energy into
the electrode to melt the end of the electrode and a low current quiescent metal transfer section allowing
the melted metal on the end of the electrode to be deposited into the weld puddle of the workpiece.
During the low current metal transfer section, the molten metal short circuits against the molten metal
175 puddle. A timer measures the actual time between the end of the melting pulse and the short circuit event.
A device is used to set a desired time between the pulse and short circuit event and a circuit is used to
create a corrective signal based upon the difference between the actual time and the desired time. This
corrective signal is used to control a given parameter of the melting pulse, such as the total energy
introduced into the wire during the melting pulse.
180 In accordance with an exemplary embodiment of the first aspect of the present invention, the
short arc welding process is an AC process wherein the melting pulse is performed with a negative
current and the quiescent low current metal transfer section of the waveform is at a positive polarity. The
AC version of the present invention is applicable for welding with a flux cored electrode in several
environments, such as the root pass of a pipe welding joint.
185 In accordance with another aspect of the power source of the present invention, the controller of
the short arc welding system includes a circuit to create a short circuit clearing pulse after the short
^k circuit. In this embodiment of the power source a waveform generator determines the polarity and profile
of the welding waveform at any given time. The welding system of the present invention is used to
maintain the time between the melting pulse and the short at a fixed value, which fixed value is in the
190 general range 0.5-2.0 ms and, in another embodiment is approximately 1.0 ms.
In accordance with another aspect of the power source or method performed by the power source,
the short arc system is performed DC positive with both the melting pulse and the quiescent section being
positive and followed by a short circuit positive clearing pulse. This implementation of the present
invention does not involve a polarity change from the waveform generator during the processing of the
9 • I
195 waveform to practice the short arc welding process. The short arc welding system is AC and there is a
circuit to control the current pulse for causing the actual time between the melting pulse and short circuit
so it is the same as the desired time. This embodiment of the present invention maintains a constant time,
as does other embodiments of the present invention.
One embodiment of the present invention controls the energy of the melting pulse to control the
200 time between the melting pulse and the ultimate short circuit event.
Yet another aspect of the first aspect of the invention is the provision of a method for controlling
Wf the melting pulse of a short arc welding process so that the process has a selected time between the
melting pulse and the short circuit event. The parameter controlled by this method is the total energy of
the melting pulse. This embodiment of the present invention may be used in the root pass of a circular
205 open root pipe joint using a flux cored electrode.
A second aspect of the invention relates at least in part, to utilizing a relatively short arc length
during AC welding as obtained by the described short arc method, which results in contamination of the
weld fi-om the atmosphere being significantly reduced. This embodiment of the invention also utilizes a
particular flux alloy system, which when used in an electrode along with this aspect of the invention, can
210 achieve beneficial results. The flux/alloy system of the cored electrode enables and promotes a short arc
^ length. Combining these aspects in accordance with an embodiment of the present invention, provides a
synergistic phenomenon which produces a sound and tough weld metal with strength of over 60 to 70 ksi,
and in another embodiment have a yield strength of at least 80 ksi, thus providing a weld which satisfies
the requirements for welding American Petroleum Institute (API) Grade X-80 line pipe, or higher.
215 Further, an exemplary embodiment of the present invention can achieve over 550 MPa yield strength and
690 MPa tensile strength, and a Charpy V-Notch (CVN) toughness of over 60 Joules at -20 degrees C.
Moreover, alloys, as used in embodiments of the present invention, allow use of thiimer pipes and there is
no need for shielding gas in the pipe welding area.
10
I
Waveform technology, as pioneered by The Lincoln Electric Company of Cleveland, Ohio, has
220 been modified for use in AC welding with flux cored electrodes. Cored electrodes allow the welding
operation to be more precisely controlled with the alloy of the weld bead being tailored to the desired
mechanical characteristics for the bead and with the position of the welding operation being less limited.
However, to provide arc stability and appropriate melting temperatures and rates, the actual control of the
waveform for the AC process is quite complicated. Contamination of the weld metal during arc welding
225 is still a problem using AC welding for cored electrodes. Contaminants, in the weld metal after the
welding operation can cause porosity, cracking and other types of defects in the weld metal.
Consequently, a major challenge confronting designers of arc welding processes has been to develop
techniques for excluding elements, such as contaminants from the atmosphere, from the arc environment
or for neutralizing the potentially harmfiil effects of such impurities. The potential source of
230 contamination, includes the materials that comprise the welding electrode, impurities in the workpiece
itself and ambient atmosphere. Cored electrodes may contain "killing" agents, such as aluminum,
magnesium, zirconium and titanium which agents combine chemically with potential contaminates to
prevent them from forming porosity and harmfiil inclusion in the weld metal. The present invention
involves the use of an elecfrode composition that reduces the tendency of a cored electrode to allow
235 inclusion of contaminants in the weld metal. The method also reduces the amount of material required as
W a "killing" agent.
Specifically, the present invention provides a self-shielded flux cored arc welding (FCAW-S)
electrode particularly adapted for forming welds having reduced levels of contaminants using an AC
waveform. The electrode has an alloy/flux system comprising from about 35 to about 55% barium
240 fluoride, from about 2 to about 12% lithium fluoride, from about 0 to about 15% lithium oxide, from
about 0 to about 15% barium oxide, from about 5 to about 20% iron oxide, and up to about 25% of a
deoxidation and denitriding agent. This agent can be selected from aluminum, magnesium, titanium,
zirconium, and combinations thereof
11
The present invention provides a method of arc welding using a self-shielded flux cored electrode
245 that utilizes a particular alloy/flux system. The method comprises applying a first negative voltage
between an electrode and a substrate to cause at least partial melting of the electrode proximate the
substrate. The method also comprises applying a positive voltage between the electrode and the substrate
to promote formation of a flowable mass of material from the electrode. The method flirther comprises
monitoring for occurrence of an electrical short between the electrode and the substrate through the
250 flowable mass. The method further comprises upon detecting an electrical short, applying a second
negative voltage between the electrode and the substrate. And, the method comprises increasing the
magnitude of the second negative voltage, to thereby clear the electrical short and form a weld on the
substrate from the flowable mass. The self-shielded flux cored electrode can comprise from about 35 to
about 55% barium fluoride, from about 2 to about 12% lithium fluoride, from about 2 to about 15%
255 lithium oxide, from about 5 to about 20% iron oxide, and up to about 25% of a deoxidation and
denitriding agent selected from the group consisting of aluminum, magnesium, titanium, zirconium, and
combinations thereof
An object of the present invention is the provision of a short arc welding system, which system j
controls the spacing of the short circuit events during the process, especially when the process is
^^260 performed in the AC mode, to provide a weld which satisfies the requirements for welding at least
American Petroleum Institute (API) Grade X-80 line pipe.
Another object of the present invention is the provision of a method for short arc welding, which
method controls the melting pulse based upon the time between the melting pulse and short so this time
remains fixed at a desired value.
265 Yet another object of the present invention is the provision of an improved electrode composition,
and particularly an electrode fill composition which is particularly adapted for use in combination with
the novel short arc welding system and method.
12
A further object of the present invention is to provide a synergistic system comprising a short arc
process and flux cored electrode to stabilize the arc at the shortest possible arc length. Thus, the
270 contamination from the atmosphere is minimized. The combination of an alloy system and a weld
process allows the arc to be stable at such short arc lengths and result in a sound and tough weld metal.
One embodiment of the invention can provide a weld, without the use of gas-shielding, having a yield
strength of at least 80 ksi, thus providing a weld which satisfies the requirements for welding American
Petroleum Institute (API) Grade X-80 line pipe, or higher. Further, an exemplary embodiment of the
275 present invention can achieve over 550 MPa yield strength and 690 MPa tensile strength, and a Charpy VNotch
(CVN) toughness of over 60 Joules at -20 degrees C.
These and other objects and advantages will become apparent from the following description
taken together with the accompanying drawings.
BRIEF DESCRIPTION OF DRAWINGS
280 The advantages, nature and various additional features of the invention will appear more fully
upon consideration of the illustrative embodiment of the invention which is schematically set forth in the
figures, in which:
^ FIGURE 1 is a block diagram of a short arc welding system used in an exemplary embodimerit of
the present invention;
285 FIGURE 1A is an enlarged cross-sectional view taken generally along line lA-1 A of FIGURE 1;
FIGURE 2 is a series of side elevational views showing the stages I-IV in a short arc welding
process;
FIGURE 3 is a combined current and voltage waveform graph showing the waveform
implementing an embodiment of the present invention as disclosed in FIGURE 4 for the various stages as
290 shown in FIGURE 2;
13
I
FIGURE 4 is a flow chart block diagram illustrating a modification of the system in FIGURE 1 to
perform the embodiment of the present invention;
FIGURES 5 and 6 are flow chart block diagrams of a portion of the welding system shown in
FIGURE I for implementing two further embodiments of the present invention
295 FIGURES 7 and 8 are partial flow chart block diagrams of the welding system as shown in
FIGURE 1 combining the embodiment of the present invention shown in FIGURE 4 with a combined
waveform control from the embodiments of the invention shown in FIGURES 5 and 6, respectively;
FIGURE 9 is a current waveform for the DC positive implementation of the present invention;
FIGURE 10 is a schematic elevational view showing the invention used in the root pass or
300 tacking pass of a pipe welding joint;
FIGURE 11 is a side elevational view with a block diagram illustrating the use of a representative
welding system and an electrode;
FIGURE 12 is an enlarged cross-sectioned pictorial view taken generally along line 12-12 of
FIGURE 11, depicting the electrode in greater detail;
^^305 FIGURE 13 is an enlarged, schematic view representing a cored electrode where the sheath and
core are melted at different rates;
FIGURE 14 is a view similar to FIGURE 13 illustrating a disadvantage of a failure to employ a
tailored waveform for welding with cored electrodes;
FIGURE 15 is a view similar to FIGURES 13 and 14;
310 FIGURE 16 is a partial, side elevational view illustrating a cored electrode in accordance with an
embodiment of the present invention and showing the arc length, which length is minimized by use of the
present invention;
14
FIGURE 17 shows the influence of wave balance and DC offset on weld metal nitrogen recovery
in an example of the present invention; and
315 FIGURE 18 depicts the joint design of an example weld performed in accordance with an
exemplary embodiment of the present invention.
EXEMPLARY EMBODIMENTS OF THE INVENTION
In the electric arc welding industry, short arc welding is a common practice and involves the four
stages I, II, III and IV as schematically disclosed in FIGURE 2. The power source for performing short
320 arc welding can be a transformer based power source; however, in accordance with an exemplary
embodiment of the present invention, system A, shown in FIGURE 1, utilizes a high switching speed
inverter based power source B having an AC supply across lines 10, 14, or a three phase supply, directed
to inverter 14 creating a first DC signal across lines 14a, 14b. In accordance with standard architecture,
boost or buck converter 20 is used in power source B for correcting the input power factor by creating a
325 controlled second DC signal across output lines 22, 24. High switching speed inverter 30 converts the
second DC signal across lines 22, 24 to a waveform created by a large number of current pulses across
output leads 32, 34. In accordance with an exemplary embodiment of the present invention, the
waveform across leads 32, 34 is either DC positive or AC; therefore, inverter 30 has an output stage, not
^ shown, that dictates the polarity of the profiled waveform across leads 32, 34. These lead^ are connected
330 to electrode E and workpiece WP, respectively. In accordance with standard short arc technology,
electrode E is an advancing end of wire W supplied through contact tip 42 Irom supply spool or drum 40.
Thus, wire W is driven toward workpiece WP at a given WFS as a controlled waveform having the
desired polarity is created across the gap between electrode E and workpiece WP. In an embodiment of
the invention, the wire W is a flux cored wire schematically illustrated in FIGURE lA and shown to
335 include an outer low carbon steel sheath 50 surrounding an internal flux core 52 having a fluxing agent
15
and normally including alloying particles, also known as a self-shielded wire or electrode. An
embodiment of the electrode will be discussed in more detail below.
Shunt 60 drives feedback current device 62 so the voltage signal on line 64 is representative of
the instantaneous arc current of the welding process. In a like manner, device 70 creates a signal on
340 output line 72 representative of the instantaneous voltage of the welding process. Controller C of inverter
30 is a digital device, such as a DSP or microprocessor, that performs ftinctions schematically illustrated
in generally analog architecture. As a central component of controller C a waveform generator 100
^ ^ processes a specific waveform from a state table stored in memory unit 102 and selected according to the
desired welding process by device or circuit 104. Upon selecting the desired short arc welding process a
345 select signal 104a is directed to memory unit 102 so that the state table defining the attributes and
parameters of the desired short arc welding waveform is loaded into waveform generator 100 as indicated
by line 102a. Generator 100 outputs the profile of the waveform at any given time on output line 100a
with the desired polarity indicated by the logic on line 100b. Illustrated power source B controlled by
digital controller C is of the current control feedback type wherein the current representative voltage on
350 line 64 is combined with the waveform profile signal on line 100a by error amplifier 110 having an output
signal on line 110a to control pulse width modulator 112 in accordance with standard waveform control
technology. The output signal on line 112a controls the shape of the waveform across lines 32, 34 and the
polarity of the particular waveform profile being implemented is set by the logic on line 100b. In this
manner, waveform generator 100 controls pulse width modulator 112 to have pulses in line 112a
355 controlling the high fi-equency operation of inverter 30. This inverter switching frequency is generally
greater than 18 kHz and preferably greater than about 40 kHz. As so far described, power source B with
controller C operates in accordance with standard technology pioneered by The Lincoln Electric
Company of Cleveland, Ohio. Controller C is digital, but illustrated in analog format. To implement a
short arc welding process, it is necessary for controller C to receive feedback information regarding a
360 short circuit condition between electrode E and workpiece WP. This feature of controller C is
16
schematically illustrated as a short circuit detector 120 that creates a logic on line 122 to announce the
existence of a short circuit event SC to waveform generator 100. Thus, the generator is informed when
there is a short circuit and implements a waveform in accordance with processing a short circuit as
accomplished in any short arc welding process. As so far described, controller C is standard technology,
365 with the exception of controlling a polarity switch at the output of inverter 30 by the logic on line 100b.
To practice the invention, controller C is provided with a circuit 150 for controlling the melting
pulse preparatory to the short circuit. Circuit 150 is digital, but schematically illustrated in analog
^ architecture. The functions are implemented by the digital processor of controller C to control the energy
of the melting pulse. Such energy control circuitry is described in prior copending application Serial No.
370 11/103,040 filed by applicant on April 11, 2005. This prior application is incorporated by reference
herein not as prior art, but as related technology. As shown in the prior application, the energy of the
melting pulse of a pulsed welding waveform can be controlled by circuit 150 including multiplier 152 for
multiplying the instantaneous signal on lines 64, 72 to provide a signal on line 154 representing the
instantaneous watts of the welding process. The wattage signal or line 154 is accumulated by a standard I
375 integrator 156 as described in Parks 4,866,247. Integration of the watt signal on line 154 is controlled by |
waveform generator 100 that creates a pulse start command shown as block 160 to correspond to the start
of the melting pulse indicated by logic on line 162. The starting point is the time ti when the melting
pulse is started by waveform generator 100. Output signal on line 164 starts integration of the watt signal
on line 154 by integrator 156. The integration process is stopped by a logic on line 170 produced by
380 activation of stop pulse device or circuit 172 upon receipt of logic on input line 172a. Logic on line 172a
toggles device 172 to change the logic in output lines 172a and 172c. The logic on line 172c Informs the
waveform generator that the melting pulse is to stop to change the profile on output line 100a. At the
same time, the signal on line 172b toggles reset device or circuit 174 to change the logic on line 170 to
stop integration of the instantaneous watt signal. The digital number on output line 156a is loaded into
385 digital register 180 having an output 182 representing the total energy of a given melting pulse in the
17
i
short art welding process. This total energy signal is compared with a desired energy level stored in
register 190 to provide a digital number or signal on line 192. Comparator 194 compares the actual
energy for a given pulse represented by a number on line 182 with a desired energy level indicated by the
number on line 192. The relationship between the actual energy and the desired energy controls the logic
390 on line 172a. When the signal from line 182 equals the signal on line 192, comparator 194 changes the
logic on line 172a to stop the pulse as indicated by device or circuit 172. This stops integration and stops
the melting pulse being created by waveform generator 100. Circuit 150 is employed for performing an
exemplary embodiment of the present invention which changes the reference or desired energy for the
melting pulse by changing the number on line 192 through adjustment of circuit 200. The pulse is
395 stopped when the adjusted energy or energy threshold is reached as determined by the number signal on
line 182 as compared to the signal on line 192. In an embodiment of the present invention, the power
source and method used adjusts circuit 200 to change the reference energy for performing a short arc
welding process by changing the melting pulse.
Short arc welding system A using power source B with digital controller C is operated by
400 adjusting circuit 200 to perform the waveform shown in FIGURE 3. AC current waveform 200 has a
negative melting pulse 212 represented by stage I in FIGURE 2 where the melting pulse produces molten
metal 220 on the end of electrode E. The level of current in pulse 212 is below current needed for spray
arc so there is a transfer by a short. The time ti starts the Joule measurement, as explained later. The
pulse has a start position 212a at time ti and a stop position 212b at time t2. Following the melting pulse,
405 in accordance with standard practice, there is a positive low current quiescent transfer section 214, as
represented by stage II of FIGURE 2. In this stage, the molten metal 220 on the end of advancing
electrode E is formed into a ball by surface tension action awaiting a short circuit which occurs at time t3
and is shown as stage III. Consequently, the time between t2 and h is the time between the end of the
melting pulse and the short circuit event, which time is indicated by the logic on line 122 as shown in
410 FIGURE 1. After stage II, a current pinch action shown as neck 222 separates the molten metal 220 from
I
J
puddle 224. This electrical pinching action shown in stage IV is accelerated in accordance with standard
practice by a negative short circuit pulse 216 having a first current section 216a with a steep slope and
followed by a second current section 216b with a more gradual slope. Ultimately, the shorted metal
separates and the SC logic on line 122 shifts to start the next current pulse at time ti indicated by a
415 transition section 218. Waveform 210 is an AC waveform having a negative melting pulse 212, a low
current quiescent section 214 and a clearance pulse 216 transitioning into the next negative pulse 212 at
time ti. The corresponding voltage has a waveform 230 with negative section 232, a low level positive
section 234 that plunges at short 236 and is followed by a negative voltage section 238 that transitions at
section 240 into the next melting pulse voltage 232. The total cycle time is from ti to the next ti and the
420 positive transfer 214 has a time less than 20% of the total cycle time. This prevents stubbing.
The present invention involves a power source and method for controlling waveform 210 by
waveform generator 100 of controller C so the time between the end of melting pulse 212 at t2 and the
time of the actual short event t3 is constant based upon adjustment of circuit 200. This time delay
adjustment, in an exemplary embodirnent, is accomplished by the circuit 250 shown in FIGURE 4. In this
425 circuit, the time between the melting pulse and at time t2 and the short circuit at time ta is set to a desired
level between 0.5 to 2.0 ms. In one embodiment, the set desired time delay is 1.0 ms, which is the level
of the signal on line 254. Thus, the numerical number on line 254 is the desired time t2 to h. The actual
time between t2 and h is determined by timer 260 which is started at time t2 and stopped at time h. The
timer is reset for the next measurement by an appropriate time indicated as ts which can be adjusted to be
430 located at various positions after ts. which position is illustrated to be during the melting pulse in FIGURE
3. The number on line 262 is the actual time between t2 and tj. This actual time is stored in register 270
which is reset at any appropriate time such as time t2. Thus, the digital data on line 272 is the actual
measured time between t2 and .ts. This time is compared to the desired time on line 254. Any error
amplifier can be used to digitally process the relationship of actual time to the set time. The process is
435 schematically illustrated as a summing junction 280 and digital filter 282 having an output 284 for
19
adjusting circuit 200. The difference between the desired time and the actual time is an error signal in
line 284 which increases or decreases the desired total energy of circuit 200. The desired total energy is
periodically updated at an appropriate time indicated as t2 by an update circuit 290. Thus, at all times the
signal in line 192 of FIGURE 1 is the desired total energy for pulse 212 of the short arc process. This
440 total energy is adjusted by any difference between time t2 and time ts so the energy of pulse 212 maintains
a constant or desired time delay for the upcoming short circuit. This time control stabilizes the short arc
welding process of system A.
^ In FIGURE 4, an exemplary embodiment of the power source is implemented by changing the
energy threshold for the melting pulse to change the timing between the pulse and the short event. This
445 time can also be changed by voltage or power of the melting pulse as schematically illustrated in
FIGURES 5 and 6. In both of these embodiments, the time of the melting pulse ti to ti is maintained
fixed as indicated by block 300. During this constant time melting pulse, the voltage or power is changed
to control the time between the pulse and the short circuit event. In FIGURE 5, the number on output line
284 fi-om filter 282 controls feedback loop 310 to adjust the voltage of the melting pulse, as indicated by
450 the numerical data on line 312. To adjust the power for controlling the delay time of the short circuit i
event, the number on output line 284 is used to adjust feedback loop 320, which is compared to the
^ instantaneous power on line 154 by waveform generator 100. The change in power is a numerical value
on line 322 which is compared to the digital number on line 154 for controlling the power of the melting
pulse. Thus, in embodiments of the present invention, the total energy of the waveform, the voltage of the
455 waveform or the power of the waveform is adjusted to maintain a constant time between tj to ts to
stabilize the arc and control the short circuit events of system A shown in FIGURE 1.
In accordance with another embodiment of the power source, the energy adjustment of melting
pulse 212 is combined with the two modifications of the present invention illustrated in FIGURES 5 and
6. Such combination controls are shown in FIGURES 7 and 8 wherein prior summing junction 280 and
460 digital filter 282 are illustrated as combined in analog error amplifier 330. The component or program
20
has output 332 with a logic for stopping the melting pulse when the threshold energy has been reached, as
indicated by the logic on line 182. Thus, the total energy of the pulse is controlled together with the pulse
voltage control circuit 310 in FIGURE 7 and the pulse power control 320 as shown in FIGURE 8. Output
312 is combined with output 172c for controlling the waveform profile in line 100a of generator 100. In a
465 like manner, the energy level is controlled by logic on line 172c in combination with the digital
information on output line 322 of power pulse control circuit 320. Other combinations of parameters can
be used to control melting pulse 212 to assure an accurate control of the time between the melting pulse
and the short circuit event.' Such other parameters are within the skill of the art in controlling a waveform
generator by closed feedback loops.
470 In an exemplary embodiment of the present invention, the process is an AC process, as shown in
FIGURE 4; however, DC positive waveform 400 can be used as shown in FIGURE 9. Melting purse 402
has a high positive current 402a until the pulse is terminated at time t2. The current, in the DC positive
mode, is limited to a level below that needed for spray arc so the metal is not detached without shorting.
This concept defines the short arc welding process. Then the waveform transitions into a low level j
475 positive current section 404 awaiting the short at time ts. This low level positive current is used in an
exemplary embodiment of the present invention and terminates at time ts. Thereafter, short clearing pulse
^ 410 is created by the waveform generator. Pulse 410 has high ramp area 412 and a stepped area 414 to
bring the current back up to the high current level 402a. Various illustrated embodiments of the present
invention can be used in implementing the positive current waveform 400; however, the logic on line
480 100b for controlling the polarity of the output waveform on lines 32, 34 is not necessary.
An exemplary embodiment of the power source is in pipe welding operation using a flux cored
electrode as schematically represented in FIGURE lA. Such pipe welding operation is schematically
illustrated in FIGURE 10 wherein pipe sections 420, 422 define an open root 424. The present invention
as shown in FIGURE 4 controls the waveform on wire W as it moves through contact tip 42 to open root
485 424 of the pipe joint. FIGURE 10 shows a particular embodiment using the present invention for welding
21
i
the root pass of a pipe joint to tack the pipe sections together for subsequent joining with standard
welding techniques.
In certain embodiments, the power sources and/or welding operations according to the present
invention exhibit one or more of the following aspects. The current density is generally less than that
490 required for spray welding since the primary mode of metal transfer is short circuit welding. As in many
short circuit processes, a pinch current is established depending upon the wire diameter, for example for a
5/64 inch flux cored wire, a current of 625 amps can be used. Generally, the positive current tends to set
^ ^ the arc length. If the positive current is allowed to reach the same level as the negative current arc length,
even for half a millisecond, the positive current arc will reach a non-desirable length. Generally, positive
495 side control current is in the range of from about 50 amps to about 125 amps, and in one embodiment is
about 75 amps. The negative portion of the wave shape can either be a constant power or voltage with a
slope of from about 5 to 15 percent current. Typically, welding can be performed at about 60 hertz, 10
percent positive. Since the positive current is set at a relatively low level, the portion that the wave shape
is positive is typically less than 20 percent.
500 FIGURES 11 and 12 schematically illustrate a waveform technology welder and/or welding
system 510, and a cored electrode 530. The welding system comprises a welder 510 having a torch 520
^ for directing an electrode 530 toward workpiece W. The welding system 510 includes a three phase input
power supply LI, L2, and L3, which is rectified through rectifier 550, 560, and a power source 540. The
power source 540 provides an output, and specifically, an AC waveform as described in U.S. application
505 Serial No. 11/263,064, filed October 31, 2005, previously incorporated by reference. An arc AC is
created between the end of electrode 530 and workpiece W. The electrode is a cored electrode with a
sheath 600 and an internal filled core 610. The core includes flux ingredients, such as represented by
particles 610a. The purpose of these ingredients 610a is to (a) shield the molten weld metal from
atmospheric contamination by covering the molten metal with stag, (b) combine chemically with any
510 atmospheric contaminants such that their negative impact on the weld quality is minimized and/or (c)
22
generate arc shielding gases. In accordance with standard practice, core 610 also includes alloying
ingredients, referred to as particles 610b, together with other miscellaneous particles 610c that are
combined to provide the fill of core 610. In prior applications, to optimize the welding operation, it has
been necessary to use solid wire with an external shielding gas. However, in order to produce a weld with
515 specific mechanical and metallurgical properties, specific alloys are required, which can be difficult to
obtain in the form of a solid wire. Further, gas shielding is not always a feasible alternative due to access
to gas or difficulty to achieve adequate shielding due to windy conditions, accessibility to clean gas
mixtures and difficult terrains. It is, therefore, advantageous to use a self shielding cored electrode, so
that the environment does not affect the welding, as in the present invention.
520 A common problem caused when using cored electrodes without control of the welding
waveform profile is illustrated in FIGURE 13. The welding process melts sheath 600 to provide a portion
of molten metal 630 melted upwardly around the electrode, as indicated by melted upper end 640. Thus,
the sheath of the electrode is melted more rapidly than the core. This causes a molten metal material to
exist at the output end of electrode 530 without protective gas or chemical reaction created by melting of
525 the internal constituents of core 610. Thus, arc AC melts the metal of electrode 610 in an unprotected
atmosphere. The necessary shielding for the molten metal is formed when the sheath and core are melted
at the same rate. The problem of melting the molten metal more rapidly than the core is fiirther indicated
by the pictorial representation of FIGURE 14. Molten metal 650 Irom sheath 600 has already joined
workpiece W before the core 610 has had an opportunity to be melted. Thus, the core 610 can not
530 provide the necessary shielding for the welding process. FIGURES 13 and 14 show the reason why AC
welding using cored electrodes has not been used for off-shore pipeline welding and other pipeline
welding. However, an AC waveform can be utilized to control the heat input when using a cored
electrode.
By controlling the precise profile for the AC waveform used in the welding process, sheath 600
535 and core 610 can be made to melt at approximately the same rate. The failure to adequately coordinate
23
the melting of the sheath with the melting of the core is one reason why a shielding gas SG, as shown in
FIGURE 15 may be used. The advantage of controlling the profile of the AC waveform is that external
shielding gas SG, may be avoided.
Although control of the AC waveform can lead to significant advantages, as previously noted, in
540 order to provide arc stability and appropriate melting temperatures and rates, the actual control of the AC
waveform, is quite complicated. And, even with the use of sophisticated AC waveforms, contamination
of the weld is possible. Contamination of welds formed by using sophisticated AC waveforms, is still
^ possible, even if shielding gas is used. Accordingly, in a preferred aspect of the present invention, certain |
electrode compositions are provided that, when used in conjunction with AC waveforms, can form strong,
545 tough, and durable welds, without significant contamination problems, and without the degree of control
otherwise required for the AC waveforms.
When welding by the method or power source, of the present invention, with a cored electrode, it
is desired to have the sheath and core melt at the same rate. This operation promotes homogeneous
mixing of certain core materials with the outer sheath, such that the mixture of molten materials
550 chemically resists the effects of atmospheric contamination. Alloying elements required to produce
desired weld metal mechanical and metallurgical characteristics are uniformly distributed in the weld
t^ metal. In addition, the protective benefits derived from slag and/or gas-forming constituents are
optimized. As previously noted, this situation is illustrated in FIGURE 15. In contrast, FIGURE 14
illustrates a situation where the sheath has melted more rapidly than the core. In this deleterious situation,
555 molten metal 650 from sheath 500 has already joined workpiece W before core 610 has had an
opportunity to be melted. Metal 650 has not been protected from the effects of atmospheric
contamination to the degree that it would have been if the unmelted core constituents had actually been
melted. Additionally, alloying elements needed to achieve desired mechanical and metallurgical
characteristics may be missing from molten metal 650.
24
560 As previously indicated, an electric welder of the type using waveform technology can be used
for AC welding using a cored electrode, such as electrode shown in FIGURE 16. Such electrode includes
an outer steel sheath 710 surrounding core 720 formed of particulate material, including alloying metals
and slag or flux materials. By having internal flux or slag materials, there is no need for external
shielding gas during the welding operation. By including alloying material in core 720, the puddle of
565 weld metal 740 on workpiece 730 can be modified to have exact alloy constituents. This is an advantage
and reason for using cored electrodes, instead of solid welding wire where alloying must be accomplished
by the actual constituent of the welding wire. Adjustment of alloying for the weld metal is quite difficult
when using solid welding wire. Therefore, it is advantageous in high quality welding to employ a cored,
i.e. self-shielded electrode. Arc AR melts sheath 710 and melts constituents or fill in core 720 at a rate
570 which can be controlled to be essentially the same. Contamination in weld metal 740, such as hydrogen,
nitrogen and oxygen can cause porosity problems, cracking and other types of physical defects in the
weld metal. Thus, it is a challenge to design the welding process to exclude contaminates from the
molten weld metal. It is common to use "killing" agents, typically silicon, aluminum, titanium and/or
zirconium which will combine chemically with potential contaminates to prevent them from forming
575 porosity or harmfiil inclusions in the weld metal. Furthermore, "scavengers" may also be added to react
with hydrogen containing a species in order to remove hydrogen from the weld. In order to deposit
^ ^ consistently sound weld metal 740, it has often been necessary to add such killing agents in quantities that
are themselves detrimental to properties of the weld metal, such as ductility and low temperature
toughness. Thus, it is desirable to reduce the exposure of the molten metal in arc AR to prevent
580 contamination of the metal passing from electrode 700 to workpiece 730 so the killing agents can be
minimized.
The electrode compositions, of the present invention, when used in AC welding, produce
desirable welds that are durable, tough, and which are not susceptible to problems otherwise associated
with the use of conventional electrode compositions. The electrode compositions of the present invention
25
585 may be used in conjunction with AC waveforms where the positive and negative shapes of the AC
waveform are modified to reduce the overall arc length LA. In this maimer, there is less exposure to the
atmosphere and less time during which the metal is molten. A detailed description of the AC waveforms
and related welding processes, for which the present invention electrode compositions are designed, is set
forth in U.S. application Serial No., 11/263,064, filed October 31, 2005, previously incorporated by
590 reference. Indeed, by reducing the arc length, the temperature of the molten metal can be reduced as it
travels from the electrode 700 to weld metal puddle 740. Typically, when using a welder that can
perform an AC welding process with different shapes for the negative and positive sections, AC welding
with cored electrodes can be used effectively in the field. Parameters of the positive and negative
portions of the alternating waveform can be independently adjusted to compensate for and optimize the
595 melting of both sheath 710 and cored 720 for selected electrode 700.
More specifically, an embodiment of the present invention involves the combination of an
electrode and an AC welding wherein the positive and negative sections of the waveform are individually
adjusted to accomplish the objective of a low arc length and reduce contamination. Using this strategy,
the electrode composition of the present invention, particularly because it is self-shielding, can provide
600 significant advantages. The electrodes are used without shielding gas and depending upon the particular
^ application, can rely on deoxidizing and denitriding agents in the core for additional protection from
atmospheric contamination.
Thus, an embodiment of the present invention provides a synergistic system of a welding method
with a unique set of alloying and flux components in the core of a FCAW-S electrode. As noted, a cored
605 electrode is a continuously fed tubular metal sheath with a core of powdered flux and/or alloying
ingredients. These may include fluxing elements, deoxidizing and denitriding agents, and alloying
materials, as well as elements that increase toughness and strength, improve corrosion resistance, and
stabilize the arc. Typical core materials may include aluminum, calcium, carbon, chromium, iron,
manganese, and other elements and materials. While flux cored electrodes are more widely used, metal-
26
610 cored products are useflil for adjusting the filler metal composition when welding alloy steels. The
powders in metal-cored electrodes generally are metal and alloy powders, rather than compounds,
producing only small islands of slag on the face of the weld. By contrast, flux cored electrodes produce
an extensive slag cover during welding, which supports and shapes the bead.
The alloy/flux system, of the present invention, comprises particular amounts of a barium source,
615 particular amounts of a lithium source, lithium oxide, iron oxide, and optional amounts of calcium oxide,
silicon oxide, and manganese oxide. One or more fluoride, oxide and/or carbonate salts of barium can be
g^ used for the barium source. And, one or more fluoride and/or carbonate salts of lithium can be used for
the lithium source. The alloy/flux system is included in the electrode fill. The electrode fill generally
constitutes fi-om about 18 to about 24% of the electrode. An exemplary embodiment of the alloy/flux
620 system comprises:
fi"om about 35 to about 55% barium fluoride as the barium source,
from about 2 to about 12% lithium fluoride as the lithium source,
fi-om about 0 to about 8% barium carbonate as a secondary barium source,
fi-om about 0 to about 8% lithium carbonate as the secondary lithium source,
^^25 fi-om about 0 to about 15% of lithium oxide,
fi"om about 0 to about 15% of barium oxide,
fi"om about 5 to about 20% of iron oxide,
fi-om about 0 to about 5% of calcium oxide,
fi-om about 0 to about 5% of silicon oxide,
630 fi-om about 0 to about 5% of manganese oxide, and
27
up to about 25% of aluminum, magnesium, titanium, zirconium, or combinations tiiereof,
for deoxidation and denitriding and the remaining metallics optionally including iron, nickel, manganese,
silicon, or combinations thereof All percentages expressed herein are percentages by weight unless noted
otherwise. In an embodiment, the electrode fill composition comprises from about 35 to about 55%
635 barium fluoride, from about 2 to about 12% lithium fluoride, from about 0 to about 15% lithium oxide,
from about 0 to about 15% barium oxide, from about 5 to about 20% iron oxide, and up to about 25% of a
deoxidizing and denitriding agent as previously noted. In other embodiments, the previously noted
electrode fill composition can also include from about 0 to about 8% barium carbonate. In yet another
embodiment, the elecfrode fill composition may additionally include from about 0 to about 8% lithium
640 carbonate. In yet another embodiment, the fill composition can include from about 0 to about 5% calcium
oxide. In yet a fiirther embodiment, the electrode fill composition can include from about 0 to about 5%
silicon oxide. And, in another embodiment, the electrode fill composition can comprise from about 0 to
about 5% manganese oxide. Other embodiments include the use of one or more of these agents, i.e. the
barium carbonate, lithium carbonate, calcium oxide, silicon oxide, manganese oxide, and combinations
645 thereof
An exemplary embodiment of the method, of the present invention, comprises applying a first
negative voltage between an electrode and a substrate to cause at least partial melting of the electrode
near the subsfrate. The method also comprises applying a positive voltage between the elecfrode and the
substrate to promote formation of a flowable mass of material from the electrode. The method fiirther
650 comprises monitoring for occurrence of an electrical short between the electrode and the substrate through
the flowable mass. The method further comprises upon detecting an electrical short, applying a second
negative voltage between the elecfrode and the substrate. And, the method comprises increasing the
magnitude of the second negative voltage, to thereby clear the electrical short and form a weld on the
substrate from the flowable mass. The composition of the electrode fill in a flux cored electrode
655 comprises from about 35 to about 55% barium fluoride, from about 2 to about 12% lithium fluoride, from
28
about 0 to about 15% lithium oxide, from about 0 to about 15% barium oxide, from about 5 to about 20%
iron oxide, and up to about 25% of a deoxidation and denitriding agent selected from the group consisting
of aluminum, magnesium, titanium, zirconium, and combinations thereof In other embodiments,
additional agents can be incorporated in the electrode fill. For instance, from about 0 to about 8% barium
660 carbonate can be included. Another embodiment of the electrode fill composition includes from about 0
to about 8% lithium carbonate. Yet another embodiment includes from about 0 to .about 5% calcium
oxide. Another embodiment includes from about 0 to about 5% silicon oxide. And, yet another
embodiment includes from about 0 to about 5% manganese oxide. In yet a fiirther embodiment, one or
^ more of these agents can be added or otherwise included in the electrode fill composition. For example,
665 the elecfrode fill can also comprise, in addition to the previously noted proportions of barium fluoride,
lithium fluoride, lithium oxide, barium oxide, iron oxide, and one or more particular deoxidation and
denitriding agents from about 0 to about 8% barium carbonate, from about 0 to about 8% lithium
carbonate, from about 0 to about 5% calcium oxide, from about 0 to about 5% silicon oxide, and from
about 0 to about 5% manganese oxide.
670 The flux/alloy system is modified from traditional flux/alloy systems used for FCAW-S
elecfrodes to achieve the short arc length and to weld at low heat inputs that result from the unique
waveforms used in this process. The short arc length and the stable arc is a result of the combination of
the alloy and flux system and the unique characteristics of the waveform. In essence, both the welding
consumable and the process are optimized in tandem to achieve the final weld product requirements.
675 In certain embodiments, the present invention provides methods of forming weld metals having
attractive properties. Generally, these methods involve providing a welding wire or electrode having a
core with the previously described composition. In an embodiment, the welding wire or electrode is used
free of shielding gas, or rather agents that form such a gas. The methods also include an operation in
which the wire or electrode is moved toward the region of interest, such as a joint formed between two
680 sections of pipe. In an additional embodiment, such movement is made at a controlled feed speed. The
29
i
i method also includes creating a welding current to melt the wire or electrode by an arc between the wire
and the pipe sections to thereby form a molten metal bead in the joint. The method also includes
transferring the melted wire to the molten metal bead by a succession of short circuit events. The method
is particularly well suited for application to welding of a joint between two sections of pipe formed from a
! 685 metal having a yield strength of at least about 70 ksi and a thickness less than about 0.75 inches. In a
further embodiment, the invention can provide a weld, without the use of gas-shielding, having a yield
strength of at least 80 ksi, thus providing a weld which satisfies the requirements for welding at least
American Petroleum Institute (API) Grade X-80 line pipe. Further, an exemplary embodiment of the
^ present invention can achieve over 550 MPa yield strength and 690 MPa tensile strength, and a Charpy V-
690 Notch (CVN) toughness of over 60 Joules at -20 degrees C.
However, it will be appreciated that the present invention can be used in applications on pipes
having thicknesses greater than or less than 0.75 inches. In one embodiment, the resulting bead that is
I formed generally has a tensile strength greater than 70 ksi and in certain applications, greater than about
90 ksi. In particular aspects, the melting current can be negative. If the melting current is negative, the
695 metal transferring operation can be performed by a positive current. The metal transferring can however,
be performed by a positive current independent of the melting current. When performing the previously
described method, in one embodiment the average arc length is less than 0.30 inches, and in a fiirther
embodiment is less than 0.20 inches, and in another embodiment is less than 0.10 inches. In an
embodiment of the previously described method, the rate of the short circuit events is automatically
700 controlled. The rate of short circuit events is generally from about 40 to about 100 cycles per second.
In other embodiments, the previously described concepts, i.e. using the power sources and control
techniques in combination with the elecfrode compositions noted herein, can be utilized to produce a weld
metal having a minimum Charpy V-Notch toughness of 60J at -20°C. Similarly, the methods can be used
to produce a weld metal having a minimum Charpy V-Notch toughness of 40J at -40°C. And, the
705 methods can be used to produce a weld metal having a tensile strength exceeding 90 ksi. Thus, thin pipe
30
of less than about 0.75 inches can be used with the resultant savings. No shielding gas is needed, so the
cost of on site gas is eliminated, or greatly reduced.
The present application can be utilized in a wide array of applications. The system, process,
and/or compositions described herein are particularly adapted for use in welding at least X80 pipe (the
710 designation X80 being in accordance with the API 5L:2000 industry specification) with self-shielded flux
core wire. However, the present invention can be utilized in conjunction with other pipe grades. The
present invention can also be utilized in "root pass" or tack welding operations performed on pipes. The
^ present invention can be utilized to melt greater amounts of welding wire with less arc force as compared
to currently known practices of using a buried short arc for the initial welding pass. Yet another
715 application for the present invention is in robotic welding applications for high speed welding of thin
gauge metals.
EXAMPLE
The following discussion is directed to an example of the present invention. The present
invention is not limited to the embodiment and results discussed below, but the following discussion is
720 provided to demonstrate the results achievable from an exemplary embodiment of the present invention.
A series of test welds were made using an embodiment of the present invention, in which a selfshielded,
flux cored electrode was used in a short arc welding process. In some tests a 0.062 inch
diameter Lincoln Innershield NR-233 was used. The welds were made at a constant wire feed speed and
travel speed. The welds were bead on plate welds, having three passes side-by-side, then two passes side-
725 by-side in a second layer on top of the first three passes. The plate surfaces were shot blasted prior to
welding to remove scale and dirt. The weld metal layer in the second layer was analyzed for nitrogen
content. Because no nitrogen was intentionally incorporated in the electrodes used, the following analysis
was (Conducted under the assumption that the nitrogen in the weld metal came from the ambient
atmosphere.
f
I
I
I
I I
t\730 Further, the welding power supply was constructed to produce alternating current with variable
waveforms, and the following characteristics of the AC waveform were varied:
"waveform balance" - the waveform balance is the percentage of the AC cycle time when the
electrode polarity is positive; and
"DC offset" - the DC offset is the measure of the degree to which the amplitudes of the positive
735 and negative portions of the waveform are unequal. A DC offset of-20 indicates that the amplitude of the
positive portion of the waveform was 19.4 volts, while the negative portion is 23 volts. Further, +20
^ indicates the reverse, i.e.-23 volts positive and 19.4 volts negative.
FIG. 17 depicts the influence of wave balance and DC offset on weld metal nitrogen recovery in
an example weld performed by an example of the claimed invention. As shovm in FIG. 17, the large data
740 point at 0% wave balance, 0.029% nitrogen recovery, is the result for the weld made with DC- current.
The two welds made at 10% wave balance, +20 DC offset, and the two made at 50% wave balance, -20
DC offset had significantly lower nitrogen recoveries than the DC- weld. Additionally, during testing it
was noted that nitrogen recoveries higher than that observed with DC- were observed with other
combinations of wave balance and DC offset.
745 Further, in additional embodiments the AC waveform can also be manipulated to control levels of
oxygen and hydrogen in the weld metal. Reducing overall levels of contamination reduces the need for
killing, scavenging, or geometry-modifying or solubility-limiting agents. Thus, alloy levels in the selfshielding
electrode can be optimized to achieve optimum physical properties in the weld metal.
The following Tables provide weld data and specifications of a weld example performed in
750 accordance with an embodiment of the present invention. In this example, a Pipeliner® electrode, from
The Lincoln Electric Company, Cleveland Ohio, was used in the 5G position according to the procedures
set forth below in Table 1. Additionally, FIG. 18 depicts a weld joint design structure corresponding with
the data shown in the Tables below. The metal welded 181 was API Grade X-80 having a 17 mm
32
thickness and the weld structure was as shown in FIG. 18. Further, as shown in FIG. 18, the weld passes
755 are shown as passes #1 through #9. Table 2 shows the mechanical test results of the weld performed in
accordance with Table 1. Finally, Table 3 shows the weld deposit chemistry of the example set forth in
Table 1.
Table 1 - Welding Procedures:
Pass 1 (Root) I 0.045" Pipeliner® 70S-G (ER70S-G) I
Semi-automatic 155A, 17.5 V DC+
Vertical-down WFS 4.1 m/min (160 in/min)
•
100% CO2 I STTII: 400A Peak, 60A Back, 0 Tail I
Pass 2-9 (Hot-Cap) 2.0 mm Pipeliner® M2M80 (FCAW-S)
Semi-automatic 2OOA 21V
Vertical-down ^^g 2.3 to 2.5 m/min (90 to 100 in/min)
Position 5G Horizontal Fixed
Heat Input (avg.) 1.4kJ/mm I 35 kJ/in
Preheat/Interpass 65.56/121.1 °C 150/250 °F
Pipe API 5L X80 DSAW (Napa)
Rpo.2 (YSo.2%) 608 MPa 88.1 ksi
Diameter x Wall | 915 x17 mm | 36 x 0.667 in |
Table 2: Mechanical Test Results (weld metal - as welded):
I Tensile (ASTM E8) All weld metal, 6.35 mm (0.25 in) dia. I
Rpo.2 (YSo.2%) average 656 MPa 95 ksi
min-max 649-662 MPa 94-96 ksi
R„(UTS) average 725 MPa 105 ksi
min-max 718-731 MPa 104-106 ksi
A5(Elong.) average 25% 25%
min-max | 25-26% \ 25-26%
Charpy V-Notch (ASTM E23) Mid-wall, 10mm x 10mm
-20°C (-4°F) Average I 97J \ 75 ft-lb
min-max 83-117 J 64-91 ft-lb
-29°C (-20°F) Average 59J 46 ft-lb
min-max 35-77 J 27-60 ft-lb
33
-40°C (-40°F) Average I 411 \ 32 ft-lb ' 1
min-max 34-46 J 26-36 ft-lb
Table 3: Weld Deposit Chemistry (SPJ):
Chemistry (ASTME350) I
Element %
C 0.026
Mn 3.43
Si 0.10
P 0.010
•
S 0.009
Ni 0.77
Cr 0.03
Mo 0.01
B 0.0022
Ti 0.010
V 0.02
Nb 0.016
Al \ L06 I
The above example is intended to merely exemplary of an embodiment of the present invention,
and is not intended to limit the scope of the present invention in any way.
In an embodiment of the present invention the short arc welding device is a welding device which
employs a welding gun to continuously advance the electrode toward the workpiece to be welded. This is
^ similar to a MIG welding process. However, as indicated above, the process is a gas-less process using
self-shielding flux-cored electrodes. Further, the method of welding using the short arc welding system
and the disclosed electrode is a welding method similar to MIG welding, in that the electrode is
continuously advanced through a welding gun.
Moreover, fiirther to the discussions above, in fiirther embodiments of the present invention, the
welding device can be an engine driven machine or a fuel cell, or battery base, driven machine.
Additionally, the present invention may also be employed with automatic or robotic welding machines.
34
The present invention has been described with certain embodiments and applications. These can
be combined and interchanged without departing from the scope of the invention as defined in the
appended claims. The systems, methods, electrodes and combinations thereof as defined in these
appended claims are incorporated by reference herein as if part of the description of the novel features of
the synergistic invention.
•
35
I

" 1 f ^ g
I/We claim: "^'^ ^'^^ "* ^ / NA^ I
1. A method of welding a workpiece (WP) the method comprising:
advancing a self-shielding electrode (E) from a welding device toward a workpiece (WP); and
employing a short arc welding process to weld the workpiece (WP) using the advancing selfshielded
electrode (E),
wherein the weld has a yield strength of atleast 70 ksi
characterized by,
applying a waveform (210) across the self-shielding electrode (E) and workpiece (WP) over a
time-period (212a, 212a), the waveform comprising a melting pulse (212) and where the melting
pulse (212) is followed by a low current transfer cycle (214) and wherein the waveform is
positive for a time period (212a, 212a) having a first duration and the amplitude of the positive
portion of the waveform is higher than the amplitude of the negative portion of the waveform, or,
the waveform is positive for a second duration and the amplitude for a positive portion of the
waveform is less than an amplitude of the negative portion of the waveform,
and controlling the melting pulse by
measuring a duration time between said melting pulse and a short circuit during said transfer
cycle (214),
setting a desired time for said duration,
creating a corrective signal by comparing said measured duration and said set desired time, and
adjusting a parameter if said melting pulse based upon said corrective signal.
2. The method as claimed in claim 1, wherein the electrode is a flux cored self-shielding
electrode.
36
2. The method as claimed in claim 1, wherein the electrode is advanced through a welding gun
toward the workpiece.
4. The method as claimed in claim 1, wherein the yield strength is at least 80 ksi.
5. The method as claimed in claim 1, wherein the weld has a tensile strength of at least 70 ksi.
6. The method as claimed in claim 1, wherein the weld has a tensile strength of at least 90 ksi.
7. The method as claimed in claim 1, wherein the weld has a Charpy V-Notch toughness of at
least 60J at -20 degrees.
8. The method as claimed in claim 1, wherein the weld has a Charpy V-Notch toughness of at
least 40J at -40 degrees.
^ ^ 9. The method as claimed in claim 1, wherein the weld satisfies the requirements for welding at
least American Petroleum Institute Grade X-80 pipe.
10. The method as claimed in claim 1, wherein the self-shielding electrode is a self-shielded flux
cored arc welding wire.
11. The method as claimed in claim 1, comprising:
37
controlling a melting pulse of the short arc welding process, where the melting pulse is followed
by a low current transfer cycle, by
measuring a duration time between said melting pulse and a short circuit during said transfer
cycle;
setting a desired time for said duration;
creating a corrective signal by comparing said measured duration and said set desired time; and
adjusting a parameter of said melting pulse based upon said corrective signal.
•
12. The method as claimed in claim 1, wherein an average arc length during said short arc
welding process is up to 0.3 inches.
13. The method as claimed in claim 1, wherein an average arc length during said short arc
welding process is up to 0.2 inches.
14. The method as claimed in claim 1, wherein an average arc length during said short arc
welding process is up to 0.1 inches.
15. A welding apparatus; comprising:
a short arc welding system which advances an electrode toward a workpiece to be
welded;wherein said electrode is a self-shielding electrode; and
wherein said short arc welding system is controlled such that said weld has a yield strength of at
least 70 ksi
characterized in that,
38
the short art welding system comprises a controller (C) arranged to apply a waveform (210)
across the electrode (E)and workpiece (WP) over a time period (212a, 212a)
the waveform comprising a melting pulse (212) created by a waveform generator (100) of the
short arc welding system, where the melting pulse is followed by a low current transfer cycle
(214) and wherein the waveform is positive for a time period (212a, 212a) having a first duration
and the amplitude of the positive portion of the waveform is higher than the amplitude of the
negative portion of the waveform, or, the waveform is positive for a second duration and the
amplitude for a positive portion of the waveform is less than an amplitude of the negative portion
of the waveform, and fiarther provided
•
with a circuit (150) for controlling the melting pulse,
a timer (260) for measuring a duration time between said melting pulse and a short circuit during
said transfer cycle, and
an adjusting circuit (200) for creating a corrective signal by comparing said measured duration
time and a set desired time and for adjusting a parameter of said melting pulse based upon said
corrective signal. ^
16. A welding apparatus; comprising:
a short arc welding system which advances an electrode toward a workpiece to be
welded;wherein said electrode is a self-shielding electrode; and
wherein the weld satisfies the requirements for welding at least American Petroleum Institute
Grade X-80 pipe.
characterized in that,
the short art welding system comprises a controller (C) arranged to apply a waveform (210)
across the electrode (E)and workpiece (WP) over a time period (212a, 212a)
the waveform comprising a melting pulse (212) created by a waveform generator (100) of the
short arc welding system, where the melting pulse is followed by a low current transfer cycle
(214) and wherein the waveform is positive for a time period (212a, 212a) having a first duration
39
I
and the amplitude of the positive portion of the waveform is higher than the amplitude of the
negative portion of the waveform, or, the waveform is positive for a second duration and the
amplitude for a positive portion of the waveform is less than an amplitude of the negative portion
of the waveform, and further provided
with a circuit (150) for controlling the melting pulse,
a timer (260) for measuring a duration time between said melting pulse and a short circuit during
said transfer cycle, and
an adjusting circuit (200) for creating a corrective signal by comparing said measured duration
9 time and a set desired time and for adjusting a parameter of said melting pulse based upon said
corrective signal.
17. A welding apparatus; comprising:
a short arc welding system which advances an electrode toward a workpiece to be
welded;wherein said electrode is a self-shielding electrode; and
wherein the weld has a Charpy V-Notch toughness of at least 60 J at -20 degrees.
characterized in that,
the short art welding system comprises a controller (C) arranged to apply a waveform (210)
across the electrode (E)and workpiece (WP) over a time period (212a, 212a)
the waveform comprising a melting pulse (212) created by a waveform generator (100) of the
short arc welding system, where the melting pulse is followed by a low current transfer cycle
(214) and wherein the waveform is positive for a time period (212a, 212a) having a first duration
and the amplitude of the positive portion of the waveform is higher than the amplitude of the
negative portion of the waveform, or, the waveform is positive for a second duration and the
amplitude for a positive portion of the waveform is less than an amplitude of the negative portion
of the waveform, and further provided
with a circuit (150) for controlling the melting pulse,
•
40
a timer (260) for measuring a duration time between said melting pulse and a short circuit during
said transfer cycle, and
an adjusting circuit (200) for creating a corrective signal by comparing said measured duration
time and a set desired time and for adjusting a parameter of said melting pulse based upon said
corrective signal.
Dated: this 28.07.06 ^ yJcU^J^
[R. MAHESH]
OF REMFRY & SAGAR
^ ATTORNEY FOR THE APPLICANT[S]
41

Documents:

1729-del-2006-Abstract-(12-08-2013).pdf

1729-del-2006-abstract.pdf

1729-del-2006-Claims-(12-08-2013).pdf

1729-del-2006-claims.pdf

1729-del-2006-Correspondence-others (21-11-2012).pdf

1729-del-2006-Correspondence-Others-(12-08-2013).pdf

1729-del-2006-correspondence-others-1.pdf

1729-del-2006-correspondence-others.pdf

1729-del-2006-Description (Complete)-(12-08-2013).pdf

1729-del-2006-description (complete).pdf

1729-del-2006-Drawings-(12-08-2013).pdf

1729-del-2006-drawings.pdf

1729-del-2006-form-1.pdf

1729-del-2006-form-18.pdf

1729-del-2006-Form-2-(12-08-2013).pdf

1729-del-2006-form-2.pdf

1729-del-2006-Form-3 (21-11-2012).pdf

1729-del-2006-form-3.pdf

1729-del-2006-form-5.pdf

1729-del-2006-GPA-(12-08-2013).pdf

1729-del-2006-gpa.pdf

1729-del-2006-Petition-137 (21-11-2012).pdf

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Patent Number

258820

Indian Patent Application Number

1729/DEL/2006

PG Journal Number

07/2014

Publication Date

14-Feb-2014

Grant Date

10-Feb-2014

Date of Filing

28-Jul-2006

Name of Patentee

LINCOLN GLOBAL, INC.

Applicant Address

14824 MARQUARDT AVENUE, SANTA FE SPRINGS, CA 90670, U.S.A.

Inventors:

#	Inventor's Name	Inventor's Address
1	BADRI NARAYANAN	6809 MAYFIELD ROAD, #367 SHAKER HEIGHTS, OH 44124, USA.
2	PATRICK T. SOLTIS	2525 KEMPER ROAD, #405 SHAKER HEIGHTS, OH 44120-1263, USA.
3	RUSSELL KENNETH MYERS	237 SUNSET DRIVE, HUDSON, OH 44236, USA.
4	ERIC STEWART	6628 MCKEE ROAD, GIRARD, PA 16417, USA.

PCT International Classification Number

B23K9/09

PCT International Application Number

N/A

PCT International Filing date

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	11/382,084	2006-05-08	U.S.A.