Title of Invention

THREADED CHANNEL CLOSURE FOR TUBULAR HEAT EXCHANGERS

Abstract

The invention relates to heat exchangers with screw plug enclosure wherein the assembly is accomplished by setting the channel cover concentric with help of threaded holding pins. These pins being inserted from radial holes and cleats provided with nuts on the threaded holding pins for the adjustment. This facilitates handling of the threaded lock ring and the channel cover independently during assembly, eliminating cumbersome handling fixtures. Plurality of holes is provided in the threaded lock ring and channel cover so as to supply lubricating oil to the threading of every push bolt and the threaded joint between the channel barrel and the threaded lock ring. The outer diameter of the threaded lock ring is located concentric by providing a guide ring, fixed to the channel header, the inner diameter of the guide ring having locating fit with the mating outer diameter of the threaded lock ring. The threaded lock ring is also located concentric at its inner end, by providing location fit with the mating inner diameter of the threaded lock ring for a small length, followed by a conical or taper diameter for some length followed by the diameter with normal clearance for rest of the length.

Full Text

FORM 2 THE PATENT ACT 1970 & The Patents Rules, 2003 PROVISIONAL /COMPLETE SPECIFICATION (See section 10 and rule 13) 1. TITLE OF THE INVENTION THRAEDED CHANNEL CLOSURE FOR TUBULAR HEAT EXCHANGER 2. APPLICANT (a) NAME : Larsen and Toubro Ltd. (b) NATIONALITY.: Indian Company, registered under the provisions of the Companies Act, 1956 (c) ADDRESS : L&T House, Ballard Estate, Maharashtra State, India. 3. PREAMBLE TO THE DESCRIPTION COMPLETE The following specification particularly describes the invention and the manner in which it is to be performed. 4. DESCRIPTION (Description starts from page 2) 5. CLAIMS: 6 Nos 6. DATE AND SIGNATURE: Given at the end of last page of specification. 7. ABSTRACT OF THE INVENTION: On separate page ORIGINAL 714/MUM/2006 09/05/06 Title of the invention: Threaded channel closure for tubular heat exchanger. Field of invention: The present invention relates to threaded channel closure, high pressure shell and tube heat exchangers having removable tube bundles such as U-tubes and floating heads. Such heat exchangers are widely used in critical services in a number of process industries such as Hydrocracking units, Hydrodewaxing units, Hydrofining units etc. Prior art: The prior art is described below with help of following figures. Fig. 1 shows the sectional view of the channel header assembly of typical H-H type heat exchanger as described bellow. Fig. 2 shows the sectional view of the channel header assembly of typical H-L type heat exchanger as described bellow. Threaded channel closure type heat exchangers are generally classified based on the operating pressures on the shell and tube sides. The heat exchangers, which have high pressure on both, shell side as well as tube side, are classified as H-H type heat exchangers. The heat exchangers, which have higher pressure on channel side and lower pressure on shell side, are classified as H-L type heat exchangers. Thus in H-H type heat exchangers, tubesheets are subjected to lesser differential pressure and consequently would typically have 2 internal tubesheet with apparatus for sealing the tubesheet against the shoulder of the channel. In H-L type heat exchangers, the tubesheet can typically get exposed to full pressure of either side independerrtly H-L type would typically have tubesheet and channel of integral construction, either single piece or welded together. The shell of the H-L type could be independently bolted or welded to the tubesheet. Tubesheets are provided with plurality of holes in which the tubes 5 are fixed. The channel 1 is provided with nozzles 6 for the tube side fluid to enter and exit the heat exchanger. The heat exchangers are preferably provided with two or more tube passes and accordingly, some of the tubes are in the first tube pass through which the tube side fluid enters the tube bundle from the channel side of the nozzle, while some tubes are in the final tube pass through which the tube side fluid exits from the tube bundle to the channel side exit nozzle. Both H-H and H-L type heat exchangers have channel headers 1 provided with a threaded closure consisting of threaded lock ring 2 and channel cover 3. Threaded lock ring is screwed in the threads provided in the channel header body. The closure is sealed by means of a gasketed joint. The gasket 7 is located in a groove made in shoulder of the channel ahead of the threads. The gasket is compressed through the peripheral portion i.e. the tongue of the diaphragm 8. The diaphragm 8 is backed by a compression ring 9 at the periphery and channel 3 cover in the center. The channel cover is held in position by the threaded lock ring 2. The push bolts/rods 10 assembled at the periphery of the threaded lock ring pressurize the compression ring 9, which in turn presses tongue of the diaphragm-to seal the gasket. The end thrust due to internal pressure on diaphragm is essentially transmitted to and resisted by the channel threads via channel cover, outer compression ring and threaded lock ring. The push bolts/rods 10 on the threaded lock ring 2 provide incremental loading to the gasket through the tongue of the diaphragm for achieving the leak-tight joint. The assembly procedure of the prior art heat exchanger is as given below. The diaphragm 8 and the outer compression ring 9 are placed in position. The diaphragm 8 and compression ring 9 are held in position by means of internal grub screws 11. These grub screws are screwed in the radial threaded holes provided in the outer compression ring 9. These grub screws are assembled from inner side of the outer compression ring and project beyond the outside diameter of outer compression ring to get engaged in the dimples 51 provided in the channel barrel. These grub screws remain under flush with respect to the inside diameter of outer compression ring to avoid interfering with the channel cover. After this, the channel cover 3 and threaded lock ring can be assembled. [It should be noted that the heat exchangers under consideration are very heavy and the size and weight of the components like 4 channel cover and the threaded lock ring can be in the range of 600 mm to 2000 mm in diameter and weights in the range of 200 kg to 10000 kg. Naturally such parts require liberal clearances between their mating parts (typically of the order of 0.5 mm to 2 mm radially) to facilitate the assembly. The arrangement of the closure is such that the major portion of the cover gets located in the inside diameter of the threaded lock ring whereas a small portion of the channel cover, whose diameter is bigger than the inside diameter of the threaded lock ring remains ahead of the threaded ring and enters into the outer compression ring. Therefore, the threaded lock ring can be assembled only when the channel cover is in position. At the same time, the channel cover cannot remain in position without being engaged with the threaded lock ring. Hence, the existing art is to handle both the threaded lock ring and the channel cover together for assembly into the channel header. Hence it is necessary to handle the threaded lock ring and the channel cover together. These components are mounted on a special cantilever type fixture and are required to be skillfully balanced using counterweights to make them vertical and aligned with the centerline of the channel. Further during assembly, while the cover remains stationary, the threaded lock ring is required to be rotated. The existing methodology of balancing the assembly, alignment of the threaded lock ring with the threads on the channel body is very difficult, cumbersome and time consuming process and if not done 5 properly can severely damage the equipment and / or its components. The grub screws 11, which are screwed from inside of the outer compression ring 9 can hamper free movement of the compression ring 9 and the diaphragm 8. After equipment has been exposed to operating condition, invariably these grub screws 11 get jammed and become extremely difficult to unscrew, more so because these screws are under flush with outer compression ring and at times get broken leading to major repair of the equipment. There is definitive tendency for the push bolts to get jammed particularly when the equipment has been in service for some period of time due to deposition of extraneous matter, scaling, rusting and / or galling in the threaded portion. When the torque is applied for loosening of such jammed bolts, it is very likely that the heads of the bolts get sheared off. The removal and replacement of these sheared bolts is very difficult and cumbersome and not always possible at the site of installation. As mentioned above, generous clearances are provided between the mating roots and crests of the male threads on the threaded lock ring 2 and female threads on the channel barrel to facilitate smooth assembly. Ideally, it is required that, this clearance should remain distributed uniformly and equally around the circumference so that the load transfer takes place along the contact at side of the flanks of the threads along the pitch line of the threads. However, due to the self weight, there is a natural 6 tendency for the threaded lock ring 2 to settle down towards the bottom portion. This could induce differential force around the circumference leading to eccentric forces on the threads, leading to very high contact stresses in the bottom side of the thread flanks compared to that on the top side. This could lead to scoring / scrapping of the metal during unscrewing, especially after the heat exchanger has been exposed to operating conditions for some time, leading to jamming of the threads and can cause severe damage to the equipment. Summary of the invention: Considering the above drawbacks of the prior art the present invention endeavors to eliminate them. The objective of the present invention is to render assembly easy by facilitating independent handling of the channel cover and threaded lock ring. . Another objective of the present invention is to avoid or eliminate the jamming of the push bolds to stop their breakage. Yet another objective of the present invention is to eliminate the problems that are caused by the eccentric fitting of the threaded lock ring 2. — In the present invention the grub screws 11 and the dimples 51 used in the prior art are eliminated. Instead, the threaded pins which are inserted from out side in the peripheral holes drilled radially on the channel body, these pins being provided with nuts, engaged in the stopper cleats fitted on the channel cover. Radial, through holes are provided on the periphery of the outer 7 compression ring to match in numbers as well as position with the radial holes in the channel body, while blind radial holes are provided on the channel cover which match with these holes in number and position. With this arrangement the assembly can be done as described below. The gasket is assembled in position. The diaphragm and compression ring are then placed in position and the radial holes on the compression ring are matched with the radial holes in the channel body. The threaded pins are then screwed in to the extent that, they engage with the radial holes in the compression ring, thus locating the compression ring in position. The channel cover (independent of the threaded lock ring) is then inserted to its assembly position, the radial blind holes on the channel cover are matched with the pins and the pins are further screwed in to engage these blind holes. The pins then are sequentially screwed in and out to position the channel cover concentric with the threads of the channel header 1 which houses the closure assembly. Then the threaded lock ring can be assembled in position separately and the push bolts are tightened thereafter. The threaded pins are withdrawn after the assembly is completed. Plurality of holes is provided in the threaded lock ring and channel cover so as to supply lubricating oil to the threading of every push bolt and the threaded joint between the channel barrel and the threaded lock ring. This ensures ease of assembly and disassembly of these components with out any damage. 8 The outer diameter of the threaded lock ring is located concentric by providing a guide ring, fixed to the channel header at its outer end, the inner diameter of the guide ring having close tolerance giving locating fit with the mating outer diameter of the threaded lock ring. At the same time, the threaded lock ring is also located concentric at its inner end, by providing the close tolerance outer diameter for a short length on the channel cover to achieve location fit with the mating inner diameter of the threaded lock ring, followed by a conical or taper diameter for some length followed by the diameter with normal clearance between the outer diameter of the channel cover and mating inner diameter of threaded lock ring. Due to this, the assembly of the threaded lock ring remains easy, at the same time the threaded lock ring gets located in its correct concentric position in final assembly. This ensures uniform loading of the threads at their pitch line in working condition and eliminates the problems caused by eccentric fitting as in the case of the prior art heat exchangers. Statement of the invention: Threaded channel closure for tubular heat exchanger comprising channel header 1-wherein the gasket 7 is provided at the shoulder of the channel, tongue of the diaphragm 8 is provided to apply pressure on the gasket to achieve the sealed joint, outer compression ring 9 provided at back side of the diaphragm 8 and being loaded by push bolts 1, provided at the periphery of threaded lock ring 2, outer compression ring 9 being supported by channel cover 3, which is 9 kept in position by threaded lock ring 2, characterized in that, the channel header 1 being provided with plurality of radial holes 108 on its periphery, approximately at the centerline of the width of the outer compression ring 9 in its assembled condition; the outer compression ring 9 being provided with plurality of radial through holes 104 matching the set of holes 108 in number as well as angular position; the channel cover 3 being provided with set of blind holes 105 matching with the sets of holes 108 in channel header 1 and hence also with set of holes 104 in the outer compression ring 9; plurality of threaded holding pins 14 being provided to engage with the sets of holes 104, 105 and 108 together with adjusting nuts 13 provided on threaded portion of the threaded holding pins 14; plurality of cleats 12 in the form of a pair of inverted "L" shaped pieces or other shapes or configurations being, fixed on the channel header 1 adjacent to the holes 108, and being so arranged that, threaded holding pin 14 can easily pass through the same, while the outward radial movement of the nut 13, which is provided on the pin 14, is restricted by the cleat 12; plurality of holes 16 and 18 being provided in the threaded lock ring 3 so as to feed the lubricating fluid to each of the threaded bolts 10 and the threaded joint between the threaded lock ring and the channel header 1; plurality of holes 17 being provided to feed lubricating fluid to the inner push bolts; outer diameter of the channel cover 3 mating with the threaded lock ring 2 being provided with close tolerance to achieve location 10 fit for a small length (approximately 10 mm to 100 mm) at the portion shown at 101, for a small length after that, followed by a conical or taper diameter portion 102 and rest of the diameter of the channel cover further to that, being provided with normal (liberal) clearance; guide ring 15 being fitted with threaded fasteners 107 at the end of the channel header, the inner diameter of the guide ring 15 being provided with close tolerance to achieve location fit with the mating outer diameter of the threaded lock ring 2; thus the threaded lock ring 2 being supported accurately concentric at both the ends viz. on diameter shown at 101 at the inner end and the diameter shown at 106 at the outer end. Threaded channel closure for tubular heat exchanger being assembled with method which comprises, fitting of the gasket 7, diaphragm 8 and compression ring 9 in position; matching the set of holes 104 on the compression ring 9 with set of holes 108 in the channel header 1; the threaded holding pins 14 being inserted and screwed in with the help of nut 13 in cooperation with the cleats 12, to the extent that, they engage the set of holes 104 in the compression ring 9 after passing through the set of holes 108 in the channel header 1; the diaphragm 8 and the compression ring 9 thus being held in position; thereafter the channel cover 3 being brought in position independent of the threaded lock ring 2 and set of holes 105 in it being matched with sets of holes 104 and 108 mentioned above; the aforesaid threaded holding pins 14 being then further screwed in to engage 11 the blind holes 105 provided in the channel cover 3; the channel cover 3 then being set accurately concentric with the channel barrel by differential screwing in or out of the threaded holding pins 14; the guide ring 15 then being fitted in position and fastened to the end of channel header 1, by means of threaded fasteners 107; once the channel cover 3 is positioned concentric, the threaded lock ring 2 being independently brought and engaged and screwed in the threads of the channel barrel 1; the mating diameters of the threaded lock ring 2 with that of channel cover 3 (outer diameter) and the guide ring 15 (inner diameter) shown at 101 and 106 respectively, guiding the threaded lock ring 3 accurately concentric with channel barrel due to the location fit achieved by close tolerances on outer diameter of channel cover 3 at diameter shown at 101 and the inner diameter of the guide ring 15 shown at 106 respectively. Description of the figures: the present invention "Threaded channel closure for tubular heat exchangers", is now described in detail with the help of following figure. Fig. 3 shows the sectional view of he present invention. Figures 4a, 4b, 4c show sectional view of the alternative arrangements for cleats 12 and nuts 13 as shown in Fig. 3. Description: The details of this invention as described below are applicable to both H-H as well as H-L type heat exchangers as they are defined above. The invention "Threaded channel closure for tubular heat exchangers" comprises, channel header 1 wherein the gasket 7 is 12 provided at the shoulder of the channel, tongue of the diaphragm 8 is provided to apply pressure on the gasket 7 to achieve the sealed joint. Outer compression ring 9 is provided at the back side of the diaphragm 8 and is loaded by tightening of the push bolts 10 provided in the threaded holes provided at the periphery of the threaded lock ring 2. This load through the diaphragm 8 is transferred to gasket 7 to achieve the leak proof joint. Outer compression ring 9 is supported by channel cover 3, which is kept in position by the threaded lock ring 2. The channel header 1 is provided with plurality of radial holes 108 on its periphery, approximately at the centeriine of the width of the outer compression ring 9 in its assembled position. The outer compression ring 9 is provided with plurality of radial through holes 104 matching the set of holes 108 in number as well as angular and axial positions. Channel cover 3 is provided with a set of blind holes 105 matching the sets of holes 108 in channel header and hence also the set of holes 104 in the outer compression ring 9. Plurality of threaded holding pins 14 are provided, to engage with the sets of holes described above, together with adjusting nuts 13 provided on the threaded portion of the pins 14. Cleats in the form of a pair of inverted "L" shaped pieces or of other shape or configuration are fixed on the channel header adjacent to the holes 108, are so arranged that the threaded holding pin 14 can easily pass through the same, while the outward radial movement of the nut 13, provided on the pin 14, is restricted by the cleat. In an alternative arrangement, 13 these cleats can be replaced by a hollow boss (Ref. Fig. 4a) provided with a recess to accommodate and restrict the radial movement of the nut 13 but permitting the entry of the threaded lock ring 14. In yet another embodiment as shown in Fig. 4b, a boss 402 can be provided having threading to match the threading of the threaded holding pins 14. In yet another embodiment, as shown in Fig. 4c the threaded holes 403 can be provided in the channel header it self instead of providing the cleats and nuts as mentioned above. Plurality of holes 16 and 18 are provided in the threaded lock ring 2 so as to feed lubricating fluid to each of the threaded bolts 10 and threaded joint between the threaded lock ring 2 and the channel header 1 respectively. Plurality of holes 17 is provided to feed the lubricating fluid to the inner push bolts. The outer diameter.of the channel cover 3 mating with the inner diameter of the threaded lock ring 2 is provided with close tolerance to achieve location fit for a small length (approximately 25mm to 250mm) at the portion shown at 101, for a small length after that, followed by a conical or tapered diameter portion 102. Rest of the outer diameter of the channel cover 3 further to that is with a normal i.e. liberal clearance, so as to provide easy movement of the threaded lock ring 2 during assembly, till it reaches its final position. Due to this, front end of the threaded lock ring 2 is held concentric with channel threads in its final assembled position. Guide ring 15 is fitted preferably with threaded fasteners 107 at the outer end of the channel header 1. 14 The guide ring 15 is provided with inner diameter at 106 having close tolerance, to achieve location fit with the mating outer diameter of the threaded lock ring 2 to ensure concentricity of the same at tbeouter end. Thus threaded lock ring 2 being supported concentric at both, the inner end as well as the outer end gets located concentric to the channel threads, uniformly loading the threads at their side flanks. The method of assembly of the heat exchanger is much simplified with these improvements and can be done as given below. First the gasket 7, diaphragm 8, and the compression ring 9 are positioned at the required location as shown in the figure 4. Set of holes 104 on compression ring 9 are matched with the set of holes 108 in the channel header 1. The threaded holding pins 14 are then inserted and screwed in with help of the nut 13, to the extent that, they engage the set of holes 104 in the compression ring 9; after passing though the set of holes 108 in the channel body 1. The compression ring 9, diaphragm 8 and the gasket 7 are thus held in position. Thereafter the channel cover 3 is brought in position independent of the threaded lock ring 2 and the set of holes 105 in it are matched-with -the sets of holes 104 and 108 mentioned above. The aforesaid threaded holding pins 14 are further screwed in, to engage the blind holes 105 provided in the channel cover 3. The channel cover 3 is then set accurately concentric with the channel threads by differential screwing in or out of the threaded holding pins 14. The guide ring 15 is then fitted in position and fastened to the end of the channel header 1 15 by means of threaded fasteners 107. Once the channel cover 3 is positioned concentric, the threaded lock ring 2 is independently brought and engaged and screwed in the threads of the channel barrel 1. While the threaded lock" ring 2 is reaching its final assembly position, its mating diameters at 101 and 106 get engaged with that of channel cover 3 and guide ring 15 respectively and locate the threaded lock ring 2 accurately concentric with the channel threads. 16 We claim 1. Threaded channel closure for tubular heat exchanger comprising channel header 1 wherein the gasket 7 is provided at the shoulder of the channel, tongue of the diaphragm 8 is provided to apply pressure on the gasket to achieve the sealed joint, outer compression ring 9 provided at back side of the diaphragm 8 and being loaded by push bolts 10, provided at the periphery of threaded lock ring 2, outer compression ring 9 being supported by channel cover 3, which is kept in position by threaded lock ring 2, characterized in that; the channel header being provided with plurality of radial holes (108) on its periphery, within the width of the outer compression ring (9) in its assembled condition; the outer compression ring (9) being provided with plurality of radial through holes (104) to match said set of holes (108); the channel cover (3) provided with set of blind holes (105) to match said sets of holes (108) and (104); plurality of threaded holding pins (14) provided to engage with the sets of holes (104), (105) and (108) together with adjusting nuts (13) provided on threaded portion of the threaded holding pins (14); plurality of cleats (12) in the form of a pair of "L" shaped pieces or of other shape or configuration being fixed on the channel header (1) adjacent to the holes (108), being so arranged such that, threaded holding pin (14) can easily pass through the same, while the outward radial movement of the nut (13) restricted by the cleat 12; 17 plurality of holes (16) and (18) being provided in the threaded lock ring (3) so as to feed the lubricating fluid to each of the threaded push bolts (10) and the threaded joint between the threaded lock ring and the channel header (1); plurality of holes (17) provided to feed lubricating fluid to the inner push bolts; outer diameter of the channel cover (3) mating with the threaded lock ring (2) being provided with close tolerance to achieve location fit for a small length (approximately 10 mm to 100 mm) at the portion shown at (101), for a small length after that, followed by a conical or taper diameter portion (102) and rest of the diameter of the channel cover (3) further to that, being provided with normal (liberal) clearance; guide ring (15) being fitted with threaded fasteners (107) at the end of the channel header (1), the inner diameter of the guide ring (15) being provided with close tolerance to achieve location fit with the mating outer diameter of the threaded lock ring (2); thus the threaded lock ring (2) being supported accurately concentric at both the ends viz. on diameter shown at (101) at the inner end and the diameter shown at (106) at the outer end. 2. Threaded channel closure for tubular heat exchanger as claimed in claim 1 being assembled with method which comprises, a. fitting of the gasket (7), diaphragm (8) and compression ring (9) in position; b. matching the set of holes (104) on the compression ring (9) with set of holes (108) in the channel header (1); 18 c. the threaded holding pins (14) being inserted and screwed in with the help of nut (13) in cooperation with cleats (12), to the extent that, they engage the set of holes (104) in the compression ring (9) after passing through the set of holes (108) in the channel header; d. the diaphragm (8) and the compression ring (9) thus being held in position; thereafter the channel cover (3) being brought in position independent of the threaded lock ring (2) and set of holes (105) in it being matched with said sets of holes (104) and (108); e. the aforesaid threaded holding pins (14) being then further screwed in, to engage the blind holes (105) provided in the channel cover (3); f. the channel cover (3) then being set accurately concentric with the channel threads by differential screwing in or out of the threaded holding pins (14); g. the guide ring (15) then being fitted in position and fastened to the end of channel header (1), by means of threaded fasteners (107); h. once the channel cover (3) is positioned concentric, the threaded lock ring (2) is independently brought and engaged and screwed in the threads of the channel barrel (1); i. the mating diameters of the threaded clock ring (2) with that of channel cover (3) (outer diameter) and the guide ring (15) (inner diameter) shown at (101) and (106) respectively, guiding the threaded lock ring accurately concentric with channel barrel due to the location fit achieved by close 19 tolerances on outer diameter of channel cover (3) at diameter shown at (101) and the inner diameter of the guide ring (15) shown at (106) respectively. 3. Threaded channel closure for tubular heat exchanger as claimed in claim 1, wherein, hollow bosses are being provided so as to accommodate and restrict the radial movement of the nuts (13), but permitting the entry of the threaded holding pins (14), as an alternative arrangement for the cleats (12). 4. Threaded channel closure for tubular heat exchanger as claimed in claim 1, wherein, bosses 402 are being provided having threaded holes to match the threading of the threaded holding pins (14) as an alternative arrangement for the cleats (12) and nuts (13). 5. Threaded channel closure for tubular heat exchanger as claimed in claim 1, wherein, threaded holes (403) being provided in the channel cover (1) it self as an alternative arrangement for the cleats (12) and nuts (13). 6. Threaded channel closure for tubular heat exchanger as claimed in claim 1, and method of assembly as claimed in claim 2 substantially described hereinbefore, with reference to the accompanying drawings. Dated the 26th Day of April 2006 M.D. Bhate (Agent for the applicant) 20

Documents:

714-mum-2006-abstract(09-05-2006).doc

714-mum-2006-abstract(09-05-2006).pdf

714-mum-2006-abstract-1.jpg

714-mum-2006-abstract.pdf

714-mum-2006-cancelled page(09-05-2006).pdf

714-mum-2006-claim(granted)-(09-05-2006).pdf

714-mum-2006-claims(granted)-(09-05-2006).doc

714-mum-2006-claims.pdf

714-mum-2006-correspondance-po.pdf

714-mum-2006-correspondance-received.pdf

714-mum-2006-correspondence(03-09-2007).pdf

714-mum-2006-correspondence(ipo)-(21-02-2008).pdf

714-mum-2006-description (complete).pdf

714-mum-2006-description (provisional).pdf

714-mum-2006-drawing(09-05-2006).pdf

714-mum-2006-form 1(09-04-2006).pdf

714-mum-2006-form 1(09-05-2006).pdf

714-mum-2006-form 18(12-09-2006).pdf

714-mum-2006-form 2(granted)-(09-05-2006).doc

714-mum-2006-form 2(granted)-(09-05-2006).pdf

714-mum-2006-form 3(21-04-2006).pdf

714-mum-2006-form 3(30-08-2007).pdf

714-mum-2006-form 5(22-04-2006).pdf

714-mum-2006-form 9(26-06-2006).pdf

714-mum-2006-form-1.pdf

714-mum-2006-form-2.doc

714-mum-2006-form-2.pdf

714-mum-2006-form-9.pdf

714-mum-2006-power of attorney(09-05-2006).pdf

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