1. Field of the Invention
The invention relates generally to electrical power switchgear with motor operators and, more particularly, to motor operators for power switches with a drive system that facilitates switch operation by force other than from the motor of the operator, such as manually applied force, even for switches at overhead (or pole-top) locations.
2. Background Art
Motor operators are widely used in combination with power switches. A variety of operators are in use with various features to permit a switch operation to be performed manually. These have included operators with features for mechanically decoupling the operator's drive system from the motor. Decoupling has taken a number of different forms.
Power switches are applied at a variety of locations including some at surface, or ground level, locations relatively easily accessed for manual decoupling and switch operation and some at overhead (or pole-top) locations less easily accessed.
For example, some overhead switches have a motor operator at or near ground level with a mechanical (reciprocating or torsional) link to a switch drive at the overhead location that may be forty or fifty feet higher. Such an operator is, for example, described in Cleaveland/Price Inc., Bulletin DB-128C01 of 2001. The motor operator is housed in an enclosure also containing other power, control and protection elements, including elements for initiating operation from a remote control station. To perform a manual switch operation with that system, a worker removes a hand tool (e.g., a hand crank) from the enclosure whose removal opens a handle interlock switch that in turn opens the motor control circuit so the motor will not operate during manual operation. A decoupler pin, or other mechanical release element, is available for manual removal so a manual switch operation can be performed using the hand tool to apply force to move the mechanical linkage to the overhead switch without requiring manual turning of the motor. When manual operations are completed, replacement of the hand tool and the decoupler pin restores the system for operation by the motor.
Such systems have been quite successful. Recently, however, some interest has developed in equipping overhead switches with motor operators at the pole-top location with only a short mechanical link to the switch. This can, for example, lessen any concerns about dimensional variance of the mechanical linkage over the long life of an installation, minimize ground equipment subject to safety or vandalism concerns, and provide an overall cleaner, uncluttered look to an installation (even though some power supply and control elements can be housed at a surface location, preferably of course well secured in a locked enclosure). While such operators may be similar to the former ground-based units in some respects, e.g., including remotely initiated power operation, if the same features for manual operation are retained there is the problem of accessing the manual elements, such as requiring a worker to climb up to the operator, or use of a lift-truck, which is expensive and troublesome.
Among other prior art of switch motor operators with some kind of decoupling for manual operation, whether or not for overhead installations, are those contained in the following U.S. patents (which are merely partially and briefly described).
Evans U.S. Pat. No. 3,980,977, Sep. 14, 1976, illustrates a system in which insertion of a specified hand tool at a particular location of a clutch mechanism in a motor operator disconnects the motor from the mechanism and allows manual rotation of a drive lever that recharges a wound spring operating mechanism.
Ramos et al. U.S. Pat. No. 5,091,616, Feb. 25, 1992, shows a pole-top motor operator and specially designed switch combination with a disconnect linkage manually operable by a hook stick or the like that moves switch-pole housings of the switch.
Sanders U.S. Pat. No. 5,856,642, Jan. 5, 1999, discloses an infinite engagement friction clutch coupled switch operator with selectable engagement and disengagement by a user to allow for manual operation.
Lo et al. U.S. Pat. No. 5,895,987, Apr. 20, 1999, and U.S. Pat. No. 6,025,657, Feb. 15, 2000, present a switchgear motor operator with a drive including a clutch with a hub and friction discs or an actuator-follower arrangement with opposing actuating and follower surfaces that is subject to an automated control means that responds to a switch operation to reverse the engaging elements to allow manual operation.
Such known art, however useful each may be and with whatever varied tradeoffs each carries with it in terms of high or low cost, convenience, complexity, and susceptibility to inoperability due to a loss of power or functionality, all has a common characteristic in that each necessitates performing an explicit decoupling process, in addition to the merely normal switch opening and closing of a motor operator, either manually or motor driven and either specifically initiated when desired or automatically by a control system.
In part, the present invention resides in a motor operator with a motor shaft coupled to an operator output, attachable to a switch, by a drive assembly that has elements with mutual engagement (coupling) temporarily during a period of force application to the output sufficient for switch operation followed, without any required manual or power intervention, by disengaging (decoupling). In this respect, the apparatus of the invention exhibits decoupling as an inherent part of its operation. It does not require a positive act to be performed, following a switch operation, to decouple manually or under power, including what some might regard as “automatic” decoupling in which a control system senses an operation and, without human intervention, drives the operator back to a decoupled state. The inherent decoupling of the invention is achieved without requiring a sensing signal to tell the operator when it may become decoupled.
Manual operation is easy to perform with the decoupled operator. The motor driven temporarily mutually engaging elements of the drive assembly do not need to meet during a manual operation.
In particular forms of the invention a wide variety of drive elements can be employed that self-disengage following motor movement sufficient for switch operation from either open to closed or from closed to open. What is generally employed, for example, includes first and second drive elements (e.g., rotating or arcuately moving plates) that carry the temporarily mutually engaged parts where one of the drive elements is continuously linked to the motor shaft and the other of the drive elements is continuously linked to the operator output. The parts with temporary mutual engagement can, for example, be selected from any of the generally known types of mechanisms for force transfer followed by disengagement including a post on one drive element moving into and through cam elements with energy storage elements such as various types of spring-loaded elements (e.g., coil springs connected with pivoting fingers or leaf springs), compressible (e.g., hydraulic) fluid containing elements, or resilient (e.g., rubber) cushion type elements or some combination of such elements. Alternatively, mechanical temporary force transfer elements such as various forms of cam elements can be used with or without one or more energy storage elements. While none of these temporary force transfer elements may be basically novel in the mechanical arts, they are not known to have been applied in combinations with motor operators for power switches in the manner described.
The inherent decoupling of the motor drive can facilitate performance of a manual operation, even with a pole-top motor operator and switch installation. A worker does not need to perform a positive act to achieve decoupling and does not need to rely on operation of a control system (that might be inoperable due to loss of power) to achieve the decoupled state. A worker can tell decoupling has occurred by, for example, status indicators at ground level or by looking at the position of an operating member (e.g., a laterally extending bar or plate), that is continuously fixed to the operator output shaft, to see if the switch is open or closed. In normal use, there is no need for a worker to be immediately at the operator. Manual operation of an overhead switch from the ground is readily performed.
The operating member is all that is required to be used for a manual operation (or an operation by any power source other than the motor of the motor operator, which could be a second, perhaps portable, motor). Typically, such as in the case of an overhead or pole-top installation, a worker applies a hookstick or the like to that operating member (e.g., a handle with one or more features such as loops or apertures to capture the hookstick) to perform a manual switch operation with the already decoupled operator.
Also, the decoupled state indicated by the operating member allows a worker to operate (e.g., for testing) the motor without operating the switch itself by locking the operating member, such as by inserting a hookstick into a locking hole in the operating member to secure the operating member to a fixed part of the housing or support structure.
The lack of complexity of the required structure enhances its reliability and convenience in use. In some forms, after the switch travels to the open or closed position (whether or not the switch itself has spring-loaded contacts), the operating member of the motor operator hits its end-of-travel stops (e.g., posts fixed to the housing or support structure) and the force (torque) transfer is greater than the maximum force that can be held by the temporarily engaged parts of the drive elements; their relative motion continues to reach the inherently decoupled state. Further, a simple limit switch at each of the open and closed positions on one of the drive elements can be triggered by the other drive element to turn off power to the motor.
In a typical installation with preferred features, a worker at ground level can interact with the motor operator system in two ways. A control switch panel at ground level can (and preferably is) first switched from “Remote” to “Local” operation (or, perhaps, a “Manual Only” switch setting to prevent any power operation (as might occur following an outage)). Then the worker uses a hookstick (or “hot stick”) to operate the lever or whatever other operating member is provided. Then “Local” operation of the motor (in the coupled or the decoupled state) can be performed as desired with controls switched to “Remote” as a further option.
While exhibiting characteristics particularly addressing the problem of difficult access described in the Background in connection with overhead switches, the apparatus of the invention also is generally applicable in combination with power switches in any location. Also, the power switches with which the operator of the invention is used may be those commonly available without requiring special switch features for getting the benefits of the invention.
These and other aspects of the present invention will be better understood from the following discussion and drawings of example embodiments.
The switch 10 may be of a known type of three-phase distribution switch. It could generally be any motor operatable switchgear, including distribution switches, transmission switches, reclosers, and the like.
In the view of
In this example, the mechanical drive assembly 42 includes, without exclusion of other possible elements, a first drive plate 44 mechanically linked to the motor shaft 40. The first drive plate 44 and the motor shaft 40 each have sprockets on which a chain 46 runs. The first drive plate 44 is an example of a first drive element that is continuously mechanically linked to, and subject to movement with, the motor shaft 40. Rotation of the first drive plate 44 occurs about, but not joined with, the operator shaft 30. One or more bearings 48 between the plate 44 and the shaft 30 allow free relative motion of the two elements.
The mechanical drive assembly 42 of this example also includes a second drive plate 50 that is affixed to and subject to rotation with the operator shaft 30 (and, consequently, the output member 26 and the operating member 28). The second drive plate 50 is, in this example, one that extends radially from the shaft 30 without completely encircling the shaft. The second drive plate 50 is an example of a second drive element that is continuously mechanically linked to, and subject to movement with, the operator shaft 30.
Mechanical linkage between the first drive plate 44 and the second drive plate 50 occurs, during operation of the motor 36, but only temporarily. That is, for switch operation, it occurs for a sufficient time, and with a sufficient force, for the switch 10 to be operated by reason of rotation of the lever 26, but then ceases. This is because the two drive plates 44 and 50 have temporarily mutually engaging parts that, in
Other elements shown in
A shaft biasing mechanism 58 (e.g., of the springloaded or weighted overcenter type) is generally illustrated on the shaft 30 near the front (left face) of the housing 22. The mechanism 58 (not detailed in the drawing) can include a member fixed on the shaft 30 that works against a spring fastened between that member and a wall of the housing 22. The arrangement is such that rotation of the shaft 30 in either direction has to overcome some spring force and loose or floppy movement of the shaft mounted elements 26 and 28 is avoided.
For convenience in assembly, the shaft may be in two colinear pieces with a fixed coupling 60.
In the example of
Also,
The elements 64 and 66 (and the unshown counterpart) result in a signal that turns off power to the motor 36 and also serve to indicate that the motor has turned the drive plate 44 clockwise or counterclockwise to the proper angular position. In addition, the operator 20 has microswitches 68 and 70 on a fixed part of the operator 20 that generate a signal when a knob 72 on the shaft 30 forces contacts of either switch 68 or 70 to close. The signals from either switch 68 or 70 indicate the open or closed rotational status of the output member 26 and, therefore, of the power switch 10. Leads for switches 68 and 70 (not shown) would also be carried by the electrical conduit 34.
Further explanation of the structure and operation of the motor operator 20 will be given in connection with
The mechanical drive assembly 42 is partly shown in
In this example operator 20, it is restriction of motion of the operating member 28 that determines the extent of the motion of the output lever 26. The handle 28 turns on the operator shaft 30 in substantially parallel relation to the fixed plates 32 and 32′ (
The decoupled motor operator 20 is now readily available for a manual operation, and the manual operation does not require any turning of the motor 36 or any engagement of parts 52 and 54 on the drive plates. In the embodiment shown, the handle 28 has portions extending beyond the plate 32. Each of these extended portions of the handle 28 has a feature, such as the open loop type features 28a and 28b, that can readily accept and retain a hookstick or the like for a manual operation. To go from a switch closed position as is taken as the example of
The geometry of the handle 28 can of course be varied from that shown. For example, it can be provided with hook retaining apertures rather than the open loops 28a and 28b. The open loops 28a and 28b contribute to worker safety. For example, if a worker has a hookstick in the handle loop 28a in the position shown in
The finger assembly 154 is but one example of a part 54 for temporary mutual engagement with a part 52, which is a fixed post in this example. The assembly 154 includes a pair of fingers or cam bars 170 and 172 that are joined at respective ends 170a and 172a to other elements and at pivot points 170b and 172b to the plate 50. Finger 170 has its end 170a coupled to a pair of coil springs 174 with fixed ends 174a attached to the plate 50. Finger 172 has its end 172a coupled to a pair of coil springs 176 with ends 176a away from the finger 172. For reasons having to do with conveniently available space, spring ends 176a are not fixed to the plate 50. Instead the ends 176a are attached to an end of a respective slider 178 which has a body that is free to slide on a securement 178a attached to the plate 50.
In
With the continuing operation of the motor 36, while the plate 50 is at a stop, the pin 52 is forced by the motor 36 through the fingers 170 and 172 by pivotal motion of the fingers about the pivot points 170b and 172b.
As soon as the pin 52 has moved far enough to release from the fingers 170 and 172, the elements 170, 172, 174, 176 and 178 all relax again into the neutral position shown in
It is to be clearly understood that the fixed post 52 on the first drive plate 44 and the finger assembly 154 on the second drive plate 50 are merely examples of parts that can mutually engage with sufficient torque transmission for switch operation and then disengage. This example is of the nature of a non-eccentric cam (the post 52) working against spring-loaded fingers (fingers 170 and 172 with related elements 174, 176 and 178). Generally such an arrangement 154 can be considered within a class of known mechanisms sometimes referred to as swinging-arm cam followers.
In other terminology sometimes used in the mechanical arts, the arrangement of pin 52 and finger assembly 154, with their respective drive plates 44 and 50, can be considered as, or similar to, a spring-loaded, positive-tooth clutch where the “teeth” represented by the pin 52 and fingers 170 and 172 make positive engagement with torque transmission and disengage after a predetermined amount of torque is encountered. In general, the parts 52 and 54 (or 154) can be located on drive plates 44 and 50 in reverse of the locations shown; that is, part 52 can be on plate 50 instead of plate 44 and part 54 (or 154) can be on plate 44 instead of plate 50.
More generally, the parts 52 and 54 can be any camming elements with or without energy storage members such as springs (e.g., coiled or leaf), compressible cylinders (e.g., hydraulic), or resilient cushion-type elements. Within the broad fields of mechanical power transmissions and mechanical linkages are a wide variety of known mechanisms that may be adapted for the purposes of a motor operator in accordance with the invention. Applicant's invention resides principally in novel combinations of such mechanisms with other motor operator elements.
From the above description, it can be understood a motor operator is provided with a drive assembly 42 including, at least in part, means for transmitting switch operating force from the motor 36 to the output member 26 that results in a decoupled state of the motor and the output member, even absent any reversal of the motor (e.g., either automatically by an electrical controls system or manually initiated) and before any manual operation is performed. The means for transmitting the force can include, at least in part, the first and second drive plates 44 and 50 that are rotatable (although a corresponding relation of longitudinally moving elements is also mechanically suitable). The means for transmitting the force also includes temporarily mutually engaging parts 52 and 54 on the drive plates 44 and 50 such as those described in connection with
Further, it is seen that the operating member 28 and the output member 26 are in a combination with the drive assembly 42 that includes stop means represented, for example, by the stop bolts 56, for stopping motion of the operating member 28 and the output member 26 upon completion of a switch operation while the motor continues to operate to reach the decoupled state (e.g., the stop means being effective in
Additionally, the example includes means on the operating member 28 (e.g., features 28a or 28b) for locating an alternative operating force means (power or manual; such as via a hookstick (not shown)).
There is also a means for selectively preventing motion of the output member, e.g., locking holes 32a and 28c, that can be held with a manually inserted hookstick for allowing operation of the motor without switch operation. Such a means can occur anywhere between the rotating shaft and the fixed structure.
In various parts of the description and claims where parts of elements or combinations of elements are described, none of the descriptions are to be taken as implying restriction to only the named elements when such a restriction is not required by other language. Accordingly, terms such as “having”, “including” or “comprising” are generally to be taken as intended to be open to other aspects or elements (whether or not spelled out) unless otherwise stated to be limited.
While the invention requires only fairly simple mechanical elements, one could accompany them with various aspects of automated control if desired.
Consequently, it is apparent numerous variations in accordance with the general teachings given above are suitable for practice of the invention.
Number | Name | Date | Kind |
---|---|---|---|
3508179 | Evans et al. | Apr 1970 | A |
3980977 | Evans | Sep 1976 | A |
5091616 | Ramos et al. | Feb 1992 | A |
5769208 | Griffith | Jun 1998 | A |
5856642 | Sanders | Jan 1999 | A |
5895987 | Lo et al. | Apr 1999 | A |
6025657 | Lo et al. | Feb 2000 | A |
6072142 | Linder et al. | Jun 2000 | A |
6818846 | Roberts | Nov 2004 | B1 |