The present disclosure relates generally to an insulating rotary diaphragm for a vacuum interrupter (VI) electrical switch. More particularly, it relates to an insulating diaphragm designed for use in VI switches where a lever is rotated by a line worker to manually open the switch.
Vacuum interrupter (VI) switches are a type of electrical switch that are often used to provide fault interruption and service restoration capability between medium voltage lateral lines and distribution transformers in an electrical distribution network. When a fault occurs, the VI switch opens its contacts to stop the flow of fault current. The VI switch also typically recloses the contacts after a brief time period, and stays closed in order to restore power to customers if the fault has self-cleared.
VI switches are used in both overhead powerline installations and in underground and ground-level (pad mounted) installations. A common design for a VI switch uses a linear electromagnetic actuator to drive one of the contacts into the open or closed position. Other types of actuators may also be used. In both overhead and underground/ground-level installations, VI switches may be required to have an external lever or handle, mechanically connected to the actuator, that can be pulled or turned by a line worker in order to manually disconnect the switch. To reduce risk to the line worker, the external lever is grounded.
A challenge encountered in the design of a VI switch is isolating the medium voltage switch components (i.e., the contacts, etc.) from the grounded external lever. One known technique for providing this isolation is to include a translational insulating rod between the switch body and the actuator, thus allowing the actuator and therefore also the external lever to be at ground potential. However, particularly in underground and ground-level installations, it is desirable to minimize the overall length of the entire VI switch assembly including the actuator and lever. The translational insulating rod adds undesirable length to the entire switch assembly.
Another known technique for providing isolation between the medium voltage portion of the switch and the external lever is to use insulating gases or fluids in a portion of a housing located between the actuator and the external lever. However, these insulating gases and fluids are expensive, and containing them within the housing without leaks is difficult.
In view of the circumstances described above, there is need for a VI switch assembly having an improved and simplified means of isolating the medium voltage components of the switch from the grounded external lever, while providing for a switch assembly with an overall length that is less than prior art designs.
The present disclosure describes an insulating rotary diaphragm for a vacuum interrupter (VI) electrical switch. The insulating diaphragm is designed for use in underground or pad-mounted VI switches where an external lever is rotated by a line worker to manually open the switch. A torsional insulating rod is coupled between a switch actuator and the external lever, and the diaphragm maintains constant contact with the insulating rod and an outer housing when the lever and rod are rotated, thus ensuring adequate isolation between the actuator and the lever. The diaphragm deforms torsionally when the lever and rod are rotated. This configuration allows the actuator to be at medium voltage, eliminates the need for a translational insulating rod between the medium voltage switch components and the lever, and thereby reduces the overall length of the VI switch.
Additional features of the present disclosure will become apparent from the following description and appended claims, taken in conjunction with the accompanying drawings.
The following discussion of the embodiments of the disclosure directed to an insulating rotary diaphragm for a vacuum interrupter (VI) electrical switch is merely exemplary and is in no way intended to limit the disclosure or its applications or uses.
An electrical power transmission/distribution network, often referred to as the electrical grid, includes circuit breakers, fuses and switches that open in the event of a fault to cut off potentially damaging fault currents. In the distribution portion of the grid, feeders and laterals provide power at medium voltage to residential and other end-use customers, where a distribution transformer performs the final transformation from medium voltage down to consumer voltages of 120/240 VAC. A switch with reclosing capability, often a vacuum interrupter (VI) switch, is typically located between the medium voltage lateral line and the distribution transformer.
The feeder 120 typically provides power to several laterals. In
Additional details are shown for the lateral 140 and the distribution transformer 146. The distribution transformer 146 transforms the medium voltage power on the lateral 140 down to the final consumer voltage—such as 120/240 VAC split phase. The distribution transformer 146 has a primary side 150 and a secondary side 160, as known in the art. The secondary side 160, which is at the final consumer voltage, typically serves several loads, e.g. consumer houses as shown at 162. On the primary side 150, a fuse or fault-interrupting switch 152 is provided proximal the connection point to the lateral 140. The switch 152 will trip open should a fault occur anywhere on the primary side 150, in the transformer 146 or on the secondary side 160. A vacuum interrupter is commonly used for the switch 152.
A vacuum interrupter (VI) is a type of switch that uses electrical contacts in a vacuum. When a fault occurs, the VI switch opens its contacts to stop the flow of fault current. The VI switch also typically recloses the contacts after a brief time period, and stays closed in order to restore power to customers if the fault has self-cleared. Power on feeders and laterals is typically provided at a voltage of 15 kVAC or more (peak to peak), and so the contacts of the VI switch are typically at a “medium voltage” potential of at least 7500 volts relative to ground.
Separation of the electrical contacts in a VI switch under a load or fault current results in a metal vapor arc, which is quickly extinguished. Vacuum interrupter switches are more compact compared with switchgear using air or oil as the arc-suppression medium. External to the vacuum volume, VI switches require an actuator to drive one of the contacts into either the open or closed position.
VI switches are used in both overhead powerline installations and in underground and ground-level installations. A common design for a VI switch uses a linear electromagnetic actuator to drive one of the contacts into the open or closed position. Other types of actuators may also be used. VI switches may be required to have an external lever or handle, mechanically connected to the actuator, that can be pulled or turned by a line worker in order to manually disconnect the switch. To reduce risk to the line worker, the external lever is grounded. Because the switch contacts are energized at the medium voltage of the lateral (typically several thousand volts AC or more), a robust means of isolation must be provided between the switch contacts and the external lever.
Some prior art VI switches have used an insulating rod in a translating configuration between the switch contacts and the actuator to provide isolation of the actuator and the external lever from the medium voltage components of the switch. Other known VI switches have the actuator at medium voltage along with the contacts and use a translating insulating rod between the actuator and the external lever. However, in either configuration, this sort of translating insulating rod adds length to the overall VI switch assembly, which is undesirable in certain applications such as underground or ground-level (pad-mounted) applications. Other prior art VI switches have used insulating gases or fluids in a portion of a housing located between the actuator and the external lever. However, these insulating gases and fluids are expensive, and containing them within the housing without leaks is difficult.
The present disclosure describes a rotary diaphragm designed for providing isolation between medium voltage components and a grounded external lever in a VI switch assembly. The rotary diaphragm overcomes the disadvantages of the previously employed isolation mechanisms discussed above.
A housing 210 serves as an enclosure for all VI switch parts except for a lever that is operable by a line worker, discussed below. The housing 210 is made of a material such as a cycloaliphatic epoxy resin that is easily cast or molded into the desired shape and has good electrical insulation properties. The outer surface of the housing 210 of the switch assembly 200 is coated with a conductive material and is grounded. VI switch contacts 220 and 222 perform the actual electrical switch opening and closing functions. The contacts 220 and 222 are maintained in a vacuum volume to improve arc-suppression performance, as is known in the art. The contact 220 is a fixed contact and is electrically coupled to an input line from the lateral at medium voltage. The contact 222 is a moving contact and is electrically coupled to an output line that typically leads to a distribution transformer, as described with respect to
The moving contact 222 is mechanically coupled to a stem 230, which is mechanically coupled to a driving rod 232, which in turn is mechanically coupled to an actuator 240. The actuator 240 may be a linear electromagnetic type actuator, or some other type or design of actuator. The purpose of the actuator 240 is to open and reclose the contacts 220/222 of the switch upon command by a controller (not shown) in the VI switch assembly 200. That is, when the controller detects a fault current, the controller commands the actuator 240 to open the switch by pulling the contact 222 downward. When the controller wants to attempt a reclosing, the controller commands the actuator 240 to reclose the switch by pushing the contact 222 upward.
The actuator 240 has an upper coupling 242 that is driven downward to open the switch and driven back upward to reclose the switch. The driving rod 232 is mechanically coupled to the upper coupling 242, such as via a threaded connection. Other components of the actuator 240—including electromagnetic components, springs, etc. —are not discussed here as they are not important to the design of the presently disclosed rotary diaphragm.
The actuator 240 also has a lower coupling 244 that moves up and down when the actuator 240 is actuated. The lower coupling 244 allows for a mechanical connection to an external lever which can be used by a line worker to manually open the contacts in the switch assembly 200. In prior art VI switch designs, the lower coupling 244 is connected to a translational rod, which is in turn connected to the external lever. However, the vertically-oriented translational rod increases the height of the VI switch, which is undesirable for underground or pad-mounted applications.
The VI switch assembly 200 of the present disclosure is designed to overcome the disadvantages of prior art VI switches. The VI switch assembly 200 includes a rotating insulating rod 250 mechanically coupled to the lower coupling 244 of the actuator 240 by a link 260. A lever 270 external to the housing 210 is attached to the insulating rod 250. When a line worker rotates the lever 270, the link 260 pulls down the lower coupling 244, which pulls down the movable contact 222 and opens the switch. The combination of rotary motion and a short insulating rod length, which is made possible by an insulating rotary diaphragm, provide for a size and shape of the VI switch assembly 200 which is more compact than previously available designs. Details of these components are discussed below.
The voltage isolation characteristics of the VI switch assembly 200 are as follows. The contacts 220/222 are at medium voltage (several thousand volts above ground potential), and there is no insulating component between the contact 222 and the actuator 240; thus, the actuator 240 is also at medium voltage. The link 260, mechanically coupled to the lower coupling 244 of the actuator 240, is therefore also at medium voltage. The insulating rod 250, made of a material such as fiberglass with very low electrical conductivity, provides isolation between the link 260 at medium voltage and the lever 270 which is grounded. An insulating rotary diaphragm 300, discussed in detail below, provides isolation of any airborne or spatial path between the medium voltage components (the actuator 240 and the link 260) and the lever 270 and a plate 280 which are grounded.
The insulating rod 250 includes a disc-shaped flange 252 in a vertical plane underneath the actuator 240. The flange 252 has a pin 254 attached at a radius from the centerline of the rod 250 and generally in a horizontally eccentric position from the centerline of the rod 250. The pin 254 moves within a slot 262 in a lower end of the link 260. At the upper end of the link 260, a through-pin 264 is pivotally coupled to the lower coupling 244 of the actuator 240.
The alignment of the centerline of the insulating rod 250 is maintained by a centering feature 212 in the housing 210 and by a through-hole in the plate 280. One end of the rod 250 pivots in the centering feature 212, and at the other end, the rod 250 passes through O-rings 282 fitted in grooves in the through-hole in the plate 280. The plate 280 seals the opening in the housing 210, as is apparent particularly in
Another design feature which ensures that the handle 270 remains positively grounded is to construct the rod 250 with a metal end 256 proximal the handle 270. That is, the portion of the rod 250 which is internal to the housing 210 (from the centering feature 212 to and through the diaphragm 300) is comprised of an insulating material such as fiberglass, while the metal end 256 (the portion of the rod 250 external to the housing 210, including the part that passes through the plate 280) is comprised of a conductive material such as a metal. The metal end 256 is rigidly joined or coupled to the insulating portion of the rod 250 in any suitable fashion—including mating mechanical features of the two components which fit together cooperatively, pins or other fasteners inserted into both components, adhesive, or a combination thereof. When the handle 270 is rotated, the entire rod 250—including the metal end 256—rotates with the handle 270.
The metal end 256 provides a conductive path from the handle 270 to the plate 280 and thereby to ground. The metal end 256 is rigidly connected to the handle 270 in a manner that also provides a reliable conductive path—such as two or more machine screws driven through holes in the handle 270 into threaded holes in the metal end 256. The metal end 256 has a reliable conductive path to the plate 280 which is preferably provided in two ways. First, at least one of the two O-rings 282, and preferably the one towards the inner volume of the housing 210, is a conductive O-ring made in silicone rubber, EPDM rubber, or other suitable elastomer that can be formulated for electrical conductivity. Alternately, the inner O-ring 282 can be replaced with a metallic coil spring made in stainless steel with or without plating (such as chrome, nickel, or silver). In addition, the clearance between the metal end 256 and the inside of the hole in the plate 280 is very small, and can be sized so that any voltage at or above 50V jumps this gap, providing another conductive path from the metal end 256 to the plate 280.
The plate 280 is itself made of metal and is firmly in contact with the housing 210 as seen in
The arrangement of the metal end 256, discussed above, ensures that the handle 270 is positively grounded via a conductive path to the plate 280 and in turn to the conductive exterior of the housing 210 and to ground. This provides a reliable grounding of the handle 270 and fail-safe protection for line workers, even in the event that a conductive path is somehow created through the fiberglass portion of the insulating rod 250 to the actuator 240.
The insulating rotary diaphragm 300 fits in an opening cavity in the housing 210, at the right of
As mentioned earlier, the lever 270 is provided to allow a line worker to manually open the contacts 220/222 in the VI switch assembly 200. However, in normal fault isolation and service restoration operations, the VI switch assembly 200 is designed to open and reclose the contacts 220/222 by way of the actuator 240. The VI switch assembly 200 is designed so that, when the actuator 240 opens and recloses the contacts 220/222, the lever 270 and the insulating rod 250 do not rotate. This is made possible by the slot 262 in the link 260. That is, the link 260 translates down when the actuator 240 opens the contact 222, and the link 260 translates back up when the actuator 240 recloses the contact 222, but these motions of the link 260 simply cause the slot 262 to move along the pin 254, without moving the pin 254 or rotating the flange 252.
On the other hand, when the line worker wants to manually open the contacts 220/222 in the VI switch assembly 200, the worker turns the lever 270 (counter-clockwise in
The VI switch assembly 200 of
The outer surface of the housing 210 of the switch assembly 200 is coated with a conductive material and is grounded, as mentioned earlier. The lever 270 and the plate 280 (along with the metal end 256 of the rod 250) are also at ground potential, as discussed above. Openings 214 and 216 (opposite side—not visible) near the top of the housing 210 allow for feed of input and output electrical cables into the housing 210. Passages inside the housing 210 enable the input cable to be electrically coupled to the fixed contact 220, and the output cable to be electrically coupled to the moving contact 222. Sealing devices are used around the input and output cables and the openings 214 and 216, so that the VI switch assembly 200 is weatherproof.
The cutaway portion at the lower right of
The diaphragm 300 is a one-piece part molded from a compliant material having good electrical insulation properties (such as a resistivity of 1010 ohm-meters or greater, although certain applications may be employ lower levels of resistivity). Candidate materials include silicone rubber, Ethylene Propylene Rubber (EPR) and Ethylene Propylene Diene Monomer (EPDM). Other materials may also be suitable.
The diaphragm 300 has a centerline 302 and a central hub 310. The central hub 310 is generally cylindrical about the centerline 302, and has a hub wall thickness 312 and an inner diameter 314. The inner diameter 314 matches the diameter of the insulating rod 250, and the inner diameter 314 of the diaphragm 300 is glued or bonded to the insulating rod 250 as discussed earlier.
The diaphragm 300 has an outer wall 320. The outer wall 320 is also generally cylindrical and has an outer wall thickness 322 and an outer diameter 324. In the preferred embodiment, the outer wall 320 has a taper angle 326, such that the outer diameter 324 exists at one end of the diaphragm 300 (the end which is proximal the plate 280 when installed in the housing 210), and an outer diameter at the other end of the diaphragm 300 is slightly smaller. The outer wall thickness 322 may also taper from one end of the diaphragm 300 to the other. The taper angle 326 allows for a positive placement and fit of the diaphragm 300 into the opening cavity of the housing 210. The outer surface of the diaphragm 300 is glued or bonded to the inner wall of the opening cavity of the housing 210, as discussed earlier.
Connecting the central hub 310 to the outer wall 320 is a web 330. The web 330 has a web thickness 332, and a web orientation angle 334 relative to a normal to the centerline 302. In the preferred design embodiment, the web 330 is axisymmetric—meaning that the web 330 does not have any helical pitch (like a screw thread). That is, any radial cross-section of the diaphragm 300 will appear the same, regardless of what circumferential location it is taken. Various filets and radii are applied to the intersections of the web 330 with the central hub 310 and the outer wall 320, resulting in localized thicknesses greater than the nominal value of the web thickness 332.
The design of the diaphragm 300 shown in
A diaphragm 620 in
A diaphragm 630 in
A diaphragm 640 in
A diaphragm 650 in
As can be seen in
The diaphragm 700 includes a lip 740 which extends circumferentially around the periphery of the outer wall 720 at the larger diameter end of the diaphragm 700. When installed in the housing 210, a face 742 of the lip 740 presses against an end face of the opening of the housing 210, while an opposing rounded surface 744 is compressed in a groove which would be provided in a face of the centering plate 280. These features of the lop 740 offer another means of securely fixing the outer diameter of the diaphragm 700 to the housing 210, while also providing additional blockage of any potential voltage leakage path from the medium voltage switch components to the plate 280.
The central hub 710 has a length 716 which extends only to the plane of the face 742, in order to facilitate the fit of the diaphragm 700 under the plate 280.
As will be understood by those skilled in the art, the controller described above in the VI switch assembly 200 performs various calculations and process steps associated with the opening and reclosing of the VI switch assembly 200. These calculations and process steps may be referring to operations performed by a computer, a processor or other electronic calculating device that manipulate and/or transform data using electrical phenomenon. Those processors and electronic devices may employ various volatile and/or non-volatile memories including non-transitory computer-readable medium with an executable program stored thereon including various code or executable instructions able to be performed by the computer or processor, where the memory and/or computer-readable medium may include all forms and types of memory and other computer-readable media.
The disclosed insulating rotary diaphragm and the corresponding insulating rod and mechanism for a vacuum interrupter (VI) electrical switch provide a significant advantage over prior designs in terms of compactness of the overall switch assembly. This compactness is particularly desirable in underground and pad-mounted VI switch applications.
The foregoing discussion discloses and describes merely exemplary embodiments of the present disclosure. One skilled in the art will readily recognize from such discussion and from the accompanying drawings and claims that various changes, modifications and variations can be made therein without departing from the spirit and scope of the disclosure as defined in the following claims.
This application claims the benefit of priority from the U.S. Provisional Application No. 63/220,287, filed on Jul. 9, 2021, the disclosure of which is hereby expressly incorporated herein by reference for all purposes.
Number | Date | Country | |
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63220287 | Jul 2021 | US |