Title of Invention

A LASER BRUTING MACHINE

Abstract A Laser Bruting machine consists with (i) Diamond Holder (ii) Set up device (iii) Processing device. In fig.2 diamond holder (8) consists of rough diamond (5), stitching die (6) & magnetic die (7) wherein the rough diamond (5) is centered on the top of stitching die (6). The stitching die(6) is then fixed on top of the magnetic die(7). In Fig.3 setup device (3) consist of CNC interface & video system. After centering the diamond, Processing device (4) consist of CNC Interface, Heat Exchanger (25), Video system, Beam delivery mechanism (26), Laser source (27), RF-Q Switch driver (28), Power supply (29) & stabilizer. Beam delivery mechanism consists of (i) Bruting system (ii) Girdle polishing system. With the standard software an optimal cut to have accurate dimensions & shape. A Laser bruting machine gives more speed, reduces weight loss, keeps the shape of diamond uniform.
Full Text FORM - 2
THE PATENTS ACT, 1970
COMPLETE SPECIFICATION
[Section 10}
1. A LASER BRVTING MACHINE
2. (A) ARVINDBHAILAVJIBHAIPATEL
(B) 48/A, Arvind estate, Bapunagar, Ahmedabad-380 025 Gujarat, India.
(C) Nationality an Indian.
The following specification particularly describes and ascertains the nature of the invention and the manner in which it is to be
performed.




The present invention relates to A Laser Bruting Machine.
The diamond has always exercised an irresistible seductive power and acquired an almost mythical fame because ,it is the most expensive of gems and the hardest of all minerals. Each diamond stone must therefore be studied in detail in order to determine the most advantageous manner to work it with the least loss of weight. In its unpolished form, a diamond is a rather vague crystal form, without any real luster. Only a succession of process such as marking, cleaving, sawing, girdling, etc. gives it its final facet form and brilliance. Girdling is the rounding of the base of sawn (or cleaved) piece so that it has more or less the form of a polished diamond. In conventional machine to achieve girdling of rough diamond stone, the sawn diamond is mounted on the chuck of a lathe and the desired rounded form is achieved by turning it against another diamond, as the cutting tool. The excess surface of the rough diamond cut with the conventional machine is imprecise. During bruting process, the conventional bruting machine works with lower speed and has the higher weight loss of diamond. This is due to the cutting force spreads to other parts of the diamond. As each diamond is unique it has become imperative to develop new techniques in order to improve the productivity of the diamond industry. A laser bruting machine is invented to overcome above limitations experienced by conventional bruting machine. With a laser bruting machine, bruting becomes a non-contact very fast process compared to conventional bruting machine. As laser bruting being a non-contact process gives more speed,


reduces weight loss significantly and keeps the shape of diamond uniform. In laser bruting machine the computer is used to show the rough diamond clearly, so we can do bruting process with low diamond lose. With the standard software computer suggest an optimal cut to have accurate rounded shape of the diamond taking dimensions & shape into account. Also the rough diamond stone to be centered and bruted is lit up by illuminating sources and these illuminating sources consist of plurality of LED's so the eye gets the impression that is always the same side of the stone that is lit and hence the illuminated rough diamond can be watched on CCTV through video system consist of CCD cameras. This is a useful technique, because bruting machine can check the process at all times without stopping the machine. Summing up all the advantages productivity increases considerably with a laser bruting machine.
The present invention will be described with greater specific and clarity with reference to following drawings:
Fig. 1 represents front view of bruting machine.
Fig. \ represents diamond holder.
Fig. 3 represents top view of rough diamond with possible maximum diameter
Fig. 4 represents front view of setup device.
Fig. 5 represents side view of setup device.
Fig. 6 represents top view of setup device.
Fig. 7 represents front view of bruting processing system.


Fig. 8 represents front view of girdle polishing system.
Fig. 9 represents block diagram of Beam delivery, mechanism.
Fig. 10 represents trolley containing power supply and heat exchanger.
Fig. 11 represents block diagram of cooling system & chilling system of
heat exchanger. Fig. 12 represents front view of chilling water tank. Fig. 13 represents front view of split tank. Fig. 14 represents diamond Fig. 15 represents flow chart
Fig. 16a represents random/initial position of rough diamond stone. Fig. 16b represents position of center of rough diamond stone on X-axis. Fig. 16c represents position of rough diamond stone when it is centered.
In Fig.l a laser bruting machine consist of (i) diamond holder 8 (ii) Setup device 3 & (iii) processing device 4; In Fig.2 diamond holder 8 consist of stitching die 6, magnetic die 7 and rough diamond 5; In Fig J setup device 3 consist of maximum diameter diamond 61 on CNC interface & video system and in Fig.l processing device 4 consists of CNC interface, heat exchanger 25, video system, beam delivery mechanism 26, laser source 27, RF-Q Switch driver 28 ,power supply 29 & stabilizer.
Bruting machine 1 which is accommodated on aluminum frame 2 consists of mainly three sections.
(1) Diamond Holder 8
(2) Set up device 3


(3) Processing device 4 (1) Diamond Holder 8: A rough diamond 5 to be processed for Bruting or Girdle Polishing is stitched on top of the stitching die 6 by adhesive & heat. Due to magnetism of magnetic die 7, stitching die 6 is fixed on top of magnetic die 7. Combination of stitching die 6 and magnetic die 7 is referred to as Diamond holder 8.
An automated gemstone/rough diamond stone 5 centering and data management system is provided to setup device 3. The physical data of a rough diamond stone/gemstone 5 is determined relative to the measured spectral response of light energy incident to a gemstone 5. Gemstone 5 is illuminated by a plurality of light sources such that the spectral response of the gemstone 5 is captured as a pixel data set, gauged, quantified and recorded for future reference via CCD cameras. A setup device 3 provides a imaging station for the automated centering and quantifying physical data of gemstone 5. The video system/ imaging station is linked to computer/analysis station for communicating captured incident light data sets thereto. The analysis station/computer 16 employs a data processor and model database for assessing the physical data of the gemstone 5 by way of the communicated pixel data sets. The spectral response of a gemstone 5 to the incident light sources is quantified relative to model pixel data sets of the database and recorded for future reference therein. The operation of the setup device 3 is controlled by a control card and instruction set. The data processor/control card of the analysis station/computer 16 provides an


instruction set for facilitating communication with the setup device 3, analyzing
communicated pixel sets. The instruction set includes analytical and statistical
image models, which extract pertinent physical data of gemstone from the pixel
data sets. Additionally, the analysis station includes mass storage memory devices
for storing the reference value database; analysis instruction set, and report
information, which may include text as well as visual data. The physical data of
gemstone 5 are communicated from the setup device 3 to the computer 21 of
processing device 4 by means of LAN.
The control data processor/control card of the setup device 3 & processing device
4 provides an instruction set for automating the steps necessary to precisely
position and operate the imaging hardware. The imaging system/video system of
set up device 3 & processing device 4 extract consistently and accurately, size,
shape, and proportion information from the images of a gemstone 5 using the data
processing instruction set.
(2) Setup device 3 consist of CNC Interface & Video System
(I) CNC INTERFACE: CNC Interface of setup device 3 comprising of
Motorized X axis positioner 9, Motorized rotatable platform 11, Motorized
up/down positioner 12, Drive cards 13,14,15 , Control card , Computer 16 &
Stepper Motors.
(II)Video System of setup device 3 consists of Upper CCD Camera 17 & Lower
CCD camera 18.
For accurate girdling/rounding or to remove surrounding excess surface of rough


diamond 5 it is essential that rough diamond 5 should have rotating/circular motion around its center point for which it is required that rough diamond 5 along with stitching die 6 should be placed on center of top of the magnetic die 7 and it is done by CNC Interface, Computer 16 with standard software and Monitor 19. Example:
Because of the Video system, rough diamond 5 appears on the monitor 19. As upper CCD camera 17 & Lower CCD camera 18 are being used, one has option for watching rough diamond 5 either in elevation or plan view. Supposing surface of the rough diamond 5 is being selected by 3-point method considering top view/plan view of rough diamond 5. Then by mouse clicking three random end points of rough diamond 5 are selected and with standard software it gives physical data of rough diamond 5 and also puts stitching die 6 on center of top of the magnetic die 7 automatically using pusher rod 10 of motorized X axis positioner 9 & motorized rotatable platform 11. The physical data of rough diamond 5 & predicted finished diamond 20 as shown in Fig.14 can be accessed in processing device 4 as computers 16 & 21 of setup device 3 and processing device 4 respectively are connected with LAN. Functioning of CNC Interface of setup device 3 : Example:
Referring to Fig. 16a, assume that center of rough diamond 5 is P(x,y) and thus it is offset from 0(0,0). It represents initial position of rough diamond 5 placed on motorized rotatable platform 11 vertically.


Referring to Fig. 16b, computerized vision system will measure the angle to rotate and by rotary motion, center P of rough diamond 5 is brought on X axis through motorized rotatable platform 11. Stepper motor drives the motorized rotatable platform 11 and hence diamond holder 8 which is placed on motorized rotatable platform 11 also rotates aiid takes the position on X-axis. Referring to figloc, to match the center P with O, Pusher rod 10 which is fixed with Motorized X axis positioner 9 pushes P towards O and hence stitching die 6 is placed on center of top of magnetic die 7. Motorized X axis positioner 9 is driven by stepper motor.
If elevation view or plafl view of rough diamond 5 do not appear clearly on monitor 19 then Motorized up/down positioner 12 comes into action to give clear image of rough diamond 5 on monitor 19 by moving vertically. Motorized Up/down positioner 12 is driven by stepper motor.
Drive cards 13,14 & 15 are connected to motorized X- axis positioner 9, motorized up/down positioner 12 & motorized rotatable platform 11 respectively. Drive cards 13,14,15 are also connected with computer 16. Drive cards 13,14,15 amplify the electronic signal coming from computer 16 and provides amplified electronic signal to Motorized X axis positioner 9, Motorized up/down positioner 12, & Motorized rotatable platform 11. A control card which is placed in the computer 16 controls the movement of motorized X axis positioner 9, Motorized up/down positioner 12 & Motorized rotatable platform 11. Also limit switches are provided to each end of motorized X axis positioner 9, motorized rotatable


platform 11 & motorized up/down positioner 12 to sense the home & end position. To switch on or off the drive cards 13,14,15, drive card power supply 22 is connected to drive cards 13,14,15. (3) Processing device 4:
Diamond holder 8 is carried to processing device 4 following the process of centering the stitching die 6 on magnetic die 7. Diamond holder 8 is fixed horizontally on motorized rotatable platform 23. As computer 16 of setup device 3 and computer 21 of processing device 4 are connected via LAN and hence physical data of rough diamond 5 taken from setup device 3 is accessed on monitor 24 through standard software installed in computer 21 of processing device 4,
Mechanism of processing device 4:
Processing device 4 consist of CNC Interface, Heat Exchanger 25, Video system, Beam delivery mechanism 26, Laser source 27, RF-Q Switch driver 28 & Power supply 29.
(I) CNC Interface of processing device 4 consist of Motorized Y-axis positioner 30,Motorized rotatable platform 23, Motorized X axis positioner 31, Computer 21, Monitor 24, CCTV 32, Y drive cards 33, X drive cards 34, R drive card 35, drive card power supply 36 & three stepper motors to drive Motorized Y-axis positioner 30, Motorized rotatable platform 23 , Motorized X axis positioner 31 & control card.
(II) Heat Exchanger 25 consist of Cooling system 37, Chilling system 38 .Interlock system 39. Cooling system 37 associated with de-ionized water


circulation from cooling system 37 to Laser head 43'& Q-switch 42 and vice versa. Chilling system 38 associated with water circulation from Heat exchanger 25 to chilling pump system 48 and vice versa. Chilling pump system 48 consist of chilling water tank 70 & split tank 71. Heat exchanger 25 is connected to Power supply 29 via interlock cable and RF Q-switch driver. Interlock system 39 saves machine from getting damaged by switching off the power supply 29 automatically if (i) flow and/or (ii) level and/or (iii) temperature of de-ionized water unnecessarily decreases or increases. Interlock system 39 of heat exchanger 25 comprising of flow LED 49, Level LED 50 & Temperature LED 51. (Ill) Video system: Video system of processing device 4 comprising of upper CCD Camera 52 and lower CCD camera 53.
(TV) Beam delivery mechanism 26 of processing device 4 consists of (i) Bruting process system 54 and (ii) Girdle polishing system 55. Bruting process system 54 consists of (a) sliding beam bender 56 (b) lower beam bender 57 & (c) lower focusing device 58. Girdle Polishing system 55 consist of (a) upper beam bender 59 (b) upper focusing device 60. Sliding beam bender 56, lower beam bender 57 and upper beam bender 59 are placed at 45° with respect to incoming laser beam.Lower focusing device 58 and upper focusing device 60 have illuminating source to illuminate rough diamond 5. Each illuminating source has plurality of LED's.
(V) Laser Source 27 consist of back mirror 40, Apertures 41,41, Q-switch 42, Laser head 43, shutter 44, polariser 45, front mirror 46 & beam expander 47.


Laser head 43 is the crucial part to generate the laser light. Front mirror 46 and back mirror 40 amplifies the laser light by providing feedback. Q-switch 42 is used to store the laser light energy to emit as a burst of high peak power. Safety shutter 44 blocks the laser beam in case of electrical failure. Safety shutter terminates laser by blocking the laser beam path and preventing emission of laser radiation out of the laser source. The safety shutter 44 is actuated by toggle switch. Apertures 41,41 restrict the light amplification along the off-axis of the resonator to provide sharp frequency band. Beam expander 47 expands the laser beam to minimize its divergence. To polarize laser beam polarizer 45 is used. (VI) RF-Q Switch driver 28: To get the pulsed laser output with high peak power, the laser is operated in Q-Switch mode. The transducer in acoustic-optic Q-switch 42 requires RF power for operation of Q-switch 42 and such requirement is fulfilled by RF-Q Switch driver 28. The RF source is pulsed at frequencies from 0.1 KHz to 50KHz corresponding to the desired pulse repetition rate of the laser. The quartz cell being switched with such a high frequency needs cooling. Therefore the Q-switch 42 also becomes cool. To operate Q-Switch 42 in pulsed mode, RF-Q Switch driver 28 is connected to Q-Switch 42,heat exchanger 25 and computer 21. Computer 21 sends the frequency data to RF-Q switch driver 28 and accordingly laser in laser source is operated in Q-switch mode. As Q-switch 42 is being switched with such a high frequency, it is cooled by circulation of de-ionized water for repetitive operations and therefore interlock system is provided. (VII) Power supply 29: It ignites and controls the intensity of the laser light



emitted by the laser lamp (Kr/Xe arc lamp). The intensity of light produced by the lamp is used for pumping die Nd atoms in Nd.YAG rod. Once the discharge in the lamp is produced, then by changing the current flowing through the lamp, the intensity of light emitted by the lamp can be controlled. In many applications laser is not used continuously and therefore the power supply 29 is provided with a special feature of standby mode which keep alive the discharge in the lamp by producing the optimum current required for the lamp to maintain the discharge in lamp. This particular arrangement is very useful in increasing the operational life of the lamp and also that of power supply. Because this will save the whole process of generating the trigger pulse for igniting the lamp. Functioning of Processing Device 4:
A diamond holder 8 which consist of stitching die 6 and magnetic die 7 is carried from setup device 3 and fixed horizontally to motorized rotatable platform 23. In bruting process laser beam coming from laser source 27 falls on sliding beam bender 56 from which it falls on lower beam bender 57 and hence laser beam coming from lower beam bender 57 which is then focused by lower focusing device 58 and finally the focused laser beam falls on gemstone/roughr diamond stone 5. And therefore maximum diameter 61 of rough diamond stone/ gemstone 5 is achieved by removing excess surface from it by rotary motion and displacement on particular axis.
Also maximum diameter 61 of rough diamond 5 is achieved with the girdle polishing process. In girdle polishing process laser beam coming from laser


source 27 falls on upper beam bender 59 bypassing sliding beam bender 56. A laser beam coming from upper beam bender 59, which is then focused by upper focusing device 60 and hence focused laser beam falls on rough diamond stone 5. Application of Bruting process 54 or Girdle polishing process 55 is to obtain maximum diameter 61 from rough diamond 5 by removing excess surrounding surface from rough diamond 5. After Bruting process 54 or Girdle polishing process 55 the shape of rough diamond 5 is converted into cylindrical shape in general. To remove excess surrounding surface of rough diamond 5 laser beam from laser source 27 is used.
Procedure for Switching on Heat exchanger 25 & Power supply 29 : Pump on/off knob 62 is accommodated in Heat exchanger 25, which is kept "on" initially and Pump LED 63 is operated by Pump on/off knob 62. Also digital temperature controlling unit 72 & Inter lock system 39 are provided to heat exchanger 25. Then in Power supply 29, T.P. 64 and Lamp 65 switches are switched "on" to trigger laser lamp of laser source 27. Also as power supply 29 is connected with heat exchanger 25 via interlock cable and therefore interlock LED 66 is provided on power supply 29. Push button switch "Push for control" 67 is pressed to start current setting unit 68. The value displayed in current setting unit 68 can be varied by current variable knob 69. Current setting unit 68 is provided to have desired watt for cutting the surrounding excess surfaces of rough diamond 5. Heat exchanger 25 & Power supply 29 are accommodated in trolley 99.


Example:
The required heat in form of laser beam to cut the surrounding excess surface of the rough diamond 5 depends on the diamond quality. Supposing for a rough diamond 5 the required watt to cut the surrounding excess surface is 25 watt and to have such value current variable knob 69 of power supply 29 is allowed to move until 25watt is achieved in watt meter. Application & functioning of Heat exchanger 25:
A large quantity of heat is generated inside the pumping cavity of laser source 27 when laser is produced. If the heat is not removed from the pumping cavity of laser source 27 then it will cause lamp and rod to get damaged and therefore a proper arrangement of heat distribution in terms of heat exchanger 25 is provided to processing device 4. The heat from De-ionized water is subsequently removed by chilling system 38. The temperature of De-ionized water is regulated by means of solenoid, which turns outside water flow from chilling system 38 on and off as required.
Heat exchanger 25 consist of (i) Cooling system 37 (ii) Chilling system 38 and (iii) Interlock system 39. Cooling system 37 circulates de-ionized water from Heat exchanger 25 to Laser head 43 & Q-Switch 42 and vice versa. Also chilling system 38 circulates water from heat exchanger 25 to chilling pump system 48 and vice versa.
In heat exchanger 25 water circulation from chilling pump system 48 decreases the temperature of incoming de-ionized water at significant level and provides de-


ionized water having less temperature to laser head 43 and Q-switch 42. Flow of water from chilling system 38 used for decreasing temperature of incoming de-ionized water from cooling system 37 is getting heated and hence temperature of such water increases. The temperature of such water is required to decrease by means of chilling pump system 48. Chilling pump system 48 consists of split tank 71 and chilling water tank 70. Example:
Supposing display of digital temperature controlling unit 72 of Heat Exchanger 25 shows temperature of de-ionized water as 35°c. Now if it is required that temperature of de-ionized water should be 30°c then press SET switch of digital temperature controlling unit 72 for few seconds. When present temperature of de-ionized water (35°c) blinks then press up/down push button switches until required temperature 30°c displayed on the display of digital temperature controlling unit 72. Press the SET push button switch of digital temperature controlling unit 72 when 30°c displayed on display of digital temperature controlling unit 72. After few moments as temperature of de-ionized water is set at 30°c the chilling pump system 48 of Heat exchanger 25 which decreases the temperature of incoming de-ionized water stops working. Though functioning of chilling pump system 48 remains continue. Functioning of Chilling pump system 48 of heat exchanger 25: Digital temperature control unit 73 is provided to chilling water tank 70. When in display of digital temperature control unit 73 if value of present water temperature


is significantly higher than the value of set water temperature then split tank 71 starts working and if value of present water temperature remains around the value of set water temperature then split tank 71 stops working. In this way the Chilling pump system 48 saves the power substantially.
Hence with the Heat exchanger 25, temperature can be maintained and the same saves the machine from getting overheated.
IN port 74 of Heat exchanger 25 is connected to one end of Teflon connector 75 via hose pipe 82 while other two ends of Teflon connector 75 are connected to OUT port 76 of laser head 43 and OUT port 77 of Q-switch 42 via hose pipes 83,84 respectively. OUT port 78 of Heat exchanger 25 is connected to one end of Teflon connector 79 via hose pipe 85 while other two ends of Teflon connector 79 are connected to IN port 80 of laser head 43 and IN port 81 of Q-switch 42 via hose pipes 86,87 respectively. OUT port 78 of Heat exchanger 25 provides de-ionized water to Laser head 43 and Q-Switch 42 through IN port 80 and IN port 81 respectively while due to laser heat warm de-ionized water come out from OUT port 76 and OUT port 77 of Laser head 43 and Q-switch 42 respectively and enters into Heat exchanger 25 through IN Port 74.
Chilling OUT port 88 of Heat exchanger 25 is connected to IN port 89 of chilling water tank 70 via hose pipe 95 and OUT port 90 of Chilling water tank 70 is connected to IN port 91 of Split tank 71 via hosepipe 96. OUT port 92 of split tank 71 is connected to dual port 93 of chilling water tank 70 via hose pipe 97 and other end of dual port 93 of chilling water tank 70 is connected to Chilling


IN port 94 of Heat exchanger 25 via hose pipe 98.
Water used to decrease the temperature of de-ionized water becomes warm and
comes out from chilling OUT port 88 of Heat exchanger 25 and travels towards
IN port 89 of Chilling water tank 70. Then this warm water travels into split tank
71 and split tank 71 decreases temperature of warm water and provides such
water to chilling water tank 70 and from chilling water tank 70 water travels into
Heat exchanger 25 through IN port 94.
Functioning of beam delivery mechanism 26 of Processing device 4:
If bruting process is selected on monitor 24 through software installed in
computer 21 Jaser beam falls on sliding beam bender 56. Then laser beam falls on
lower beam bender 57 from which it travels towards lower focusing device 58 and
hence focused laser beam falls on side of a rough stone 5 accommodated on
diamond holder 8.
If Girdle polishing process is selected on monitor 24 through software installed in
computer 21 then laser beam falls on upper beam bender 59 bypassing sliding
beam bender 56. Now laser beam passes through upper focusing device 60 and
hence focused laser beam falls on rough stone 5 accommodated on diamond
holder 8.
Also upper focusing device 60 and lower focusing device 58 have illuminating
component to illuminate rough diamond 5 by means of plurality of surrounding
LED's for watching bruting process or girdle polishing process on CCTV 32.
Functioning of CNC interface of processing device 4:


Motorized Rotatable Platform 23:
Surrounding excess surface of rough diamond 5 is removed by laser beam due to rotation of motorized rotatable Platform 23 on which diamond holder 8 is mounted horizontally. To drive the motorized rotatable platform 23, stepper motor is used.
Motorized Y-axis positioner 30 and Motorized X-axis positioner 31: During Bruting process, laser beam dipping into rough diamond 5 gradually until the maximum diameter 61 or cylindrical shape of the diamond achieved for which displacement of rough diamond 5 through motorized rotatable platform 23 on Y-axis and/or X-axis is required which is accomplished by motorized Y-axis positioner 30 and/or motorized X-axis positioner 31. Motorized Y-axis positioner 30 is mounted on Motorized X-axis positioner 31 in such a way that Motorized Y-axis positioner 30 can travel on Motorized X-axis positioner 31. Displacement of motorized X- axis positioner 31 and/or motorized Y-axis positioner 30 is done automatically or by manual data feed through software installed in computer 21. Movement of Motorized Y-axis positioner 30, Motorized X-axis positioner 31 and rotation of motorized rotatable platform 23 are controlled by control card installed in computer 21.
As Y-drive card 33 is connected to computer 21 & motorized Y-axis positioner 30, it amplifies the electronic signal coming from computer 21 and send amplified signal to motorized Y-axis positioner 30. Similarly X-drive card 34 and R-drive card 35 send amplified electronic signals to Motorized X-axis positioner 31 and


Motorized Rotatable platform 23 respectively. Y-drive card 33, X-drive card 34 and R-drive card 35 can be switched on/off through drive card power supply 36 connected to them. Motorized Y- axis positioner 30 and Motorized X-axis positioner 31 are driven by stepper motors. Also limit switches are provided to each end of Motorized Y axis positioner 30 , Motorized X axis positioner 31 & motorized rotatable platform 23 to sense the home & end position. A rough diamond 5 to be processed for bruting or girdle polishing can be watched on CCTV 32 through video system of processing device 4 consist of upper CCD camera 52 and lower CCD camera 53.
As laser bruting being a non-contact process gives more speed, reduces weight loss significantly and keeps the shape of diamond uniform. In laser bruting machine the computer becomes an important element in cutting of diamond. With the standard software computer suggest an optimal cut to have accurate rounded shape of the diamond taking dimensions & shape into account. Also the rough diamond stone to be centered and bruted is lit up by illuminating sources and these illuminating sources consist of plurality of LED's so the eye gets the impression that is always the same side of the stone that is lit and hence the illuminated rough diamond can be watched on CCTV through video system consist of CCD cameras. This is a useful technique, because bruting machine can check the process at all times without stopping the machine and the same can be operated by a single person. Summing up all the advantages productivity increases significantly by using laser bruting machine.


We claim:
1. A Laser Bruting Machine comprising a diamond holder (8) consisting of
stitching die (6) with magnetic die (7) and rough diamond (5) adapted to be
mounted on the said stitch die (6) due to magnetism;
a setup device (3) for setting up said diamond holder (8) consisting of CNC interface of motorized X axis positioner (9) having a motorized rotatable platform (11) with motorized up/down positioner (12) provided with the drive cards (13,14,15) connected to the said motorized X-axis positioner (9) and also a control card, connected to a computer (16) with monitor (19), driven by three stepper motors with power supply (22) and provided with video system;
a processing device (4) for cutting and polishing of said diamond on the diamond holder(8) consists of CNC_Jnterface of processing device (4) motorized Y-axis positioner (30) with motorized rotatable platform (23) motorized X axis positioner (31) connected to computer (21) with monitor (24) and provided with Y drive card (33), X drive card (34), R drive card (35), drive card power supply (36) and driven by three steeper motors, controlled by control card, a laser source (27) with beam delivery mechanism (26) controlled by RF-Q Switch driver (28) and a CCTV connected to CCD camera (18) for observing the laser bruting process.
2. A Laser Bruting Machine as claimed in claim 1 wherein rough diamond
(5) is stitched on the top of stitching die (6) by adhesive & heat; stitching die
(6) along with rough diamond (5) is fixed on top of magnetic die (7) due to magnetism.

3. A Laser Bruting Machine as claimed in claim 1 wherein
motion of motorized X axis positioner (9), motorized rotatable platform (11), motorized up/down positioner (12) is controlled by drive cards(13,14 & 15) placed in computer (16);
limit switches are provided to each end of motorized X axis positioner (9), motorized rotatable platform (11), motorized up/down positioner (12) to sense the home & end position.
4. A Laser Bruting Machine as claimed in claim 1 wherein video system of
setup device (3) is connected to computer (16) & it consists of Upper CCD
camera (17) & Lower CCD Camera (18).
5. A Laser Bruting Machine as claimed in claims 1 to 4 wherein one end of
the said Y drive card (33), R drive card (35) & X drive card (34) are
connected to motorized Y-axis positioner (30), motorized rotatable platform
(23) & motorized X axis positioner (31) respectively and other end of Y
drive card (33), R drive card (35), X drive card (34) are connected to control
card of computer (21) through (37) pin, connector; Y -drive card (33), X
drive card (34), R drive card (35) are connected to drive card power supply
(36).
6. A Laser Bruting Machine as claimed in claim 5 wherein motion of
motorized Y-axis positioner (30), motorized rotatable platform (23),
motorized X axis positioner (31) are controlled by control card of computer
(21).

7. A Laser Uniting Machine as claimed in claim 5 wherein displacement
of rough diamond (5) of diamond holder (8) via motorized rotatable platform (23) on Y-axis and X-axis is accomplished by motorized Y-axis positioner (30) and motorized X-axis positioner (31) respectively; motorized Y-axis positioner (30) and motorized X-axis positioner (31) are mounted in such a way that motorized Y-axis positioner (30) travels on motorized X-axis positioner (31).
8. A Laser Uniting Machine as claimed in claim 3 wherein limit switches are provided to each end of Motorized Y axis positioner (30), Motorized X axis positioner (31) & motorized rotatable platform (23) to sense the home & end position.
9. A Laser Uniting Machine as acclaimed in claim 1, wherein video system of processing device (4) is connected to computer (21) consist of upper CCD camera (52) and lower CCD camera (53).
10. A Laser Bruting Machine as acclaimed in claim 1, wherein heat exchange (25) of processing device (4) is connected to power supply (29) and RF Q-switch driver (28);
digital temperature controller (72), LED's (49, 50, 51) of interlock controller for flow , level & temperature indication of de-ionized water, pump on / off (62), pump LED (63) are accommodated in heat exchange (25).

11. A Laser Bruting Machine as acclaimed in claim 1 heat exchanger (25)
consist of cooling system (37), chilling system (38) wherein cooling system (37) circulate de-ionized water and in this cooling system (37) IN port (74) of heat exchanger (25) is connected to one end of Teflon connector (75) via hose pipe (82) while other two ends of Teflon connector (75) are connected to OUT port (76) of laser head (43) and OUT port (77) of Q-switch (42) via hose pipes (83,84) respectively and OUT port (78) of heat exchanger (25) is connected to one end of Teflon connector (79) via hose pipe (85) while other two ends of Teflon connector (79) are connected to IN port (80) of laser head (43) and IN port (81) of Q-switch (42) via hose pipes (86,87) respectively;
while chilling system (38) circulate water and this chilling system (38) consist of chilling pump system (48) which consist of split tank (71), chilling water tank (70) and digital temperature controller (73) is connected to chilling water tank (70) and chilling OUT port (88) & chilling IN port (94) of heat exchanger (25) are connected to chilling pump system (48); chilling OUT port (88) of heat exchanger (25) is connected to IN port (89) of chilling water tank (70) via hose pipe (95) and OUT port (90) of chilling water tank (70) is connected to IN port (91) of split tank (71) via hosepipe (96); OUT port (92) of split tank (71) is connected to dual port (93) of chilling water tank (70) via hose pipe (97) and other end of dual port (93) of chilling water tank (70) is connected to chilling IN port (94) of heat exchanger (25) via hose pipe (98).

12. A Laser Bruting Machine as acclaimed in claim 1, wherein Beam delivery mechanism (26) of processing device (4) consists of Bruiting process system (54), girdle polishing system (55).
13. A Laser Bruting Machine as acclaimed in claim 12, wherein Bruiting
process system (54) consists of sliding beam bender (56), lower beam bender (57), lower focusing device (58).
14 . A Laser Bruting Machine as acclaimed in claim 11 &12jjyherein Girdle polishing system (55) consist of upper beam bender (59), upper focusing device (60); sliding beam bender (56), lower beam bender (57) and upper beam bender (59) are placed at 45° with respect to incoming laser beam; each of the beam bender (56,57,59) bends the laser beam at 90°;
lower focusing device (58) and upper focusing device (60) focuses the incoming laser beam; lower focusing device and upper focusing device (60) have illuminating source to illuminate rough diamond (5); each illuminating source of lower focusing device (58) & upper focusing device have plurality of LED's.
15. A Laser Bruting Machine as claimed in claim 1, wherein said source (27) consist of back mirror (40), apertures (41), Q-switch (42), laser (43), shutter (44), polariser (45), from mirror (46) & beam expander (47).

16. A Laser Bruting Machine as claimed in claim 1 wherein RF Q Switch
driver (28) is connected to computer (21), Q- Switch (42) & heat exchanger (25).
17. A Laser Bruting Machine as claimed in claim 1 wherein stabilizer is
connected to power supply (29); T.P. switch (64), Laser lamp on/off toggle switch (65), current setting unit (68), push button on/off switch (67) of current setting unit (68), current variable knob (69) are provided to power supply (29).
18. A Laser Bruting Machine as claimed in claims 3,8,17 wherein
computers (16 & 21) are connected by LAN and the computer program for bruting process system (54) & girdle polishing system (55).
19 . A Laser Bruting Machine substantially here in described with reference to an accompanying drawings

Documents:

550-mum-2003-abstract(2-7-2004).doc

550-mum-2003-abstract(2-7-2004).pdf

550-mum-2003-cancelled pages(2-7-2004).pdf

550-mum-2003-claims(granted)-(2-7-2004).doc

550-mum-2003-claims(granted)-(2-7-2004).pdf

550-mum-2003-correspondence(2-7-2004).pdf

550-mum-2003-correspondence(ipo)-(23-5-2007).pdf

550-mum-2003-drawing(2-7-2004).pdf

550-mum-2003-form 1(30-5-2003).pdf

550-mum-2003-form 19(5-6-2003).pdf

550-mum-2003-form 2(granted)-(2-7-2004).doc

550-mum-2003-form 2(granted)-(2-7-2004).pdf

550-mum-2003-form 26(2-5-2003).pdf

550-mum-2003-form 3(2-5-2003).pdf

550-mum-2003-form 5(2-5-2003).pdf

550-mum-2003-form-pct-isa-210(30-5-2003).pdf

abstract1.jpg


Patent Number 207130
Indian Patent Application Number 550/MUM/2003
PG Journal Number 30/2007
Publication Date 27-Jul-2007
Grant Date 23-May-2007
Date of Filing 30-May-2003
Name of Patentee ARVINDBHAI LAVJIBHAI PATEL
Applicant Address 48/A, ARVIND ESTATE, BAPUNAGAR, AHMEDABAD-380 025, GUJARAT, INDIA.
Inventors:
# Inventor's Name Inventor's Address
1 ARVINDBHAI LAVJIBHAI PATEL 48/A, ARVIND ESTATE, BAPUNAGAR, AHMEDABAD-380 025, GUJARAT, INDIA.
PCT International Classification Number B28D5/00, B23K26/08
PCT International Application Number N/A
PCT International Filing date
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 NA