This application claims priority of Taiwanese Application No. 097143683, filed on Nov. 12, 2008.
1. Field of the Invention
The present invention relates to an electromagnetic relay, more particularly to an electromagnetic relay that is easy to assemble accurately and has a relatively higher breakdown voltage value.
2. Description of the Related Art
Referring to
The conventional electromagnetic relay 1 has the following disadvantages. First, the configuration of connecting the first and second mounting frame 112, 115 is easily broken. Second, riveting of the resilient component 131 on the yoke component 113, and improper positioning of the magnetic component 132 relative to the first mounting frame 112 result in complex and difficult assembly of the relay 1. Moreover, the casing 12 has an open configuration such that the relay core member 11 of the conventional electromagnetic relay 1 cannot be electromagnetically isolated very well, and is susceptible to interference from the surroundings. Further, assembly accuracy is relatively poor due to the open configuration of the casing 12 such that the conventional electromagnetic relay 1 has a relatively lower breakdown voltage value.
Therefore, an object of the present invention is to provide an electromagnetic relay that is easy to assemble, that costs relatively less for manufacturing, and that has a relatively higher breakdown voltage value.
Accordingly, an electromagnetic relay of the present invention comprises a casing, a relay core member, an actuating set, a terminal set, and a housing.
The casing has a first side formed with an opening and a second side opposite to the first side. The relay core member is adapted for generating an electromagnetic field, is inserted into the casing through the opening, and is formed with a recess having first and second positioning portions which are exposed from the casing.
The actuating set includes an elongate magnetic component and a resilient component. The elongate magnetic component is inserted into the first positioning portion of the recess in the relay core member, and extends along a direction generally perpendicular to a direction of the electromagnetic field generated by the relay core member. The elongate magnetic component is pivotable between a first position and a second position. The resilient component is inserted into the second positioning portion of the recess in the relay core member and pressing against the magnetic component for providing a resilient force thereto. When the electromagnetic field is generated, the magnetic component is at the second position. When the electromagnetic field is not generated, the magnetic component is biased to the first position.
The terminal set includes first, second and third terminals which are disposed on the casing. The third terminal is disposed between the first terminal and the second terminal, and is biased to contact the first terminal when the magnetic component is at the first position. The actuating set actuates the third terminal to contact the second terminal when the magnetic component is moved from the first position to the second position. The housing accommodates the casing, the relay core member, the actuating set and the terminal set.
Other features and advantages of the present invention will become apparent in the following detailed description of the preferred embodiment with reference to the accompanying drawings, of which:
Referring to
Referring to
The relay core member 3 is adapted for generating an electromagnetic field, and includes a coil unit 31, a first mounting frame 32 for mounting the coil unit 31 thereon and disposed within the casing 2, a second mounting frame 33 connected fixedly to the first mounting frame 32 for sealing the opening 23 in the casing 2 and formed with a recess (333R), an L-shaped limiting component 34, and a pair of conductive pins 35. The coil unit 31 includes a coil 311 wound around the first mounting frame 32, and a magnetic core 312 extending through the coil 311 and the second mounting frame 33 along the direction (X) of the electromagnetic field. The magnetic core 312 includes a neck 313 projecting therefrom.
Preferably, the first and second mounting frames 32, 33 are formed integrally. The first mounting frame 32 includes a connecting end 32′ and a non-connecting end 32″ opposite to the connecting end 32′ and formed with a first through hole 321. The second mounting frame 33 includes an elongate transverse plate 331 extending along a direction perpendicular to the direction (X) and formed with a second through hole 332, an engaging block 333 exposed from the casing 2 and formed with the recess (333R), and two barbs 336 disposed on the engaging block 333 and engaging the engaging grooves 241 in the block-engaging unit 24 of the casing 2. The elongate transverse plate 331 has a first side surface 331′ connected fixedly to the connecting end 32′ of the first mounting frame 32, and a second side surface 331″ opposite to the first side surface 331′. The engaging block 333 extends integrally from the second side surface 331″ of the transverse plate 331 along the direction (X) and has a first side surface 333′ formed with the recess (333R) and an opposite second side surface 333″.
The recess (333R) is defined by two opposite inner surfaces (333W), and has a first positioning portion 334 and a second positioning portion 335. The inner surfaces (333W) are formed with two aligned slots (333S) that constitute cooperatively the second positioning portion 335.
Moreover, the transverse plate 331 further has a neck-engaging hole 337 formed at a position where the engaging block 333 extends from the transverse plate 331. The limiting component 34 has a connecting plate part 342 connected to the transverse plate 331, a limiting plate part 343 perpendicular to the connecting plate part 342, and a neck 344 projecting from the connecting plate part 342. The limiting plate part 343 abuts against the non-connecting end 32″ of the first mounting frame 32, and has a third through hole 341 formed through the limiting plate part 343. The neck 344 fittingly engages the neck-engaging hole 337 in the transverse plate 331. The magnetic core 312 extends through the first through hole 321 and the second through hole 332, and the neck 313 of the magnetic core 312 fittingly engages the third through hole 341, such that removal of the magnetic core 312 from the first mounting frame 32 through the first through hole 321 is prevented. The conductive pins 35 are inserted through the engaging block 333 of the second mounting frame 33, and are electrically connected to the coil 311.
The actuating set 4 includes an elongate magnetic component 41 inserted into the first positioning portion 334 of the recess (333R) in the engaging block 333 and extending along a direction generally perpendicular to the direction (X), a resilient component 42 inserted into the second positioning portion 335 of the recess (333R) in the engaging block 333, and a drive component 43 extending along the direction (X) for connecting the magnetic component 41 with the terminal set 5. The magnetic component 41 is pivotable between a first position and a second position. When the electromagnetic field is generated, the magnetic component 41 is at the second position, as shown in
The magnetic component 41 includes an insertion end 411 inserted into the first positioning portion 334 of the recess (333R) in the engaging block 333 and formed with a hole 413 in a surface facing the resilient component 42, and a traction end 412 connected to the drive component 43. Preferably, the magnetic component 41 is longer than the transverse plate 331. The resilient component 42 includes a frame 421 having an inner periphery 420, a resilient arm 422 connected integrally and inclinedly to the inner periphery 420, inserted into the hole 413, and pressing against the magnetic component 41 for providing a resilient force to the magnetic component 41, a pair of barbs 423 extending respectively from two opposite sides of the frame 421 away from each other and anchored in the slots (332S), respectively, and a limiting plate 424 perpendicularly connected to the frame 421 and exposed from the recess (333R). The limiting plate 424 abuts against the engaging block 333 for positioning the frame 421 of the resilient component 42 within the second positioning portion 335 of the recess (333R) in the engaging block 333.
The terminal set 5 includes first, second and third terminals 51, 52 and 53 which are disposed on the terminal-mounting unit 25 of the casing 2 such that the terminal set 5 and the opening 23 are disposed respectively at two opposite sides of the casing 2, wherein the third terminal 53 is disposed between the first terminal 51 and the second terminal 53, and is connected to the drive component 43 of the actuating set 4. The third terminal 53 is biased to contact the first terminal 51 when the magnetic component 41 is at the first position, and the drive component 43 of the actuating set 4 actuates the third terminal 53 to contact the second terminal 52 when the magnetic component 41 is moved from the first position to the second position.
The housing 6 accommodates the casing 2, the relay core member 3, the actuating set 4 and the terminal set 5.
Referring to
In sum, the electromagnetic relay of the present invention has the following advantages. First, because the magnetic component 41 and the resilient component 42 are inserted respectively into the first and second positioning portions 334, 335 of the recess (333R) in the engaging block 333, it is relatively easy to assemble the electromagnetic relay of the present invention so as to enhance the assembly accuracy. Therefore, an automated manufacturing process can be utilized for the electromagnetic relay of the present invention. Second, the second mounting frame 33 seals the opening 23 in the casing 2 for isolating electromagnetically the coil unit 31 to thereby minimize electromagnetic interference from the surroundings and maintain an effective magnetic attraction for the magnetic component 41. Third, because the first and second mounting frames 32, 33 are formed integrally, and the engaging block 33 extends integrally from the second side surface 331″ of the transverse plate 331, the configuration of the electromagnetic relay of the present invention is relatively strong. Additionally, under the same magnetic attraction of the electromagnetic field, since the magnetic component 41 is longer than the transverse plate 331, a relatively long moment arm associated with a force applied to the third terminal 53 can be obtained to thereby enhance switching accuracy of the terminal set 5.
According to the above-mentioned advantages, it has been verified through experiments that the electromagnetic relay of the present invention has a breakdown voltage value much higher than that of a conventional electromagnetic relay. Therefore, the service life of the electromagnetic relay of the present invention is relatively longer.
While the present invention has been described in connection with what is considered the most practical and preferred embodiment, it is understood that this invention is not limited to the disclosed embodiment but is intended to cover various arrangements included within the spirit and scope of the broadest interpretation so as to encompass all such modifications and equivalent arrangements.
Number | Date | Country | Kind |
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097143683 | Nov 2008 | TW | national |