Electrical switching mechanisms for medium to high voltage applications are designed to be highly insulated. Insulation can be accomplished by creating large air gaps or by using insulating materials, such as oil or SF6. As devices are made smaller or electrical surfaces are brought closer together, it can be extremely challenging to design and manufacture a safe and small electrical switching mechanism.
In accordance with certain embodiments, an improved switching device and related components are provided.
In accordance with one embodiment an apparatus is provided that includes a switching mechanism rated to switch 27 kilovolts, a housing to house the switching mechanism, and an isolation point of the switching mechanism visible from outside the housing to visibly exhibit a physical open-circuit by the switching mechanism.
In accordance with another embodiment, a method is provided that includes installing a switching mechanism rated to switch 27 kilovolts, and observing through a housing for the switching mechanism an isolation point of the switching mechanism, the isolation point visible from outside the housing to visibly exhibit a physical open-circuit by the switching mechanism.
In accordance with yet another embodiment, an apparatus is provided that includes at least a first insulated compartment that has an insulated base and an insulated cover. A first electrical contact for a switching mechanism is disposed on a support within the insulated compartment; and a first shed insulator is disposed along the support and adjacent the electrical contact. A second shed insulator is also disposed along the support and adjacent the electrical contact and on an opposite side of the contact from the first shed insulator.
In accordance with another embodiment, a method is provided that includes disposing a first electrical contact for a switching mechanism between a first shed insulator and a second shed insulator along a support, and disposing the support in an insulated compartment formed by an insulated base and an insulated cover.
In accordance with yet another embodiment, an apparatus is provided that includes an upper insulating shield, a top portion of an interrupter seated in the upper insulating shield, a first lower insulating shield, and a lower portion of the interrupter seated in the first lower insulating shield.
In accordance with another embodiment, a method is provided that includes seating a top portion of an interrupter in an upper insulating shield; and seating a lower portion of the interrupter in a first lower insulating shield.
In accordance with still another embodiment, an apparatus is provided that includes an interrupter comprising an integrated external terminal configured for serving as a terminal in a switching mechanism.
And, in yet another embodiment, a method is provided that includes integrating an external terminal as part of an interrupter wherein the external terminal is configured to serve as a contact in a switching mechanism.
In accordance with still another embodiment, an apparatus is provided that includes a first support structure; an interrupter having an external terminal mechanically coupled with the first support structure; and an interrupter support mechanically coupled with a movable contact of the interrupter.
In accordance with another embodiment, a method is provided that includes mechanically coupling an external terminal of an interrupter with a first support structure, and mechanically coupling a movable contact of the interrupter with an interrupter support.
In accordance with one embodiment, an apparatus is provided that includes an insulator having a recess, and a spring for an interrupter disposed within the recess.
In accordance with still another embodiment, a method is provided that includes disposing a spring for an interrupter within a recess of an insulator.
Further embodiments will be apparent from this written description and the accompanying figures.
Utilities are faced with the fact that much of their distribution switchgear equipment dates back well into the early 1900's and, in far too many cases, exceeds the intended lifespan of the equipment. Along with dated equipment and the significant dangers associated with it, various new regulatory requirements and utility safety policy changes have gone into effect, and utilities find themselves searching for replacement switchgear that must solve a myriad of problems.
Electric utilities want to replace their outdated equipment, especially outdated switches on underground networks, so as to avoid potential failures, explosions, and the financial liability associated with such events. However, the utilities face significant challenges in making such changes. For example, utilities would prefer not to use switches that contain harmful materials. To date, however, the utilities have not had the option of a switch that can fit into a confined underground vault and that does not use such harmful materials. One example of a harmful insulating material is insulating oil, which is highly flammable. Another example of a harmful insulating material is SF6 gas, which is the number one greenhouse gas and is currently being regulated by the EPA. SF6 gas also produces a dangerous S2F10 by-product during normal operation and that by-product can be released during a failure of a switch.
Another challenge that has faced utility companies is safely performing maintenance operations on equipment—especially equipment that operates at medium voltage or greater. Switchgear needs to be maintained or reconfigured periodically. Thus, utility operating crews need to be assured that the circuit components they want to work on are de-energized. For switchgear located in a housing, confirming de-energization can be difficult. Therefore, utility operating crews will often (1) operate an upstream switch to disengage electrical service to a piece of switchgear that they want to work on, and then (2) remove the electrical cables to that piece of switchgear. In this way, utility operating crews can visually ensure that a piece of equipment is safe to work on. Since the upstream switch generally controls other pieces of equipment, as well, a simple maintenance procedure can lead to a major disruption, power outage, and inconvenience. Also, it should be appreciated that the time it takes to disconnect a medium voltage cable from a piece of equipment, for example, is not a trivial task. Time and effort are expended to both disconnect and reconnect such cables.
In accordance with certain embodiments, certain ones of these issues are addressed by the present technology described herein. For example, one embodiment does not contain any oil or SF6 gas as an interrupting or insulating medium. That embodiment is compact, small, modular in design, and is configurable into multiple switchgear designs thereby allowing the equipment to fit into existing manhole and vault locations. A visible open isolation point is visible through a clear cover and through tank-mounted viewing windows, providing the utility operating crews with a “visible” way to determine that a circuit is indeed “Open,” isolated, and safe to perform their work without having to remove heavy electrical cables attached to the device.
In accordance with another embodiment, a multi-phase solid dielectric and air insulated interrupter with integral visible open isolation point assembly can be utilized. The interrupter and secondary isolation switch can be rated to withstand full system voltage. Moreover, the secondary isolation switch can allow an operator to visibly see three sets of “open” electrical contacts through clear window(s) of the switch tank and through a clear cover of the visible open isolation point assembly. In addition, multiple configurations and positions within a housing, such as a welded enclosure, may be utilized. It is believed that to date, no other solid dielectric switching mechanisms provide a visible isolation point that is rated to withstand full system voltage.
It should be appreciated that embodiments of the present technology are disclosed herein in the context of a switching mechanism. A “switching mechanism” is a device that can interrupt and/or energize an electrical circuit. For example, such a device can include a fault current interrupter, a load current interrupter, a switch, or a circuit breaker.
In accordance with another embodiment, a switching device is provided that has three operating positions (Open, Closed and Tripped Open). Due to the large voltages, ranging from, for example, 5,000 volts to 35,000 volts, and large currents, for example, up to 25,000 amps, that this device operates at under normal conditions, it is much more complex than a household circuit breaker operating at 120 volts. This embodiment can utilize an interrupter, such as a vacuum interrupter, as the primary interruption device to interrupt the flow of current in a circuit. Moreover, this device can utilize a combination of solid dielectric insulating materials, as well as air, to insulate the energized parts from one another within the switchgear, thus eliminating the need for oil or SF6 gas as insulating mediums.
Unlike examples in your home, it is very difficult to separate high voltage cables from the switchgear. At home, one can simply unplug the vacuum cleaner, for example, from the electrical outlet before changing the dust bag or belt. Unplugging the vacuum cleaner from the wall outlet is creating a “visible, open circuit”—somebody can visually confirm that the circuit is open. With the cable removed from the electrical outlet, there is no way that the vacuum cleaner can become energized while you are working on it. Thus, when the cord is removed from the outlet, one has created a “safe to work” visible, isolation point from the electricity in the wall outlet.
A “visible and safe to work” system or process is utilized by utility operating crews working on medium voltage equipment. The utility operating crews determine by some means that a circuit is de-energized and “open.” Historically, an operating crew would remove the cables from the oil-filled or SF6 gas-filled switchgear to ensure that the switchgear was de-energized and thus safe to work on. In accordance with one embodiment, a “visible open circuit” can now be provided as part of a switching mechanism.
Certain embodiments described herein can be accomplished without the use of oil or SF6 gas inside the switchgear, thus such embodiments are believed to be the safest switchgear for utility crews, the public, and the environment, on the market today.
Referring now to
The embodiment of
In one embodiment, a hermetically sealed container can be used as the housing. Use of an enclosed housing helps to reduce build up of dirt, debris, and/or water in the switching mechanism.
In another embodiment, the external container can be shaped with a substantially circular circumference so as to fit through a standard manhole. Moreover, a multi-switch unit can be configured within the same tank. For example, three operating handles can be attached to three handle housings. One handle can be associated with each interrupter assembly mounted inside the switch tank. Nine bushings or external electrical connections could also be welded into the tank lid. The three interrupters with integral visible open isolation point devices could also be sealed into a welded stainless steel switch tank.
The combination of a handle with the “open” and “closed” positions as well as windows in a tank that allows the operator to visually confirm an open circuit provides a safety enhancement. For example, when a handle is down and parallel with the lid of the switch tank and the associated semaphore reads “Closed,” the operator has the initial impression that the circuit is closed. However, the operator can look through viewing windows on the surface of the tank to confirm that the visible open isolation point is indeed “Closed.” Similarly, when the handle is up and away from the tank surface, and the semaphore reads “Open,” the operator has the initial impression that the circuit is open. However, the operator can look through the viewing windows on the surface of the tank to confirm that the visible open isolation point is open for each phase.
When an operating handle is down and parallel to the tank lid, but the associated semaphore reads “Open”—despite the fact that the handle is in the down position—the operator knows that the interrupter is in the “Tripped Open” position. To re-set the interrupter and to position the Visible Open Isolation Point device in the “Open” position, the operator can simply pull the operating handle up. The visible open isolation point device would then be seen in the “Open” position through the viewing windows.
Referring to
In the example of
Each interrupter's lower external movable contact includes a threaded bolt that is used to connect to the associated electrical bus work and lower drive mechanism, such as the associated push-pull rod assembly. Supporting the interrupters are twelve insulating rods 311, such as G-10 FR4 insulating rods. The G-10 FR4 material is a thermo-laminated glass polyester material. It exhibits superior dielectric strength, mechanical strength, stability in high temperature environments, and very high resistance to absorbing moisture. These twelve rods (six rods are shown and another six rods are positioned in symmetrical locations on the opposing side) insulate the upper and lower external interrupter contacts from a Basic Insulating Level (BIL) of 125,000 volts of electricity. The G-10 FR4 rods support the upper base structure as well as the contact bottom guides 310. Moreover, the G-10 FR4 rods couple together the upper base structure, the contact bottom guides, and the lower supporting structure 314.
In
In
The upper electrical terminals 318 allow one to connect the switch via insulated cables to electrical bushings mounted on the lid of a switch tank, for example. The rotatable drive shaft 319 is connected to an actuator, such as a pull handle and operating linkage 319. The operating linkage opens and closes the interrupters as well as the phase switches disposed on the rotatable drive shaft. Each phase-switch can serve as a visible open isolation point because it can be viewed from outside the switchgear. The term phase-switch is used to identify an individual switch that is in series with an interrupter. It can apply to a circuit having a single phase or to a circuit having multiple phases. In
The linkage can be set so that when an operating handle—located, for example, on the outer surface of a switch tank—is pulled to the “open” position, the interrupter contacts for each phase of a circuit open completely before the linkage for the visible open isolation point is engaged to rotate the visible open isolation point shaft to the “Open” position. A position semaphore may also be used and located on the external handle housing to clearly identify the mechanism's position: Open (green indicator) and Closed (red indicator).
An example 400 of a lower drive assembly is depicted in
The design can include specific features to address the issues of voltage “creep” along the surface of the structure as well as “jump distances.” Voltage “creep” refers to the fact that voltage and current travel along and on surfaces. For this reason, the drive shaft of the visible open isolation point device can utilize shed insulators 522. Sheds 522 are insulators affixed or molded to the drive shaft in such a way as to increase the surface distance between energized parts and thus to increase the distance that an arc must travel along the drive shaft, thereby increasing the distance between energized parts without increasing the length of the shaft. For example, such sheds can be made from epoxy resin.
Voltage “jump distances” refer to the ability of the voltage potential to build up on surfaces and create an arc jumping through air to another electrical contact associated with another phase or to ground. The design of the cover 515 and base 508 can include insulating barriers 520 formed into the molds of the cover 515 and base 508. These insulation barriers divide the cavity formed between the base and cover into three compartments. Moreover, these insulation barriers operate to block arcing from one phase to another because the phase-switches for each phase are located in separate compartments. Polycarbonate can be used for the barriers.
Contacts 605 and 606 are located on rotatable shaft 616. As the shaft is rotated in the direction of arrow 699 parallel contacts 605 engage with stab contacts 627, while parallel contacts 606 (disposed under respective insulated covers) engage with stab contacts 604.
In accordance with one embodiment, a design can be implemented that is compact and small. Compact and small embodiments are useful in that they can be installed into pre-existing, relatively small manholes and vaults. One of the challenges to making electrical distribution equipment small is that medium and high voltage equipment require significant levels of electrical insulation. Some have relied upon insulating oil or SF6 gas to provide insulation. However, such materials are dangerous, for a variety of reasons.
In accordance with one embodiment, unique insulating materials are utilized to provide sufficient electrical insulation without utilizing insulating oil or dangerous gases, such as SF6. Materials that can be used to provide insulation include, for example, Bisphenol epoxy resins, NEMA G-10 FR4 epoxy-glass rods, room temperature vulcanizing (RTV) adhesive, Polyolefin heat shrink tubing, molded silicone sheds, non-conductive plastic bushings, fiberglass polyester NEMA GPO-3 sheet and channel insulating material, non-metallic fasteners, and a molded polycarbonate insulating cover. The result of combining these various materials in the design of a unit is that one can achieve the same electrical clearances of oil or SF6-gas filled equipment without the need for oil or SF6 gas for insulation. “Electrical clearances” are electrical measurements of pre-determined distances or levels of insulation capable of insulating or creating distance between energized components for the voltage the equipment will be subjected to.
In accordance with one embodiment, a switching mechanism is configured to be rated to be installed on electrical circuits energized up to 27,000 volts and with electrical clearances and Basic Insulation Levels (BIL) to meet or exceed 125,000 volts for 27,000 volt applications. This embodiment is also compact and easy to modify for a plug-and-play replacement design for older equipment dating back to the early 1900's.
The lower portion of the interrupter 892 is similarly mounted into a lower insulating shield, such as an interrupter contact bottom guide 893, to electrically insulate the interrupter. The interrupter contact bottom guide 893 can be a molded component that includes an additional insulating shield to insulate the interrupter contact. The insulating shield 894 can also be made of epoxy resin. A cowling 805 extends at least partially around the circumference of the insulator and serves as an electrical insulating shield for the lowest electrical connection point 896 between interrupter 892 and push/pull rod drive assembly 899. The push/pull rod drive assembly includes insulated sheds to provide further insulation for the connection point 896. Thus, in addition to the interrupter contact bottom guide 893 which serves as a first lower insulating shield for the interrupter, the insulating shield 894 and cowling 805 can serve as second and third lower insulating shields for an interrupter. RTV sealant adhesive is used to install, insulate, and seal the top and bottom edges of the interrupter 892 into upper insulating shield 891 of the upper base 890 and insulating shield 894.
To provide support for the structure, NEMA G-10 FR4 epoxy-glass insulating rods 895 can be used. For example, such rods can be used between the upper insulating shield and the lower insulating shield as insulating support members for the base/cover/rotatable switch structure. Such rods provide physical strength to support the base and hold the device together. Such rods also can maintain 27,000 volts of system voltage and Basic insulating level (BIL) rating of 125,000 volts for the entire device.
The lower portion of the mechanism is also supported by NEMA G-10 FR4 epoxy-glass insulating rods 898. Such rods provide support and maintain 27,000 volts of system voltage and Basic Insulating Level (BIL) rating of 125,000 volts from the lower interrupter contact 897 to the fiberglass polyester NEMA GPO-3 802 insulating barrier covering the steel frame 803. Machined in the insulating barrier are holes for push/pull rod drive assembly shafts 801 to connect to a lower drive mechanism. These holes can be insulated with non-conductive plastic guide bushings.
One embodiment can use and combine engineered components (including molded epoxy resin components, and custom electrical contacts), multiple insulating materials and air to provide a very compact and small assembly that can fit into (for example, as replacement switchgear) a pre-existing manhole or vault, all the while maintaining electrical clearances for successful operation and rating, without the need for oil or SF6 gas as an electrical insulation. Oil has been used in switchgear since the early 1900's for both insulating and arc-quenching applications. In the 1960's, SF6 gas was introduced into switchgear as a new form of dielectric insulation to potentially replace oil. The possibility of explosion and release of deadly by-products from normal operation make oil- and SF6-filled switchgear extremely dangerous to operating crews and to the public.
Current non-oil and non-SF6 switchgear use a process of encapsulating the interrupter in rubber or cycloaliphatic material, calling it a solid dielectric device. These designs do not include a visible open device or a safe to work isolation point that can withstand full system voltage and they rely on the rubber and cycloaliphatic materials to protect the device from the environment in the vault or manhole. At least one embodiment described herein provides a stainless steel switch tank housing to protect the interrupter with integral visible open isolation point from the underground vault environment. Placing such a device inside a sealed vessel permits the use of air as insulation for the integral visible open isolation point.
In
Notably, others have had to use an injection molding process to produce encapsulated components from expensive molds to reach an appropriate level of insulation. In accordance with at least one embodiment described herein, no such molding is necessary to achieve the appropriate level of insulation. Thus, no costly molds or capital equipment are required. The manufacturing process can be performed in-house where quality can be closely monitored. Expensive interrupters are not damaged or thrown away because of molding process errors that create voids in the solid dielectric material, thus making the encapsulated parts unusable. No voids are created during the insulation and assembly of interrupters. Moreover, the process and assembly is easily repeatable with little to no scrap created.
One design feature that allows a more compact design is the use of interrupters that remain along the same longitudinal axis during both an opening and closing of a switching mechanism. Such a design allows the workspace in front of the interrupters to remain constant regardless of whether the interrupters are in an “open” or “closed” position. Thus, the housing for the switching mechanism does not have to be sized for electrical clearance purposes to accommodate the worst case position for the interrupters. In this way, the volume of space needed by a housing to house a switching mechanism—or operational volume—can be substantially the same for a switching mechanism in both an open-circuit position and a closed-circuit position.
Similarly, the compact design techniques described herein allow the operational clearances for a switching mechanism to be substantially the same when the switching mechanism is in either an open-circuit position or a closed-circuit position.
By utilizing the volume saving techniques described herein, a compact switching mechanism can be implemented without the need for dangerous or harmful insulating materials. This allows switching mechanisms to be disposed, for example, in underground vaults, through manholes, and to retrofit 1900's era switches. Such retrofits can save time and expense for electrical service providers. Moreover, the design allows utility operating crews to safely determine that a switching mechanism has been deenergized before having to work on the equipment and without having to disconnect cables from the switchgear housing before performing a service operation.
Depicted in
Due to the nature of interrupter technology, interrupter contacts, when in the closed position, are held together under constant pressure to keep the contacts closed. Each of the two contacts 910 and 911 within the interrupter is under magnetic forces. The two forces are in opposition to one another and work to push the interrupter contacts apart. These forces increase under fault (or short circuit) conditions. Correct and constant pressure should be applied to the interrupter contacts over the lifetime of the switchgear, when in a closed position.
If the correct and constant pressure is not present, two issues can arise: (1) a highly resistive connection between the contact surfaces will cause a “heat rise,” causing premature interrupter failure; (2) as interrupter contacts are operated, e.g., repeatedly opened and closed, the contact surfaces erode thereby reducing the amount of material at the contact surface. In accordance with at least one embodiment, a self-calibrating spring pressure device to hold the contacts together under both fault and normal conditions solves some or all of these problems.
Next, a shoulder bolt assembly is installed. The shoulder bolt assembly is made up of two machined components and a shoulder bolt 917. A first machined component 915 having a flat machined surface to press against the die spring and a partially threaded interior hole on the opposite end. A shoulder bolt 917 is installed through this machined part at the threaded end. Next, a second machined component 914 with both internal and external threads is installed in the first machine part to captivate the shoulder bolt. A gap is left inside of the first machined component to allow the shoulder bolt to move up and down inside the first machined component. The gap area is created to allow the compression spring to expand to keep the correct and constant pressure on the interrupter contacts as they erode with operation. The second machined component 914 includes a threaded center hole to which a threaded end 912 of the movable contact 910 is installed to connect the push/pull rod drive assembly to the interrupter.
An exploded view of an example 1000 of a self-calibrating assembly is shown in
The upper portion of interrupter 1044 is seated in the base 1048 and protected by the upper contact guide molded into the base. The lower portion of interrupter 1044 is seated into lower contact guide 1036. The base 1048 and lower contact guide 1036 are also insulated by support rod(s) 1040. The lower contact of the interrupter extends through the opening in lower contact guide and screws into a hole in the top of bushing cap 1028.
Referring again to
A contact bottom guide can also serve as an interrupter support structure. Each interrupter's lower external movable contact includes a threaded bolt that is used to connect to the associated electrical bus work and a drive mechanism, such as the associated push-pull rod drive assembly.
Still further, the frame 903, such as a stainless steel frame, can provide another point of support. The push/pull rod can be coupled at one end to the frame 903 and coupled at its other end to the interrupter support structure. Since the push/pull rod is coupled to the movable contact, these points of support help maintain the axial alignment of both the push/pull rod and the movable contact.
In one embodiment the container can be evacuated so that the interrupter serves as a vacuum interrupter. In
Referring again to
The interrupter contacts, located inside the interrupter, cannot be seen—they are merely being illustrated by the transparent depiction in
In accordance with one embodiment, an actuator can be utilized that allows operation of a switching mechanism. Such an actuator can include a single handle coupled with a linkage that activates two separate drive mechanisms. For example,
In
Embodiments can also be described as methods. For example,
Once a piece of switchgear is installed, it can be operated and serviced from time to time. For example, it can be disconnected from service and worked on. To work on the switchgear, an operator, such as utility personnel, confirms the switchgear is de-energized before approaching or contacting components. The embodiment in
In operation 1510, an operator uses an actuator to actuate the switching mechanism. The switching mechanism is actuated so as to open the interrupters prior to opening the phase-switches. The linkage of the actuator can be adjusted to provide a pre-determined time delay between actuating the opening of the interrupters and the phase-switches. Such a time delay allows the interrupters to break the electrical circuit. This is shown in operation 1512.
Various contact arrangements can be utilized for the phase-switches. In the embodiment of
Once the handle has been moved to an “OPEN” position, the operator can observe through a housing for the switching mechanism an isolation point of the switching mechanism. The isolation point is visible from outside the housing and visibly exhibits a physical open-circuit via the switching mechanism. This is illustrated by operation 1520.
When an operator is ready to close a switching mechanism, the operator can actuate the switching mechanism so as to close the phase-switches before closing the interrupters, as shown in operation 1522. Closing the phase-switches before closing the interrupters avoids the phase switches from experiencing any arcing at phase-switch contacts during energization. As shown by operation 1524, a single movement of a handle can be used to close the phase-switches and the interrupters. Also, multi-blade contacts of the phase-switches can be engaged with stab contacts of the phase-switches to close the phase-switch circuits in this embodiment.
It should be appreciated that in accordance with this embodiment the interrupters can be operated along a fixed longitudinal axis. Thus, the interrupter body does not move in order to open or close contacts. Rather, the interrupter body is positioned along the fixed longitudinal axis when the interrupter is in an open-circuit position and a closed-circuit position.
Referring now to
In
In operation 1708, a lower portion of the interrupter is seated in a first lower insulating shield. Again, the lower insulating shield can include one or more sidewalls that extend partially down the side of the interrupter, when seated, and substantially or completely around the interrupter so as to cup the lower portion of the interrupter. Such insulation helps to shield the second terminal of the interrupter from electrical faults. The interrupter can also be sealed to the lower insulating shield with a sealant.
A cowling shield can be disposed in proximity to the second terminal of the interrupter in operation 1710. The cowling shield can extend partially or completely around the circumference of an electrical connection between the lower (or second) terminal of the interrupter and the push/pull rod assembly for the interrupter. The push/pull rod assembly can be used to close/open the contacts of an interrupter.
The surface of an interrupter can also be covered with insulation. For example, a substantial portion of the interrupter can be covered with insulation. Through the use of different insulating techniques, the non-terminal portions of an interrupter can essentially be encapsulated. For example, an interrupter can essentially be encapsulated by the upper insulating shield, the lower insulating shield, and a layer of insulation disposed on the container for the interrupter, as illustrated by operation 1712. Operation 1714 illustrates that one might alternatively insulate a majority of the outer surface area of the non-terminal portions of an interrupter.
Additional insulating materials can be utilized with the structural support components. For example, operation 1716 illustrates that the base structure can be supported with at least one insulating support member.
It should also be appreciated that the push/pull rod assembly can be insulated by an insulated shed that is placed proximate the lower portion of the interrupter, as shown by operation 1718.
Referring now to
In
In operation 1908, a first end of a push/pull rod can be mechanically coupled with a second support structure, such as the stainless steel base for a piece of switchgear. Operation 1910 shows that a second end of the push/pull rod can be mechanically coupled with the movable contact of the interrupter. Finally, operation 1914 shows that axial alignment of the non-movable contact and the movable contact can be maintained via such mechanical couplings, e.g., the mechanical coupling with the first support structure, the mechanical coupling with the interrupter support, and the mechanical coupling with the second support structure.
Additional views of some examples of the structural pieces discussed herein are shown in the figures to provide further illustration.
In some of the examples described herein a three-phase switching mechanism has been used as the example. It should be appreciated that the technology described herein can apply to not only multi-phase devices, but also, single-phase devices.
It some of the examples described herein a switching mechanism that utilizes a visual open isolation point is used as the example. It should be appreciated that a visual open isolation point is not required by all embodiments. In some instances, disclosed features could be implemented on devices that do not utilize visual open isolation points.
In some of the examples described herein an interrupter having an integral terminal configured for serving as part of a switch terminal, such as a stab terminal, is described. It should be appreciated that such a terminal is not required by all embodiments.
The above specification, examples, and data provide a complete description of the structure and use of exemplary embodiments. Feature(s) of the different embodiment(s) may be combined in yet another embodiment without departing from the recited claims.
The present application claims benefit of priority under 35 U.S.C. § 119 to U.S. Provisional Patent Application No. 61/793,880, entitled “Electrical Switching Device” and filed on Mar. 15, 2013, which is specifically incorporated by reference herein in its entirety for all that it discloses or teaches and for all purposes. The present application is also related to U.S. Nonprovisional patent application Ser. No. 14/218,587 entitled “Insulated Switch”; U.S. Nonprovisional patent application Ser. No. 14/218,645 entitled “Insulated Interrupter”; U.S. Nonprovisional patent application Ser. No. 14/218,715 entitled “Interrupter Spring Guide Assembly”; and U.S. Nonprovisional patent application Ser. No. 14/218,756 entitled “Interrupter Having Integral External Contact”, all of which are filed concurrently herewith, and all of which are specifically incorporated by reference herein in their entirety for all that they disclose or teach and for all purposes.
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