1. Field of the Invention
The invention relates to a motor operator for opening and closing a mains switch of switchgear in mains power distribution systems such as public medium high voltage distribution systems.
2. Description of the Prior Art
Motor operators for switchgears are known see, e.g., U.S. Pat. No. 4,804,809 to Chance Co. AB, U.S. Pat. No. 5,254,814 to Chance Co. AB, WO 2008/052548 A1 to Linak A/S, and WO 2006/106364 to Viserge Ltd. These motor operators are separate units for mounting in front of switchgears as indicated in U.S. Pat. No. 4,804,809 to Chance Co. AB and WO 2006/106364 to Viserge Ltd. The motor operators are contained in a weather- and vandal-proof enclosure which is rather voluminous. Further, it should be fully operable under all weather conditions and operate in a reliable manner. The front surface of the switchgear is exposed to the open air, which is why the overall size of the motor operator is of no significant importance. However, there are also switchgears where the front surface is covered by a front door to protect the front surface of the switchgear and to prevent unauthorized access to the switchgear. The front door restricts the space available for a motor operator, and not only that, it also complicates the mounting as it is prohibited to make bores and weldings in the switchgear cabinet.
It should also be taken into account that the motor 35 operator may be activated either locally or remotely to open and close the mains switch of the switchgear. However, as a safety precaution it should also be possible to operate the switchgear manually, e.g., in case of failure of the motor operator. This also complicates the construction of the motor operator and contributes to the overall size.
Hence, there is a need for a motor operator which overcomes these and other problems associated with the known motor operators.
It is an object of the present invention to provide a motor operator which is easy to mount and could be mounted on switchgear from various manufacturers of switchgear and which to a great extent is nonintrusive and vandal proof. Another object of the invention is to provide a solution that takes up less space and thus can be mounted as a retrofit directly in the accessible part of the housing of the switchgear itself.
According to the invention this is accomplished in that the motor operator further comprises an adapter fixedly connected to the second end of the connection shaft and where a recess in the worm wheel is designed for receiving the adapter in a rotational interlocking manner. Additionally, the worm wheel and the worm is embedded in a separate worm gear housing and a driven end of the worm is accessible on the housing, preferably on a side surface for connection with the drive shaft of the motor. In this way, the overall dimension and especially the thickness of the housing can be kept very small not taking up much space in the front of the switchgear. The connection between the operating shaft of the mains switch and the motor operator is obtained by plugging the adapter into the recess of the worm wheel in a non-rotational interlocking manner, so that the adapter will be carried along in the rotational movements of the worm wheel. The worm wheel is rotated in its bearing in the worm gear housing by the worm which has a driven end to be connected to the electric motor. The electric motor could be fitted directly to the worm gear housing with the motor axle connected directly to the driven end of the worm. Since an electric motor is rather voluminous, it could be advantageous to move the motor a distance away from the worm gear housing. In some switchgear cabinets quite a lot of space is left on top of the sealed compartment of the switch, where it in a preferred embodiment would be convenient to mount the electrical motor in a separate control box also containing various electronic equipments. On the other hand, the motor and the various electronic equipments could also be located in separate housings. The connection from the motor to the driven end of the worm could be a universal transmission, such as a cardan drive. However, a flexible shaft is preferred. The flexible shaft also has the benefit that initial or peak forces to a certain degree are absorbed by the flexible shaft.
In an embodiment the recess in the worm wheel is a through hole aligned with a through hole in the worm gear housing for receiving the adapter bearing the connection shaft. The rotational interlocking of the adapter in the worm wheel so the adapter is carried along with the movements of the worm wheel could be carried out in various manners. The hole could, e.g., have a none-circular cross section, e.g., hexagonal or have at least one straight wall part. On the other hand, the hole could also be circular, but then with means for interlocking, such as retractable pins resting in holes on the other part. In a preferred embodiment the means for rotational interlocking of the adapter in the worm wheel comprises at least one key and one keyway and that the key could be pushed forward from a retracted position to an expelled position in engagement with the keyway preferable by means of a wrench for manually operation of the switchgear. In another embodiment the adapter is located in a circular recess in the worm wheel and is connected to this by a coupling such as a ball coupling.
The adapter or the entire worm gear housing has to be removed if a manual switching of the switchgear is necessary, since it will not be possible to manually drive the worm wheel with the worm and the motor, because of the mechanisms self-locking qualities. When the adapter shaft is removed, the opening in the worm wheel uncovers the operating shaft of the switchgear which can then be operated manually by inserting and using a handle tool suited for the purpose.
Conveniently, the worm gear housing will be equipped with a sensor to sense if the adapter is placed in position in the housing in relation to the worm wheel in a rotational interlocking manner. A receiver to receive the signal provides the signal to a control for monitoring the state of operation of the switchgear.
In a preferred embodiment, the motor operator includes a sensor to determine the rotation angle of the worm wheel.
The information on the rotation angle of the worm wheel can be logged together with the information on the switching transition of the mains switch contacts, and later be used to determine the position of the mains switch contacts. To use a sensor to determine the angle of the worm wheel and thus also the operating shaft of the mains switch is appreciated, since the angle for when a switching transition is accomplished varies from switchgear to switchgear, not only when it comes to different manufacturers, but also of the same type and brand. A procedure of convenience when equipping and installing a motor operator on a switchgear will be to perform a learning session, where as a first action the motor operator will force the mains switch from an open to a closed state, and accordingly store the angle on which the switching transition is activated. After that, a second action must be performed using the motor operator to force the mains switch from the closed state and back to the open state, and accordingly store the angle on which the switching transition is activated. From the stored angles it is possible to map at least three different angle scales that picture the mains switch contacts in the open state, the mains switch contacts in the closed state, and a not determined state in between the two well-defined states where the motor operator performs a switching transition of the switchgear. If the angle measurement stays in the scale where the state of the switchgear is not defined for a long period, an alarm should be issued, since it seems to indicate a failure of the motor operator. It would be appreciated if the control could maintain a log of last known stable connection to provide information regarding the state of the switchgear in case of a faulty motor operator.
In some cases there could be a need to perform a manual operation of the switchgear. It could be in the case of a faulty motor operator, or when service personnel are on site and wishes to manually operate the switchgear and perform service on the transmission line. In that case the transmission line has to be connected to the earth potential by operating the earth switch. This action can only be performed when the switchgear state is open and the handle tool for the mains switch contacts is pulled out. This means that not only the operating tool has to be pulled out, but also if the tool is substituted by the adapter inserted in the worm wheel, it also has to be pulled out. For operating the switchgear operating shaft, a spring has to be suppressed before the power of the spring is released in the transition operation of the mains switch contacts. Removing the adapter or the entire worm gear housing when the spring is not in its relaxed state will be a difficult task and would lead to a sudden release of the spring and rotation of the operating shaft, and should be avoided. To insert the adapter shaft in position back in the worm wheel will be impossible since the means for keeping the adapter shaft in a rotational interlocking manner will not be positioned to receive the adapter shaft. Anyhow, the problem can be solved by adding another two stored set points with basis in the rotation angle of the worm wheel to reflect the angle of the rotation of the worm wheel corresponding to the positions possible to insert the adapter shaft when the spring is in its relaxed state. These set points are calibrated when the motor operator is installed as part of the installation procedure of the motor operator. A procedure of convenience for the storing of the set points could be performed by first manually operating the switch gear to the open state and accordingly manually drive the motor operator until it is possible to insert the adapter and then store the angle measurement as an expression of the relaxed state of the spring when the switchgear is in its open state. As a second action unplugging the adapter and manually operating the switch gear to the closed state and accordingly manually driving the motor operator until it is possible to insert the adapter and then store the angle measurement as an expression of the relaxed state of the spring when the switch gear is in its closed state. After a manual operation, it will then be possible to automatically force the motor drive to automatically rotate the worm wheel into the angle positions where it is again possible to insert or remove the adapter. It has to be understood that the manual operations performed could be substituted with motor drive operations. Then the set points have to be made when it is possible to take out the adapter of the work wheel.
Equipping or connecting the motor operator with a sensor to detect earthing mode will be an advantage since the state of the switch gear can then be monitored from remote via the control system. For more information on a control and surveying system for a switch gear reference is made to WO 2008/052550 A1 to Linak A/S which hereby is made part of the present application. The procedures and features related to controlling the motor operator described in this document will be understood to be possible to implement and carry out in a control unit as referred to. Also the angle detection and stored set points and automated processes are understood to be carried out by the control.
In a preferred embodiment, the motor drives and the control system are arranged in a shared housing, and will benefit from being a compact and easy to install unit which is sealed and protected against the environment. An appreciated type of housing is the type of modular housing specified in WO 2008/052549 A1 Linak A/S which hereby is made part of the present application. The control system for the motor operator in form of an electronic circuitry on a printed circuit board is in an expedient way mounted in one end of the cabinet. In connection with the printed circuit board are sockets for receiving the energy to drive the motors and connections for interfacing with the control system from remote, to transfer data or to directly control the switchgear. The sockets can be placed directly on the printed circuit board and preferably arranged in a way where they fit premade holes for inserting the connectors through the walls of the cabinet. Of course this should be done in a way with respect to keeping the sealing of the cabinet intact, by adding protective means like o-rings on the connectors which go into connector ports to fit into the connection sockets. The motor drives can be placed side by side in the distant end of the cabinet, the output axles protruding out of the end of the cabinet in order to easily mount the flexible cable for connection with the driven worm on the rotary gear mechanism.
Further, the system as described is advantageous since it can be mounted retrofit, nonintrusive on a switch gear with the use of mounting brackets fitted on the outer framework of the switch gear or at already present and available mounting parts of the switchgear housing. Reference is made to WO 2008/052549 A1 Linak A/S for more information as how to mount a motor operator retrofit nonintrusive on a switch gear. Said document is hereby made a part of the present application.
An embodiment of the invention will be described in the following with reference to the accompanying drawings.
In
The operating shaft for the mains switch could be operated by a motor operator 10 which comprises a worm gear housing 11 mounted on a mounting bracket 12 attached to a horizontal transverse beam 13 mounted on the switchgear. Further, the motor operator comprises an electric motor 14 located remotely in a separate control box on top of the switchgear cabinet 2. A flexible connection shaft 15 interconnects the motor 14 and the worm gear housing 11.
In the worm gear housing 11 is embedded a worm wheel 16 having a collar at a front end 17 of the housing 11. Also in the worm gear housing 11 is embedded a worm, a driven end 18 of which is accessible on a sidewall 19 of the housing 11 for connection with the flexible connection 15 to the drive axle of the motor 14. The worm wheel 16 has a recess in the nature of a through hole 20 for receiving an adapter 21 with a connection shaft 22. A first end 23 of the connection shaft 22 is designed as a coupling part 8′ like the coupling part 8 of the wrench 7 so it could operate the operating shaft of the mains switch. The adapter 21 has on its side a key 23 and the hole 20 of the worm wheel 16 has a mating keyway 24 so the adapter could be received in the through hole 20 of the worm wheel 16 in a rotational interlocking manner. The key 23 has a certain clearance in the keyway 24 to prevent the forces from the spring mechanism to be transferred to the worm wheel 16.
The key 23 is a separate element received in a groove in the adapter 21 and could from a retracted position be pushed out when the adapter 21 is located in the through hole 20 of the worm wheel 16 for engagement with the keyway 24 such that the adapter 21 is locked also in its lateral position to secure a correct position in the worm wheel 16 but also in relation to the coupling part 5,5′ of the operation shaft of the mains switch. Most important the locking secures that the coupling part 8′ of the connection shaft 15 of the adapter 21 in fact is in engagement with the operating shaft of the mains switches when the adapter 21 is correctly located in the worm wheel 16. The key 24 is resting on an eccentric in the adapter, which eccentric could be operated by means of the wrench 7 in the hole 25 at the front end of the adapter 21.
Accordingly, it would be understood that the mains switch could be operated by the motor operator when the adapter 21 has been correctly located in the worm wheel 16 and at the same time earthing is prevented. Having the need for operating the switchgear manually, the adapter 21 is removed and the wrench 7 could be inserted through the through hole in the worm wheel 16 and the rear end of the worm gear housing.
All though not shown it should be noted that a similar motor operator is mounted in connection with the other operating shaft of the switchgear the coupling part of which is indicated by 5′.
In a further embodiment, as shown in
As can be seen from
In
In
Although the motor operator has been described in connection with a switchgear having a front door, it would be understood that it could also be used in connection with switchgear where the front surface is exposed to the open air.
Number | Date | Country | Kind |
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2008 01322 | Sep 2008 | DK | national |
2008 01604 | Nov 2008 | DK | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/DK2009/000211 | 9/24/2009 | WO | 00 | 3/23/2011 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2010/034313 | 4/1/2010 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4804809 | Thompson et al. | Feb 1989 | A |
5254814 | Harr | Oct 1993 | A |
5895987 | Lo et al. | Apr 1999 | A |
8129644 | Christensen et al. | Mar 2012 | B2 |
8139345 | Christensen et al. | Mar 2012 | B2 |
Number | Date | Country |
---|---|---|
WO 9716660 | May 1997 | WO |
2006106364 | Oct 2006 | WO |
2008052549 | May 2008 | WO |
2008052550 | May 2008 | WO |
WO 2012163354 | Dec 2012 | WO |
Number | Date | Country | |
---|---|---|---|
20110192707 A1 | Aug 2011 | US |