Protective relays are commonly used in electric utility applications to detect various possible problems in electrical power output. Such relays protect a wide variety of equipment and are used in relay systems which also include circuit breakers. The primary function of a relay is to provide trip signals to circuit breakers.
Generally, current transformers and potential transformers are employed to obtain a signal in high current and/or high potential applications. Transformers reduce the magnitude of the current or voltage, and then feeds the signal to the relays, meters and instruments at a much lower level for detection. The relay terminals may then be electrically connected to a test switch terminal or poles. Each test switch can be associated with one or more relays. As is known in the art, it is necessary to short circuit the line and load terminals when the relay is removed from its case or the adjacent test switch is opened. The test switch provides this necessary short circuit or bypass feature. If this short circuit does not occur, the associated current transformer may be damaged and the safety of nearby personnel could be jeopardized.
With reference to
Test switch 10 includes on its front face 10 switches 12a to 12j arranged in five (5) sets. In the embodiment shown in
An example of the three sets of switches associated with a current transformer are shown in
As is known in the art, test switch 10 also includes a plurality of terminals 18a-j on its rear face for connection to the relays associated with the current transformers and the three phases and neutral of the three phase source. When test switch 10 is mounted in a switchboard panel the switches 12a to 12j are accessible from the front of the panel and the rear terminals are accessible from the rear of the panel.
Prior art test switches typically include a pair of threaded posts that extend from the front face. These posts are received in holes in a cover, which fits over and protects the front face. A threaded thumbnut is then secured to the protruding posts to hold the cover in place during normal operation.
When the switch must be accessed, the cover must be removed. In the past, covers have been misplaced once removed. In other instances, the covers have been damaged after removal when placed in non-safe locations. Thus, there is a need in the art to provide a cover for a test switch which minimizes the risk of loss or damage when the cover is removed.
According to one aspect of the present invention, a cover assembly is provided for protecting a test switch having a pair of forwardly extending, opposed posts, each post including a threaded portion. The cover assembly includes a cover including a front wall having a pair of holes on opposed sides of the front wall, the holes are sized to receive at least a portion of the posts therethrough. A pair of thumbnuts are provided, each including a hollow cylindrical body portion. A plurality of resilient tabs extend outwardly from a first end of the hollow cylindrical portion. An annular gripping portion is positioned at a second end of the hollow cylindrical portion. The annular gripping portion has a larger radius than the hollow cylindrical portion. A nut is positioned at the second end radially interior to the annular gripping portion. The nut includes a threaded hole for engaging the threaded portion of the post. Each thumbnut is positioned in one of the holes and the nut is composed of a first material and all other components of the thumbnut are composed of a second material, the first material being a metallic magnetic material.
According to another aspect of the present invention, a cover assembly is provided for protecting a test switch having a pair of forwardly extending, opposed posts. Each post includes a threaded portion. The cover assembly includes a cover including a front wall having a pair of holes on opposed sides of the front wall. The holes are sized to receive at least a portion of the posts therethrough. A thumbnut is positioned in each hole and includes a threaded hole for engaging the threaded portion of the post. A tether is secured at a first end to the cover and at a second end has a looped portion sized to removably receive the post therein. The looped portion is made of a magnetic material.
With reference now to
With reference now to
With reference now to
At the second end 70 of body portion 64 a flange 72 extends radially outwardly. An annular gripping portion 74 extends from the outer edge of flange 72. As can be seen, annular gripping portion 74 includes a radially facing grip surface 76 that includes a plurality of ridges that improves a human's grip of thumbnut 62.
Thumbnut 62 includes a nut 78 having a central threaded hole 80 that is axially aligned with the hollow center 82 central body portion 64. The hollow center 82 of body portion 64 includes a radius that is equal to or larger than the radius of threaded hole 80. According to one embodiment, nut 78 may be in the form of a hex nut.
At least some portion of thumbnut 62 is made of a magnetic material.
According to one particularly advantageous embodiment, nut 78 is formed of a magnetic metallic material and the remaining parts of thumbnut 62 may be formed of a non-magnetic material. According to this embodiment, a magnetized nut 78 may be provided, and the remaining parts of thumbnut 62 may be formed of a plastic material, over-molded over nut 78.
With reference now to
With reference now to
During normal use, cover 100 is secured to test switch 50 in the same manner as discussed above, wherein a thumbnut is secured to a post that extends through hole 110. When cover 100 is removed from a test switch, the rear edge 114 may be positioned proximate to a generally flat, metallic surface 116 so that magnets 112 hold cover 100 thereto. According to this embodiment, thumbnuts may be removed (as shown in
With reference now to
Cover 200 includes a pair of projections 210 that extend rearwardly from front wall 202. One projection 210 is proximate to each side wall 204 so that projections 210 are on opposed ends of cover 200. Projections 210 extend rearwardly about half the depth of side wall 204. Each projection 210 carries a magnet 212 on its rear face 214. Ring shaped magnet 212 is cylindrical or ring shape and defines a central aperture 216.
Cover 200 includes an additional projection 218 that extends rearwardly from front wall 202. Projection 218 is positioned proximate to one of side walls 204 between projection 210 and top wall 206. Projection 218 extends rearwardly nearly the same depth as side wall 204. Projection 218 carries a magnet 220 on its rear face 222. Magnet 220 may extend rearwardly from rear surface 222 so that it is even with or extends slightly past the rear edge 224 of side wall 204.
Cover 200 protects a test switch 226 that is substantially identical to the test switch 50 described above with the exception that posts 228 are modified. Posts 228 do not include a threaded area and are sized to be received in central apertures 216. According to one embodiment, posts 226 are metallic and thus, by inserting posts 228 into apertures 216, cover 200 is retained against test switch 226. According to another embodiment, posts 228 may also be magnetic, thus facilitating an even stronger attraction between cover 200 and test switch 226.
Should a maintenance person wish to access test switch 226, cover 200 is pulled forward with sufficient force to break the magnetic bonds between magnets 212 and posts 228. Thereafter, the cover 200 may be positioned proximate to a generally flat, metallic surface 230 such that magnet 220 holds cover 200 thereto (see
With reference now to
During normal use, cover 300 is secured to test switch 326 in the same manner as discussed above, wherein a thumbnut is secured to a post 324 extending through holes 310. When cover 300 is removed from test switch 326, the tether 318 holds cover 300 beneath test switch 326. In this manner, the cover 300 is retained near the test switch 326. This prevents the cover from being damaged or lost.
According to yet another embodiment, the looped portion 322 may be made of a magnetic material. This magnetic material may help hold the looped portion 322 on post 324. Further, tether 318 may be removed from post 324, and looped portion 322 may be placed against any metallic surface. Thereafter, the magnetic attraction holds loop portion, and consequently cover 300, until such time that the cover is reaffixed to test switch 326.
It is to be understood that the description of the foregoing exemplary embodiment(s) is (are) intended to be only illustrative, rather than exhaustive, of the present invention. Those of ordinary skill will be able to make certain additions, deletions, and/or modifications to the embodiment(s) of the disclosed subject matter without departing from the spirit of the invention or its scope, as defined by the appended claims.
This application claims priority to U.S. Provisional Application No. 61/157218 titled Test Switch Cover Assembly and filed on Mar. 4, 2009, the contents of which are incorporated by reference in their entirety.
Number | Date | Country | |
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61157218 | Mar 2009 | US |