Title of Invention	HIGH-VOLTAGE SWITCHGER ASSEMBLY
Abstract	The invention relates to a gas-insulated high voltage switchgear, comprising at least one bus bar with three phase conductors (L1, L2, L3), whereby each phase conductor (L1, L2, L3) is connected to the input of a respectively provided bus bar section (11, 21, 31). The phase conductor (L1, L2, L3) and the bus bar section (11, 21, 31) are arranged in a three-phase bus bar module (40,41) with three single-phase power switches (12, 22, 32), each arranged in a separate power switch housing (13, 23, 33) and each bus bar section (11, 21, 31) is connected at the output therefrom to a respectively provided power switch (12, 22, 32).

Title of Invention

HIGH-VOLTAGE SWITCHGER ASSEMBLY

Abstract

The invention relates to a gas-insulated high voltage switchgear, comprising at least one bus bar with three phase conductors (L1, L2, L3), whereby each phase conductor (L1, L2, L3) is connected to the input of a respectively provided bus bar section (11, 21, 31). The phase conductor (L1, L2, L3) and the bus bar section (11, 21, 31) are arranged in a three-phase bus bar module (40,41) with three single-phase power switches (12, 22, 32), each arranged in a separate power switch housing (13, 23, 33) and each bus bar section (11, 21, 31) is connected at the output therefrom to a respectively provided power switch (12, 22, 32).

Full Text	WO 2006/066785 PCT/EP2005/013474 High-voltage switchgear assembly Description The invention relates to a gas-insulated high-voltage switchgear assembly. The invention further relates to modules for the gas-insulated high-voltage switchgear assembly according to the invention. It is generally known that gas-insulated high-voltage switchgear assemblies with rated voltages of above 200 kV are generally designed as single-phase- encapsulated systems. In this case, the switching devices, such as circuit breakers, isolabors and grounding switches, for example, and further components, such as overhead line connections, for example, are designed to be single-phase and are arranged in separate housings. Also, the three phase conductors of a busbar are arranged in separate, generally tubular, housings. However, this design results in a comparatively high space requirement. The invention is based on the object of specifying a high-voltage switchgear assembly having a reduced space requirement. This object is achieved according to the invention by a high-voltage switchgear assembly having the features mentioned in claim 1. A gas-insulated high-voltage switchgear assembly according to the invention comprises at least one busbar having three phase conductors, each phase conductor being connected to the input of a busbar isolator associated with it. In this case, the phase conductors and the busbar isolators are arranged in a WO 2006/066785 - 2 - PCT/EP2005/013474 common three-phase busbar module. The high-voltage switchgear assembly according to the invention further comprises three single-phase circuit breakers, which are each arranged in a separate circuit breaker housing. Each busbar isolator is in this case connected on the output side to in each case one circuit breaker associated with it. Owing to this arrangement in which the three phase conductors of a busbar and the associated busbar isolators are arranged in a common housing, the space requirement of the high-voltage switchgear assembly is advantageously reduced in comparison with a conventional high-voltage switchgear assembly. The object is also achieved by a busbar module having the features mentioned in claim 7. Accordingly, a busbar module according to the invention, in which three phase conductors of a busbar and three busbar isolators are arranged and each phase conductor is connected to the input of the busbar isolator associated with it, has three single-phase interfaces, which are each associated with a busbar isolator. Such a busbar module allows for a direct and therefore comparatively simple connection of three single-pole circuit breakers. It is not necessary to insert additional modules. The design of the high-voltage switchgear assembly is simplified, and the embodiment is particularly space-saving. The object is also achieved by a splitter module having the features mentioned in claim 9. A splitter module according to the invention has at least one three-phase interface and three single-phase WO 2006/066785 - 3 - PCT/EP2005/013474 interfaces. Three phase conductors are guided from the three-phase interface to in each case the single-phase interfaces within the splitter module. Such a splitter module allows for a connection of a busbar module with a three-phase interface to three single-phase circuit breakers. Busbar modules having a three-phase interface are known for switchgear assemblies having a low rated voltage, in particular of from 100 kV to 200 kV. Advantageously, a known busbar module can be used in a high-voltage switchgear assembly according to the invention with the aid of a splitter module. Furthermore, such a splitter module allows three single-phase circuit breakers to be connected to a three-phase outgoing feeder unit. Further advantageous configurations of the invention are provided in the dependent claims. The invention, advantageous configurations and improvements of the invention and further advantages will be explained and described in more detail with reference to the drawings, in which exemplary embodiments of the invention are illustrated and in which: figure 1 shows a circuit diagram of a first outgoing feeder panel of a switchgear assembly according to the invention, figure 2 shows a circuit diagram of a second outgoing feeder panel of a switchgear assembly according to the invention, figure 3 shows a splitter module for connection to two busbars, figure 4 shows a splitter module for connection to an outgoing feeder unit, and WO 2006/066785 - 4 - PCT/EP2005/013474 figure 5 shows a circuit diagram of a third outgoing feeder panel of a switchgear assembly- according to the invention. Figure 1 shows a circuit diagram of a first three-phase outgoing feeder panel 60 of a three-phase switchgear assembly according to the invention. The switchgear assembly is designed for a rated voltage of approximately from 2 00 kV to 250 kV. However, use at a lower rated voltage, for example of from 100 kV to 2 00 kV, or at a higher rated voltage, for example of from 250 kV to 400 kV, is also within the concept of the invention. The switchgear assembly illustrated is in the form of a metal-encapsulated, gas-insulated high-voltage switchgear assembly. Sulfur hexafluoride (SF6) is used as the insulating gas. Alternatively, nitrogen (N2) or carbon dioxide (CO2) can be used as the insulating gas. The switchgear assembly has a busbar having three phase conductors LI, L2, L3. The three phase conductors LI, L2, L3 are guided in the region of the first; outgoing feeder panel 60 within a first busbar module 4 0 and further to busbar modules (not illustrated here) of adjacent panels. The housing of the first busbar module 4 0 is cylindrical, the phase conductors LI, L2, L3 of the busbar being guided parallel to the mid-axis of the housing of the first busbar module 40. The first busbar module 4 0 has three flange connectors 118, 128, 138 for connecting circuit breaker housings or other modules. These flange connectors are arranged on the outside of the cylindrical housing of the first busbar module 4 0 so as to protrude radially and so as to lie adjacent to one another along a surface line. WO 2006/066785 - 5 - PCT/EP2005/013474 Furthermore, the first busbar module 4 has in each case one flange connector (not illustrated here) for connecting in each case one further busbar module or another element, such as a covering cap, for example, at each end side of its cylindrical housing. A first busbar isolator 11 is associated with the first phase conductor LI and is connected on the input side to the first phase conductor LI. The busbar isolator 11 is in this case likewise arranged within the first busbar module 40. Correspondingly, the second phase conductor L2 is connected to a second busbar isolator 21, and the third phase conductor L3 is connected to a third busbar isolator 31. Furthermore, in each case one grounding switch (not illustrated here) is associated with each busbar isolator 11, 21, 31 and is connected to the output of the respective busbar isolator 11, 21, 31. The busbar isolators 11, 21, 31 and the associated grounding switches can in this case be in the form of separate switching devices or in the form of a combined disconnecting and grounding switch. The busbar isolators 11, 21, 31 are in this case in particular in the form of sliding-contact isolators, but a configuration as rotary isolators is also conceivable. A first circuit breaker 12 is associated with the first busbar isolator 11, and said first busbar isolator is connected to said first circuit breaker on the output side. The first circuit breaker 12 is in rhis case arranged in a separate, first circuit breaker housing 13, which is fixed on the first flange connector 118 of the first busbar module 40. Correspondingly, a second circuit breaker 22 is associated with the second busbar isolator 21. In this WO 2006/066785 - 6 - PCT/EP2005/013474 case, the second circuit breaker 22 is arranged in a separate second circuit breaker housing 23, which is fixed to the second flange connector 128 of the first busbar module 40. A third circuit breaker 32 is associated with the third busbar isolator 31. The third circuit breaker 3 2 is arranged in a separate, third circuit breaker housing 33, which is fixed to the third flange connector 138 of the first busbar module 40. The connecting conductors between the busbar isolators 11, 21, 31 and the circuit breakers 12, 22, 32 are in this case each guided separately through in each case one of the three flange connectors of the first busbar module 40. In addition, in each case one intermediate piece can be inserted between the circuit breaker housings 13, 23, 33 and the three flange connectors 118, 128, 138 of the first busbar module 40. Such an intermediate piece is in the form of a branch piece, for example, and therefore allows the connection of two or more busbars. In this way, the circuit breakers can be connected comparatively easily to a plurality of busbars. A first outgoing feeder housing 14, which is split into a plurality of segments (not illustrated here) which are connected in series, adjoins the first circuit breaker housing 13. In this case, further components (not illustrated here), such as an outgoing feeder isolator and an outgoing feeder grounding switch, for example, are arranged in the segments of the first outgoing feeder housing 14. The first outgoing feeder housing 14 has a first cable connection point 15, to which a high-voltage cable can be connected. Correspondingly, the second circuit breaker housing 23 is connected to a second outgoing feeder housing 24, which has a second cable connection point 25, and the WO 2006/066785 - 7 - PCT/EP2005/013474 third circuit breaker housing 33 is connected to a third outgoing feeder housing 34 with a third cable connection point 35. Voltage transformers (not illustrated here) are arranged on the outgoing feeder housings 14,, 24, 34, which voltage transformers are connected to the corresponding phase conductors LI, L2, L3 and measure their voltage to ground. Instead of the cable connection points 15, 25, 35, outdoor bushings for connection to cables of an overhead line can also easily be provided. Connection elements for connecting a transformer are also conceivable and within the concept of the invention. Figure 2 shows a circuit diagram of a second three- phase outgoing feeder panel 70 of a three-phase switchgear assembly according to the invention. In the text which follows, the same reference symbols as in figure 1 are used for identical components. In a similar manner to as in figure 1, the three phase conductors LI, L2, L3 of a busbar run within a second, cylindrical busbar module 41 parallel to its mid-axis, and the busbar isolators 11, 21, 31, which are associated with the phase conductors LI, L2, L3, are arranged within the housing of the second busbar module 41. The second busbar module 41 has a radially protruding flange connector, which is arranged on the outside of the housing of said second busbar module and to which a first splitter module 42 is fixed. Furthermore, the second busbar module 41 has in each case one flange connector (not illustrated here) for connecting in each case one further busbar module or another element, such as a covering cap, for example, WO 2006/066785 - 8 - PCT/EP2005/013474 at each end side of its cylindrical housing. The first splitter module 42 has a first three-phase interface 51 by means of which it is connected to the outputs of the busbar isolators 11, 21, 31. This first three-phase interface 51 of the first splitter module 42 also comprises a flange connector, by means of which the first splitter module 42 is connected, for example screwed, to the flange connector of the second busbar module 41. The first splitter module 42 also has three single- phase interfaces 16, 26, 36, to which in each case one single-phase circuit breaker 12, 22, 32 is connected. The connection between the housing of the first splitter module 41 and the circuit breaker housings 13, 23, 33 is also produced by means of flange connectors. All of the switching devices, such as the circuit breakers 12, 22, 32, the busbar isolators 11, 21, 31 or grounding switches, for example, are arranged outside of the housing of the first splitter module 42. Only rigid electrical conductors are guided in each case from the single-phase interfaces 16, 26, 36 to the first three-phase interface 51 in the interior of the splitter module 42. On the outgoing feeder side, a third splitter module 44 is connected to the circuit breaker housings 13, 23, 33. The third splitter module 44 has, for this purpose, three single-phase interfaces 18, 28, 38, by means of which it is connected to in each case one of the circuit breaker housings 13, 23, 33. The third splitter module 44 furthermore has a second three-phase interface 52, to which a three-phase outgoing feeder unit 46 is connected. The outgoing feeder unit 46 is split into a plurality WO 2006/066785 - 9 - PCT/EP2005/013474 of segments (not illustrated here) which are connected in series and in which further components (not illustrated here) , such as three outgoing feeder isolators, three outgoing feeder grounding switches and three high-speed grounding switches, for example, are arranged. A three-phase voltage transformer (not illustrated here), which measures the voltages of the conductors with respect to one another arid/or the voltages of the conductors with respect to ground, is fixed to the outgoing feeder unit 46. The outgoing feeder unit 4 6 furthermore comprises, on the outgoing feeder side, a three-phase connection point (not shown here) having three cable connection points for connecting a high-voltage cable. Likewise, a three-phase outdoor bushing for connection to cables of an overhead line or a three-phase connection element for connecting a transformer are also conceivable. As an alternative to the three-phase connection point, which is laid on the outgoing feeder side, three single-phase connection points can also be realized, for example for connecting high-voltage cables. Switching devices, such as the circuit breakers 12, 22, 32, outgoing feeder isolators or outgoing feeder grounding switches, for example, are arranged outside of the housing of the third splitter module 44. Only rigid electrical conductors are guided in each case from the single-phase interfaces 18, 28, 38 to the second three-phase interface 52 in the interior of the third splitter module 44. Figure 3 illustrates a second splitter module 43 having a third three-phase interface 53 and a fourth three- phase interface 54. The three-phase interfaces 53, 54 are used for connection to in each case one busbar. The second splitter module 43 in this case has a WO 2006/066785 - 10 - PCT/EP2005/013474 cylindrical housing, whose mid axis runs at right angles to the plane of the drawing. The third three-phase interface 53 is fitted to the outwardly pointing side of this cylindrical housing. The third three-phase interface 53 comprises, in addition to the three electrical phase conductors LI, L2, L3, a flange connector for fixing it to a second busbar module 41 (not shown here). The three electrical phase conductors LI, L2, L3 pass through the flange connector of the third three-phase interface 53 and can be connected to busbar isolators of a busbar module. Furthermore, the fourth three-phase interface 54, which likewise has three electrical phase conductors LI, L2, L3 and a flange connector for fixing it to a busbar module (not shown here), is attached to the outwardly pointing side of the cylindrical housing of the second splitter module 43. The three electrical phase conductors LI, L2, L3 pass through the flange connector of the fourth three-phase interface 54 and can be connected to busbar isolators of a busbar module. Furthermore, a seventh single-phase interface 116, an eighth single-phase interface and a ninth single-phase interface are located on the outwardly pointing side of the cylindrical housing of the second splitter module 43, in this example diametrically opposite the third three-phase interface 53. These three single-phase interfaces each have a flange connector for fixing in each case one circuit breaker housing (not shown here). Only the seventh single-phase interface 116 is visible in the illustration shown; the eighth single-phase interface and the ninth single-phase interface are hidden by the seventh single-phase interface 116. The first electrical phase conductor LI passes through the flange connector of the seventh single-phase WO 2006/066785 - 11 - PCT/EP2005/013474 interface 116 and can be connected to a single-phase circuit breaker. Correspondingly, the second electrical phase conductor L2 passes through the flange connector of the eighth single-phase interface (not visible here) and can be connected to a single-phase circuit breaker, and the third electrical phase conductor L3 passes through the flange connector of the ninth single-phase interface (not visible here) and can likewise be connected to a single-phase circuit breaker. A seventh current transformer 117, which is arranged within the housing of the second splitter module 43 in the vicinity of the seventh single-phase interface 116 and surrounds the first phase conductor LI, is associated with the seventh single-phase interface 116. Correspondingly, an eighth current transformer, which is arranged within the housing of the second splitter module 4 3 in the vicinity of the eighth single-phase interface and surrounds the phase conductor L2, is associated with the eighth single-phase interface. A ninth current transformer, which is arranged within the housing of the second splitter module 43 in the vicinity of the ninth single-phase interface and surrounds the phase conductor L3, is associated with the ninth single-phase interface. In the illustration shown, that section of the phase conductor L2 which runs through the eighth single-phase interface and that section of the phase conductor L3 which runs through the ninth single-phase interface are not visible, since they are hidden by the first phase conductor LI. Likewise, the eighth current transformer and the ninth current transformer are hidden by the seventh current transformer 117. WO 2006/066785 - 12 - PCT/EP2005/013474 In this example, the second splitter module 4 3 has two three-phase interfaces 53, 54. However, it is also conceivable for one splitter module to have only one or more than two, for example three, three-phase interfaces. Figure 4 illustrates the third splitter module 44 for connection to an outgoing feeder unit. The third splitter module 44 has a second three-phase interface 52, which has, in addition to the three-electrical phase conductors LI, L2, L3, a flange connector for fixing an outgoing feeder unit (not shown here). Furthermore, the third splitter module 44 has a fourth single-phase interface 18, a fifth single-phase interface 28 and a sixth single-phase interface 38. The three single-phase interfaces 18, 28, 38 each comprise a flange connector for fixing in each case one circuit breaker housing (not shown here). A conductor section of the first phase conductor LI passes through the flange connector of the second three-phase interface 52 and is guided through the interior of the housing of the third splitter module 44 to the fourth single-phase interface 18, which it likewise passes through. A conductor section of the second phase conductor L2 passes through the flange connector of the second three-phase interface 52 and is guided through the interior of the housing of the third splitter module 44 to the fifth single-phase interface 28, which it likewise passes through. Correspondingly, a conductor section of the third phase conductor L3 passes through the flange connector of the second three-phase interface 52 and is guided through the interior of the housing of the third splitter module 44 to the sixth single-phase interface 38, which it likewise passes WO 2006/066785 - 13 - PCT/EP2005/013474 through. A fourth current transformer 19, which is associated with the fourth single-phase interface 18, is arranged within the third splitter module 44 in the vicinity of the fourth single-phase interface 18 and surrounds the first phase conductor LI. Correspondingly, a fifth current transformer 29, which surrounds the phase conductor L2, is associated with the fifth single-phase interface 28, and a sixth current transformer 39, which surrounds the phase conductor L3, is associated with the sixth single-phase interface 38. In the example shown, the second three-phase interface 52 is arranged on that side of the housing of the third splitter module 44 which lies diametrically opposite the single-phase interfaces 18, 28, 38. Other arrangements are also conceivable. For example, the three-phase interface 52 can be arranged such that its mid-axis forms a right angle with the mid-axes of the single-phase interfaces 18, 28, 38. Figure 5 illustrates a circuit diagram of a third three-phase outgoing feeder panel 80 of a three-phase switchgear assembly according to the invention. The third outgoing feeder panel 80 in this case has a second busbar module 41. A radially protruding flange connector, to which a first splitter module 42 is fixed by means of the flange connector of its first three- phase interface 51, is attached to the outside of the cylindrical housing of the second busbar module 41. In each case one single-phase circuit breaker 12, 22, 32 is connected to the single-phase interfaces 16, 26, 36 of the first splitter module 42. In this case, in each case one single-phase outgoing feeder housing 14, WO 2006/066785 - 14 - PCT/EP2005/013474 24, 25 is connected to the circuit breaker housings 13, 23, 33 of the single-phase circuit breakers 12, 22, 32. WO 2006/066785 - 15 - PCT/EP2005/013474 List of reference symbols LI: First phase conductor 31: Third busbar isolator L2: Second phase 32: Third circuit breaker conductor L3: Third phase conductor 33: Third circuit breaker housing 34: Third outgoing feeder housing 11: First busbar isolator 35: Third cable connection point 12: First circuit breaker 36: Third single-phase interface 13: First circuit breaker 37: Third current housing transformer 14: First outgoing feeder 38: Sixth single-phase housing interface 15: First cable 39: Sixth current connection point transformer 16: First single-phase 138: Third flange interface connector 17: First current transformer 18: Fourth single-phase 40: First busbar module interface 19: Fourth current 41: Second busbar module transformer 116: Seventh single-phase 42: First splitter module interface 117: Seventh current 43: Second splitter transformer module 118: First flange 44: Third splitter module connector 46: Outgoing feeder unit 21: Second busbar isolator 22: Second circuit 51: First three-phase breaker interface WO 2006/066785 - 16 - PCT/EP2005/013474 23: Second circuit 52: Second three-phase breaker housing interface 24: Second outgoing 53: Third three-phase feeder housing interface 25: Second cable 54: Fourth three-phase connection point interface 26: Second single-phase interface 27: Second current 60: First outgoing feeder transformer panel 28: Fifth single-phase 70: Second outgoing interface feeder panel 29: Fifth current 80: Third outgoing feeder transformer panel 128: Second flange connector WO 2006/066785 - 17 - PCT/EP2005/013474 Patent Claims 1. A gas-insulated high-voltage switchgear assembly, having at least one busbar having three phase conductors (LI, L2, L3), each phase conductor (LI, L2, L3) being connected to the input of a busbar isolator (11, 21, 31) associated with it, the phase conductors (L1, L2, L3) and the busbar isolators (11, 21, 31) being arranged in a three-phase busbar module (40, 41), and having three single-phase circuit breakers (12, 22, 32), which are each arranged in a separate circuit breaker housing (13, 23, 33), each busbar isolator (11, 21, 31) being connected on the output side to in each case one circuit breaker (12, 22, 32) associated with it. 2. The high-voltage switchgear assembly as claimed in claim 1, characterized in that the busbar isolators (11, 21, 31) in the busbar module (40, 41) and the circuit breakers (12, 22, 32) are associated with a busbar branch. 3. The high-voltage switchgear assembly as claimed in either of claims 1 and 2, characterized in that the high-voltage switchgear assembly has at least one splitting module, which has at least one three-phase interface (51, 52, 53, 54) and three single-phase interfaces (16, 26, 36, 18, 28, 38) and three phase conductors (LI, L2, L3), in each case one of the phase conductors (LI, L2, L3) being guided by the at least one three-phase interface (51, 52, 53, 54) to in each case one of the single-phase interfaces (16, 26, 36, 18, 28, 38) . 4. The high-voltage switchgear assembly as claimed in claim 3, characterized in that a first splitting module, which is in the form of a splitter module (42, 43, 44), is inserted between the busbar module (41) and WO 2006/066785 - 18 - PCT/EP2005/013474 the circuit breakers (12, 22, 32). 5. The high-voltage switchgear assembly as claimed in either of claims 3 and 4, characterized in that a second splitting module, which is in the form of a splitter module (42, 43, 44), is inserted between a three-phase outgoing feeder unit (46) and the circuit breakers (12, 22, 32). 6. The high-voltage switchgear assembly as claimed in one of the preceding claims, characterized in that at least two current transformers are associated with each circuit breaker (12, 22, 32), at least one current transformer (17, 27, 37) being arranged on the input side and at least one current transformer (19, 29, 39) being arranged on the output side of the respective circuit breaker (12, 22, 32). 7. A busbar module (40) for a gas-insulated high- voltage switchgear assembly, having three phase conductors (LI, L2, L3) and having three busbar isolators (11, 21, 31) , which are arranged in a common housing, each phase conductor (LI, L2, L3) being connected to the input of the busbar isolator (11, 21, 31) associated with it, characterized in that a single- phase interface is associated with each busbar isolator (11, 21, 31) on the output side. 8. The busbar module (4 0) as claimed in claim 7, characterized in that the phase conductors (LI, L2, L3) can be connected to the phase conductors (LI, L2, L3) of two further busbar modules (4 0, 41). 9. A splitter module (42, 43, 44) for a gas-insulated high-voltage switchgear assembly, which has at least one three-phase interface (51, 52, 53, 54) and three single-phase interfaces (16, 26, 36, 18, 28, 38), having three phase conductors (LI, L2, L3), in each WO 2006/066785 - 19 - PCT/EP2005/013474 case one of the phase conductors (LI, L2, L3) being guided from the at least one three-phase interface (51, 52, 53, 54) to in each case one of the single-phase interfaces (16, 26, 36, 18, 28, 38) . 10. The splitter module (42, 43, 44) as claimed in claim 9, characterized in that switching devices are avoided in the interior of the housing of the splitter module (42, 43, 44). 11. The splitter module (42, 43, 44) as claimed in either of claims 9 and 10, characterized in that at least one current transformer (17, 27, 37, 19, 29, 39) is associated with each phase conductor (LI, L2, L3) in the interior of the housing of the splitter module (42, 43, 44) . 12. The splitter module (42, 43, 44) as claimed in claim 11, characterized in that at least one of the current transformers (17, 27, 37, 19, 29, 39) is arranged in the vicinity of its single-phase interface (16, 26, 36, 18, 28, 38) for each phase conductor (LI, L2, L3). 13. The splitter module (42, 44) as claimed in one of claims 9 to 12, characterized in that the splitter module (42, 44) has precisely one three-phase interface (51, 52) . The invention relates to a gas-insulated high voltage switchgear, comprising at least one bus bar with three phase conductors (L1, L2, L3), whereby each phase conductor (L1, L2, L3) is connected to the input of a respectively provided bus bar section (11, 21, 31). The phase conductor (L1, L2, L3) and the bus bar section (11, 21, 31) are arranged in a three-phase bus bar module (40,41) with three single-phase power switches (12, 22, 32), each arranged in a separate power switch housing (13, 23, 33) and each bus bar section (11, 21, 31) is connected at the output therefrom to a respectively provided power switch (12, 22, 32).

Full Text

WO 2006/066785 PCT/EP2005/013474
High-voltage switchgear assembly
Description
The invention relates to a gas-insulated high-voltage
switchgear assembly. The invention further relates to
modules for the gas-insulated high-voltage switchgear
assembly according to the invention.
It is generally known that gas-insulated high-voltage
switchgear assemblies with rated voltages of above
200 kV are generally designed as single-phase-
encapsulated systems. In this case, the switching
devices, such as circuit breakers, isolabors and
grounding switches, for example, and further
components, such as overhead line connections, for
example, are designed to be single-phase and are
arranged in separate housings.
Also, the three phase conductors of a busbar are
arranged in separate, generally tubular, housings.
However, this design results in a comparatively high
space requirement.
The invention is based on the object of specifying a
high-voltage switchgear assembly having a reduced space
requirement.
This object is achieved according to the invention by a
high-voltage switchgear assembly having the features
mentioned in claim 1.
A gas-insulated high-voltage switchgear assembly
according to the invention comprises at least one
busbar having three phase conductors, each phase
conductor being connected to the input of a busbar
isolator associated with it. In this case, the phase
conductors and the busbar isolators are arranged in a

WO 2006/066785 - 2 - PCT/EP2005/013474
common three-phase busbar module. The high-voltage
switchgear assembly according to the invention further
comprises three single-phase circuit breakers, which
are each arranged in a separate circuit breaker
housing. Each busbar isolator is in this case connected
on the output side to in each case one circuit breaker
associated with it.
Owing to this arrangement in which the three phase
conductors of a busbar and the associated busbar
isolators are arranged in a common housing, the space
requirement of the high-voltage switchgear assembly is
advantageously reduced in comparison with a
conventional high-voltage switchgear assembly.
The object is also achieved by a busbar module having
the features mentioned in claim 7.
Accordingly, a busbar module according to the
invention, in which three phase conductors of a busbar
and three busbar isolators are arranged and each phase
conductor is connected to the input of the busbar
isolator associated with it, has three single-phase
interfaces, which are each associated with a busbar
isolator.
Such a busbar module allows for a direct and therefore
comparatively simple connection of three single-pole
circuit breakers. It is not necessary to insert
additional modules. The design of the high-voltage
switchgear assembly is simplified, and the embodiment
is particularly space-saving.
The object is also achieved by a splitter module having
the features mentioned in claim 9.
A splitter module according to the invention has at
least one three-phase interface and three single-phase

WO 2006/066785 - 3 - PCT/EP2005/013474
interfaces. Three phase conductors are guided from the
three-phase interface to in each case the single-phase
interfaces within the splitter module.
Such a splitter module allows for a connection of a
busbar module with a three-phase interface to three
single-phase circuit breakers.
Busbar modules having a three-phase interface are known
for switchgear assemblies having a low rated voltage,
in particular of from 100 kV to 200 kV. Advantageously,
a known busbar module can be used in a high-voltage
switchgear assembly according to the invention with the
aid of a splitter module.
Furthermore, such a splitter module allows three
single-phase circuit breakers to be connected to a
three-phase outgoing feeder unit.
Further advantageous configurations of the invention
are provided in the dependent claims.
The invention, advantageous configurations and
improvements of the invention and further advantages
will be explained and described in more detail with
reference to the drawings, in which exemplary
embodiments of the invention are illustrated and in
which:
figure 1 shows a circuit diagram of a first outgoing
feeder panel of a switchgear assembly
according to the invention,
figure 2 shows a circuit diagram of a second outgoing
feeder panel of a switchgear assembly
according to the invention,
figure 3 shows a splitter module for connection to two
busbars,
figure 4 shows a splitter module for connection to an
outgoing feeder unit, and

WO 2006/066785 - 4 - PCT/EP2005/013474
figure 5 shows a circuit diagram of a third outgoing
feeder panel of a switchgear assembly-
according to the invention.
Figure 1 shows a circuit diagram of a first three-phase
outgoing feeder panel 60 of a three-phase switchgear
assembly according to the invention. The switchgear
assembly is designed for a rated voltage of
approximately from 2 00 kV to 250 kV. However, use at a
lower rated voltage, for example of from 100 kV to
2 00 kV, or at a higher rated voltage, for example of
from 250 kV to 400 kV, is also within the concept of
the invention.
The switchgear assembly illustrated is in the form of a
metal-encapsulated, gas-insulated high-voltage
switchgear assembly. Sulfur hexafluoride (SF6) is used
as the insulating gas. Alternatively, nitrogen (N2) or
carbon dioxide (CO2) can be used as the insulating gas.
The switchgear assembly has a busbar having three phase
conductors LI, L2, L3. The three phase conductors LI,
L2, L3 are guided in the region of the first; outgoing
feeder panel 60 within a first busbar module 4 0 and
further to busbar modules (not illustrated here) of
adjacent panels.
The housing of the first busbar module 4 0 is
cylindrical, the phase conductors LI, L2, L3 of the
busbar being guided parallel to the mid-axis of the
housing of the first busbar module 40.
The first busbar module 4 0 has three flange connectors
118, 128, 138 for connecting circuit breaker housings
or other modules. These flange connectors are arranged
on the outside of the cylindrical housing of the first
busbar module 4 0 so as to protrude radially and so as
to lie adjacent to one another along a surface line.

WO 2006/066785 - 5 - PCT/EP2005/013474
Furthermore, the first busbar module 4 has in each case
one flange connector (not illustrated here) for
connecting in each case one further busbar module or
another element, such as a covering cap, for example,
at each end side of its cylindrical housing.
A first busbar isolator 11 is associated with the first
phase conductor LI and is connected on the input side
to the first phase conductor LI. The busbar isolator 11
is in this case likewise arranged within the first
busbar module 40. Correspondingly, the second phase
conductor L2 is connected to a second busbar isolator
21, and the third phase conductor L3 is connected to a
third busbar isolator 31.
Furthermore, in each case one grounding switch (not
illustrated here) is associated with each busbar
isolator 11, 21, 31 and is connected to the output of
the respective busbar isolator 11, 21, 31. The busbar
isolators 11, 21, 31 and the associated grounding
switches can in this case be in the form of separate
switching devices or in the form of a combined
disconnecting and grounding switch. The busbar
isolators 11, 21, 31 are in this case in particular in
the form of sliding-contact isolators, but a
configuration as rotary isolators is also conceivable.
A first circuit breaker 12 is associated with the first
busbar isolator 11, and said first busbar isolator is
connected to said first circuit breaker on the output
side. The first circuit breaker 12 is in rhis case
arranged in a separate, first circuit breaker housing
13, which is fixed on the first flange connector 118 of
the first busbar module 40.
Correspondingly, a second circuit breaker 22 is
associated with the second busbar isolator 21. In this

WO 2006/066785 - 6 - PCT/EP2005/013474
case, the second circuit breaker 22 is arranged in a
separate second circuit breaker housing 23, which is
fixed to the second flange connector 128 of the first
busbar module 40. A third circuit breaker 32 is
associated with the third busbar isolator 31. The third
circuit breaker 3 2 is arranged in a separate, third
circuit breaker housing 33, which is fixed to the third
flange connector 138 of the first busbar module 40.
The connecting conductors between the busbar isolators
11, 21, 31 and the circuit breakers 12, 22, 32 are in
this case each guided separately through in each case
one of the three flange connectors of the first busbar
module 40.
In addition, in each case one intermediate piece can be
inserted between the circuit breaker housings 13, 23,
33 and the three flange connectors 118, 128, 138 of the
first busbar module 40. Such an intermediate piece is
in the form of a branch piece, for example, and
therefore allows the connection of two or more busbars.
In this way, the circuit breakers can be connected
comparatively easily to a plurality of busbars.
A first outgoing feeder housing 14, which is split into
a plurality of segments (not illustrated here) which
are connected in series, adjoins the first circuit
breaker housing 13. In this case, further components
(not illustrated here), such as an outgoing feeder
isolator and an outgoing feeder grounding switch, for
example, are arranged in the segments of the first
outgoing feeder housing 14. The first outgoing feeder
housing 14 has a first cable connection point 15, to
which a high-voltage cable can be connected.
Correspondingly, the second circuit breaker housing 23
is connected to a second outgoing feeder housing 24,
which has a second cable connection point 25, and the

WO 2006/066785 - 7 - PCT/EP2005/013474
third circuit breaker housing 33 is connected to a
third outgoing feeder housing 34 with a third cable
connection point 35.
Voltage transformers (not illustrated here) are
arranged on the outgoing feeder housings 14,, 24, 34,
which voltage transformers are connected to the
corresponding phase conductors LI, L2, L3 and measure
their voltage to ground.
Instead of the cable connection points 15, 25, 35,
outdoor bushings for connection to cables of an
overhead line can also easily be provided. Connection
elements for connecting a transformer are also
conceivable and within the concept of the invention.
Figure 2 shows a circuit diagram of a second three-
phase outgoing feeder panel 70 of a three-phase
switchgear assembly according to the invention. In the
text which follows, the same reference symbols as in
figure 1 are used for identical components. In a
similar manner to as in figure 1, the three phase
conductors LI, L2, L3 of a busbar run within a second,
cylindrical busbar module 41 parallel to its mid-axis,
and the busbar isolators 11, 21, 31, which are
associated with the phase conductors LI, L2, L3, are
arranged within the housing of the second busbar module
41.
The second busbar module 41 has a radially protruding
flange connector, which is arranged on the outside of
the housing of said second busbar module and to which a
first splitter module 42 is fixed.
Furthermore, the second busbar module 41 has in each
case one flange connector (not illustrated here) for
connecting in each case one further busbar module or
another element, such as a covering cap, for example,

WO 2006/066785 - 8 - PCT/EP2005/013474
at each end side of its cylindrical housing.
The first splitter module 42 has a first three-phase
interface 51 by means of which it is connected to the
outputs of the busbar isolators 11, 21, 31. This first
three-phase interface 51 of the first splitter module
42 also comprises a flange connector, by means of which
the first splitter module 42 is connected, for example
screwed, to the flange connector of the second busbar
module 41.
The first splitter module 42 also has three single-
phase interfaces 16, 26, 36, to which in each case one
single-phase circuit breaker 12, 22, 32 is connected.
The connection between the housing of the first
splitter module 41 and the circuit breaker housings 13,
23, 33 is also produced by means of flange connectors.
All of the switching devices, such as the circuit
breakers 12, 22, 32, the busbar isolators 11, 21, 31 or
grounding switches, for example, are arranged outside
of the housing of the first splitter module 42. Only
rigid electrical conductors are guided in each case
from the single-phase interfaces 16, 26, 36 to the
first three-phase interface 51 in the interior of the
splitter module 42.
On the outgoing feeder side, a third splitter module 44
is connected to the circuit breaker housings 13, 23,
33. The third splitter module 44 has, for this purpose,
three single-phase interfaces 18, 28, 38, by means of
which it is connected to in each case one of the
circuit breaker housings 13, 23, 33. The third splitter
module 44 furthermore has a second three-phase
interface 52, to which a three-phase outgoing feeder
unit 46 is connected.
The outgoing feeder unit 46 is split into a plurality

WO 2006/066785 - 9 - PCT/EP2005/013474
of segments (not illustrated here) which are connected
in series and in which further components (not
illustrated here) , such as three outgoing feeder
isolators, three outgoing feeder grounding switches and
three high-speed grounding switches, for example, are
arranged. A three-phase voltage transformer (not
illustrated here), which measures the voltages of the
conductors with respect to one another arid/or the
voltages of the conductors with respect to ground, is
fixed to the outgoing feeder unit 46.
The outgoing feeder unit 4 6 furthermore comprises, on
the outgoing feeder side, a three-phase connection
point (not shown here) having three cable connection
points for connecting a high-voltage cable. Likewise, a
three-phase outdoor bushing for connection to cables of
an overhead line or a three-phase connection element
for connecting a transformer are also conceivable.
As an alternative to the three-phase connection point,
which is laid on the outgoing feeder side, three
single-phase connection points can also be realized,
for example for connecting high-voltage cables.
Switching devices, such as the circuit breakers 12, 22,
32, outgoing feeder isolators or outgoing feeder
grounding switches, for example, are arranged outside
of the housing of the third splitter module 44. Only
rigid electrical conductors are guided in each case
from the single-phase interfaces 18, 28, 38 to the
second three-phase interface 52 in the interior of the
third splitter module 44.
Figure 3 illustrates a second splitter module 43 having
a third three-phase interface 53 and a fourth three-
phase interface 54. The three-phase interfaces 53, 54
are used for connection to in each case one busbar. The
second splitter module 43 in this case has a

WO 2006/066785 - 10 - PCT/EP2005/013474
cylindrical housing, whose mid axis runs at right
angles to the plane of the drawing.
The third three-phase interface 53 is fitted to the
outwardly pointing side of this cylindrical housing.
The third three-phase interface 53 comprises, in
addition to the three electrical phase conductors LI,
L2, L3, a flange connector for fixing it to a second
busbar module 41 (not shown here). The three electrical
phase conductors LI, L2, L3 pass through the flange
connector of the third three-phase interface 53 and can
be connected to busbar isolators of a busbar module.
Furthermore, the fourth three-phase interface 54, which
likewise has three electrical phase conductors LI, L2,
L3 and a flange connector for fixing it to a busbar
module (not shown here), is attached to the outwardly
pointing side of the cylindrical housing of the second
splitter module 43. The three electrical phase
conductors LI, L2, L3 pass through the flange connector
of the fourth three-phase interface 54 and can be
connected to busbar isolators of a busbar module.
Furthermore, a seventh single-phase interface 116, an
eighth single-phase interface and a ninth single-phase
interface are located on the outwardly pointing side of
the cylindrical housing of the second splitter module
43, in this example diametrically opposite the third
three-phase interface 53. These three single-phase
interfaces each have a flange connector for fixing in
each case one circuit breaker housing (not shown here).
Only the seventh single-phase interface 116 is visible
in the illustration shown; the eighth single-phase
interface and the ninth single-phase interface are
hidden by the seventh single-phase interface 116.
The first electrical phase conductor LI passes through
the flange connector of the seventh single-phase

WO 2006/066785 - 11 - PCT/EP2005/013474
interface 116 and can be connected to a single-phase
circuit breaker.
Correspondingly, the second electrical phase conductor
L2 passes through the flange connector of the eighth
single-phase interface (not visible here) and can be
connected to a single-phase circuit breaker, and the
third electrical phase conductor L3 passes through the
flange connector of the ninth single-phase interface
(not visible here) and can likewise be connected to a
single-phase circuit breaker.
A seventh current transformer 117, which is arranged
within the housing of the second splitter module 43 in
the vicinity of the seventh single-phase interface 116
and surrounds the first phase conductor LI, is
associated with the seventh single-phase interface 116.
Correspondingly, an eighth current transformer, which
is arranged within the housing of the second splitter
module 4 3 in the vicinity of the eighth single-phase
interface and surrounds the phase conductor L2, is
associated with the eighth single-phase interface. A
ninth current transformer, which is arranged within the
housing of the second splitter module 43 in the
vicinity of the ninth single-phase interface and
surrounds the phase conductor L3, is associated with
the ninth single-phase interface.
In the illustration shown, that section of the phase
conductor L2 which runs through the eighth single-phase
interface and that section of the phase conductor L3
which runs through the ninth single-phase interface are
not visible, since they are hidden by the first phase
conductor LI. Likewise, the eighth current transformer
and the ninth current transformer are hidden by the
seventh current transformer 117.

WO 2006/066785 - 12 - PCT/EP2005/013474
In this example, the second splitter module 4 3 has two
three-phase interfaces 53, 54. However, it is also
conceivable for one splitter module to have only one or
more than two, for example three, three-phase
interfaces.
Figure 4 illustrates the third splitter module 44 for
connection to an outgoing feeder unit. The third
splitter module 44 has a second three-phase interface
52, which has, in addition to the three-electrical
phase conductors LI, L2, L3, a flange connector for
fixing an outgoing feeder unit (not shown here).
Furthermore, the third splitter module 44 has a fourth
single-phase interface 18, a fifth single-phase
interface 28 and a sixth single-phase interface 38. The
three single-phase interfaces 18, 28, 38 each comprise
a flange connector for fixing in each case one circuit
breaker housing (not shown here).
A conductor section of the first phase conductor LI
passes through the flange connector of the second
three-phase interface 52 and is guided through the
interior of the housing of the third splitter module 44
to the fourth single-phase interface 18, which it
likewise passes through.
A conductor section of the second phase conductor L2
passes through the flange connector of the second
three-phase interface 52 and is guided through the
interior of the housing of the third splitter module 44
to the fifth single-phase interface 28, which it
likewise passes through. Correspondingly, a conductor
section of the third phase conductor L3 passes through
the flange connector of the second three-phase
interface 52 and is guided through the interior of the
housing of the third splitter module 44 to the sixth
single-phase interface 38, which it likewise passes

WO 2006/066785 - 13 - PCT/EP2005/013474
through.
A fourth current transformer 19, which is associated
with the fourth single-phase interface 18, is arranged
within the third splitter module 44 in the vicinity of
the fourth single-phase interface 18 and surrounds the
first phase conductor LI.
Correspondingly, a fifth current transformer 29, which
surrounds the phase conductor L2, is associated with
the fifth single-phase interface 28, and a sixth
current transformer 39, which surrounds the phase
conductor L3, is associated with the sixth single-phase
interface 38.
In the example shown, the second three-phase interface
52 is arranged on that side of the housing of the third
splitter module 44 which lies diametrically opposite
the single-phase interfaces 18, 28, 38. Other
arrangements are also conceivable. For example, the
three-phase interface 52 can be arranged such that its
mid-axis forms a right angle with the mid-axes of the
single-phase interfaces 18, 28, 38.
Figure 5 illustrates a circuit diagram of a third
three-phase outgoing feeder panel 80 of a three-phase
switchgear assembly according to the invention. The
third outgoing feeder panel 80 in this case has a
second busbar module 41. A radially protruding flange
connector, to which a first splitter module 42 is fixed
by means of the flange connector of its first three-
phase interface 51, is attached to the outside of the
cylindrical housing of the second busbar module 41.
In each case one single-phase circuit breaker 12, 22,
32 is connected to the single-phase interfaces 16, 26,
36 of the first splitter module 42. In this case, in
each case one single-phase outgoing feeder housing 14,

WO 2006/066785 - 14 - PCT/EP2005/013474
24, 25 is connected to the circuit breaker housings 13,
23, 33 of the single-phase circuit breakers 12, 22, 32.

WO 2006/066785 - 15 - PCT/EP2005/013474
List of reference symbols

LI: First phase conductor 31: Third busbar isolator
L2: Second phase 32: Third circuit breaker
conductor
L3: Third phase conductor 33: Third circuit breaker
housing
34: Third outgoing feeder
housing
11: First busbar isolator 35: Third cable
connection point
12: First circuit breaker 36: Third single-phase
interface
13: First circuit breaker 37: Third current
housing transformer
14: First outgoing feeder 38: Sixth single-phase
housing interface
15: First cable 39: Sixth current
connection point transformer
16: First single-phase 138: Third flange
interface connector
17: First current
transformer
18: Fourth single-phase 40: First busbar module
interface
19: Fourth current 41: Second busbar module
transformer
116: Seventh single-phase 42: First splitter module
interface
117: Seventh current 43: Second splitter
transformer module
118: First flange 44: Third splitter module
connector
46: Outgoing feeder unit
21: Second busbar
isolator
22: Second circuit 51: First three-phase
breaker interface

WO 2006/066785 - 16 - PCT/EP2005/013474

23: Second circuit 52: Second three-phase
breaker housing interface
24: Second outgoing 53: Third three-phase
feeder housing interface
25: Second cable 54: Fourth three-phase
connection point interface
26: Second single-phase
interface
27: Second current 60: First outgoing feeder
transformer panel
28: Fifth single-phase 70: Second outgoing
interface feeder panel
29: Fifth current 80: Third outgoing feeder
transformer panel
128: Second flange
connector

WO 2006/066785 - 17 - PCT/EP2005/013474
Patent Claims
1. A gas-insulated high-voltage switchgear assembly,
having at least one busbar having three phase
conductors (LI, L2, L3), each phase conductor (LI, L2,
L3) being connected to the input of a busbar isolator
(11, 21, 31) associated with it, the phase conductors
(L1, L2, L3) and the busbar isolators (11, 21, 31)
being arranged in a three-phase busbar module (40, 41),
and having three single-phase circuit breakers (12, 22,
32), which are each arranged in a separate circuit
breaker housing (13, 23, 33), each busbar isolator (11,
21, 31) being connected on the output side to in each
case one circuit breaker (12, 22, 32) associated with
it.
2. The high-voltage switchgear assembly as claimed in
claim 1, characterized in that the busbar isolators
(11, 21, 31) in the busbar module (40, 41) and the
circuit breakers (12, 22, 32) are associated with a
busbar branch.
3. The high-voltage switchgear assembly as claimed in
either of claims 1 and 2, characterized in that the
high-voltage switchgear assembly has at least one
splitting module, which has at least one three-phase
interface (51, 52, 53, 54) and three single-phase
interfaces (16, 26, 36, 18, 28, 38) and three phase
conductors (LI, L2, L3), in each case one of the phase
conductors (LI, L2, L3) being guided by the at least
one three-phase interface (51, 52, 53, 54) to in each
case one of the single-phase interfaces (16, 26, 36,
18, 28, 38) .
4. The high-voltage switchgear assembly as claimed in
claim 3, characterized in that a first splitting
module, which is in the form of a splitter module (42,
43, 44), is inserted between the busbar module (41) and

WO 2006/066785 - 18 - PCT/EP2005/013474
the circuit breakers (12, 22, 32).
5. The high-voltage switchgear assembly as claimed in
either of claims 3 and 4, characterized in that a
second splitting module, which is in the form of a
splitter module (42, 43, 44), is inserted between a
three-phase outgoing feeder unit (46) and the circuit
breakers (12, 22, 32).
6. The high-voltage switchgear assembly as claimed in
one of the preceding claims, characterized in that at
least two current transformers are associated with each
circuit breaker (12, 22, 32), at least one current
transformer (17, 27, 37) being arranged on the input
side and at least one current transformer (19, 29, 39)
being arranged on the output side of the respective
circuit breaker (12, 22, 32).
7. A busbar module (40) for a gas-insulated high-
voltage switchgear assembly, having three phase
conductors (LI, L2, L3) and having three busbar
isolators (11, 21, 31) , which are arranged in a common
housing, each phase conductor (LI, L2, L3) being
connected to the input of the busbar isolator (11, 21,
31) associated with it, characterized in that a single-
phase interface is associated with each busbar isolator
(11, 21, 31) on the output side.
8. The busbar module (4 0) as claimed in claim 7,
characterized in that the phase conductors (LI, L2, L3)
can be connected to the phase conductors (LI, L2, L3)
of two further busbar modules (4 0, 41).
9. A splitter module (42, 43, 44) for a gas-insulated
high-voltage switchgear assembly, which has at least
one three-phase interface (51, 52, 53, 54) and three
single-phase interfaces (16, 26, 36, 18, 28, 38),
having three phase conductors (LI, L2, L3), in each

WO 2006/066785 - 19 - PCT/EP2005/013474
case one of the phase conductors (LI, L2, L3) being
guided from the at least one three-phase interface (51,
52, 53, 54) to in each case one of the single-phase
interfaces (16, 26, 36, 18, 28, 38) .
10. The splitter module (42, 43, 44) as claimed in
claim 9, characterized in that switching devices are
avoided in the interior of the housing of the splitter
module (42, 43, 44).
11. The splitter module (42, 43, 44) as claimed in
either of claims 9 and 10, characterized in that at
least one current transformer (17, 27, 37, 19, 29, 39)
is associated with each phase conductor (LI, L2, L3) in
the interior of the housing of the splitter module (42,
43, 44) .
12. The splitter module (42, 43, 44) as claimed in
claim 11, characterized in that at least one of the
current transformers (17, 27, 37, 19, 29, 39) is
arranged in the vicinity of its single-phase interface
(16, 26, 36, 18, 28, 38) for each phase conductor (LI,
L2, L3).
13. The splitter module (42, 44) as claimed in one of
claims 9 to 12, characterized in that the splitter
module (42, 44) has precisely one three-phase interface
(51, 52) .

The invention relates to a gas-insulated high voltage switchgear, comprising at least
one bus bar with three phase conductors (L1, L2, L3), whereby each phase conductor
(L1, L2, L3) is connected to the input of a respectively provided bus bar section (11, 21,
31). The phase conductor (L1, L2, L3) and the bus bar section (11, 21, 31) are arranged
in a three-phase bus bar module (40,41) with three single-phase power switches (12,
22, 32), each arranged in a separate power switch housing (13, 23, 33) and each bus bar
section (11, 21, 31) is connected at the output therefrom to a respectively provided
power switch (12, 22, 32).

Documents:

01755-kolnp-2007-abstract.pdf

01755-kolnp-2007-claims.pdf

01755-kolnp-2007-correspondence others 1.1.pdf

01755-kolnp-2007-correspondence others 1.2.pdf

01755-kolnp-2007-correspondence others.pdf

01755-kolnp-2007-description complete.pdf

01755-kolnp-2007-drawings.pdf

01755-kolnp-2007-form 1.pdf

01755-kolnp-2007-form 2.pdf

01755-kolnp-2007-form 3.pdf

01755-kolnp-2007-form 5.pdf

01755-kolnp-2007-gpa.pdf

01755-kolnp-2007-international publication.pdf

01755-kolnp-2007-international search report.pdf

01755-kolnp-2007-pct request form.pdf

01755-kolnp-2007-priority document.pdf

1755-KOLNP-2007-(10-12-2014)-CORRESPONDENCE.pdf

1755-KOLNP-2007-(10-12-2014)-FORM-1.pdf

1755-KOLNP-2007-(17-11-2014)-ABSTRACT.pdf

1755-KOLNP-2007-(17-11-2014)-ANNEXURE TO FORM 3.pdf

1755-KOLNP-2007-(17-11-2014)-CLAIMS.pdf

1755-KOLNP-2007-(17-11-2014)-CORRESPONDENCE.pdf

1755-KOLNP-2007-(17-11-2014)-OTHERS.pdf

1755-KOLNP-2007-(17-11-2014)-PETITION UNDER RULE 137.pdf

1755-KOLNP-2007-(23-12-2014)-PETITION UNDER RULE 137.pdf

1755-kolnp-2007-form 18.pdf

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Patent Number

266037

Indian Patent Application Number

1755/KOLNP/2007

PG Journal Number

14/2015

Publication Date

03-Apr-2015

Grant Date

28-Mar-2015

Date of Filing

17-May-2007

Name of Patentee

ABB TECHNOLOGY AG

Applicant Address

AFFOLTERNSTRASSE 44 CH-8050 ZURICH

Inventors:

#	Inventor's Name	Inventor's Address
1	BETZ, THOMAS	VOGELSBERGSTR. 77, 63505 LANGENSELBOLD
2	GNANADHANDAPANI, IIANGO	KASHALDENSTR. 31, CH-8052 ZURICH
3	GRANATA, CARLO	VIA G. CONTI NO.9, I 26824 CAVENAGO D'ADDA

PCT International Classification Number

H01H 33/12

PCT International Application Number

PCT/EP2005/013474

PCT International Filing date

2005-12-15

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	10 2004 061 358.3	2004-12-21	Germany