1. Field of the Invention
The present invention relates to an electromagnetic relay, more particularly to an electromagnetic relay including an armature component supported pivotally at a middle portion thereof.
2. Description of the Related Art
Referring to
When the armature block 135 is affected by an electromagnetic field generated by the electromagnet block 12, the armature block 135 is brought into contact with left fixed contacts, so as to establish electrical connection between the common terminals 132 and the left fixed contact terminals 133 while breaking electrical connection between the common terminals 132 and the right fixed contact terminals 133. When the electromagnetic field is not generated, the armature block 135 is brought into contact with right fixed contacts, so as to establish electrical connection between the common terminals 132 and the right fixed contact terminals 133 while breaking electrical connection between the common terminals 132 and the left fixed contact terminals 133. Therefore, the electromagnetic relay 1 can serve as a switch unit.
However, because the coil winding portions 122 of each pair of the junction terminals 123 project from the spool 121 away from each other, the size of the base body 131 is relatively large in order to accommodate the entire electromagnet block 12. Moreover, since there is no mechanism for fixing the electromagnet block 12 in the base body 131, it is difficult to connect the junction terminals 123 accurately to the coil terminals 134 during assembly. Further, the common, fixed contact, and coil terminals 132, 133, 134 are manually welded on both sides of the base body 131, so that the electromagnetic relay 1 cannot be fabricated at a high rate.
Therefore, an object of the present invention is to provide an electromagnetic relay that is easy to assemble and that can be fabricated at a high rate.
Accordingly, an electromagnetic relay of this invention comprises a casing, and a relay core member that is sealed in the casing, and that includes an electromagnetic unit and a terminal unit.
The electromagnetic unit is adapted for generating an electromagnetic field, and includes a spool frame set that includes a pair of opposite first sides and a pair of opposite second sides, a coil unit wound on the spool frame set, and a pair of coil winding pins. Each of the coil winding pins has a conductive portion exposed from one of the first sides, and a coil winding portion extending along one of the second sides. The spool frame set further includes an engagement portion.
The terminal unit includes an engaging block including an engagement portion connected to the engagement portion of the spool frame set of the electromagnetic unit for preventing separation of the terminal unit from the electromagnetic unit, a terminal set exposed from the casing, and an armature component being affected by the electromagnetic field generated by the electromagnetic unit and serving as a switch mechanism by cooperating with 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
The casing 2 includes an upper casing body 21 and a bottom casing body 22 that are connected with each other by press fitting.
The electromagnetic unit 3 is adapted for generating an electromagnetic field, and includes a spool frame set 31 having a pair of opposite first sides (31a) and a pair of opposite second sides (31b), a coil unit 32 being wound on the spool frame set 31 and including at least one coil 32′, and a pair of coil winding pins 33. The spool frame set 31 includes a spool frame 310 wound with the coil unit 32, a pair of mounting frames 311, an iron core 312 attached fixedly to the spool frame 310, and a permanent magnet 313 inserted into the spool frame 310 and disposed on a middle portion of the iron core 312. Each of the mounting frames 311 is disposed at and extends along a respective one of the first sides (31a) of the spool frame set 31, and has a pair of through holes 315 formed therethrough and spaced apart from each other. Further, each of the mounting frames 311 includes an outer surface formed with a groove 314. Each of the coil winding pins 33 has a conductive portion 331, and a coil winding portion 332 extending along one of the second sides (31b) of the spool frame set 31. Each of the conductive portions 331 has a horizontal section being exposed from one of the mounting frames 311, and a vertical section extending into a corresponding one of the through holes 315. One end of each of the conductive portions 331 is aligned with an outer surface of the corresponding mounting frame 311, and the coil winding portions 332 of the coil winding pins 33 are disposed in a space 316 defined by the mounting frames 311.
The terminal unit 4 includes an engaging block 41 configured for accommodating the electromagnetic unit 3, a terminal set 42 inserted into the engaging block 41 and exposed from the bottom casing body 22 of the casing 2, and an armature component 43 being affected by the electromagnetic field generated by the electromagnetic unit 3 and serving as a switch mechanism by cooperating with the terminal set 42. The engaging block 41 includes a pair of opposite sidewalls 414 corresponding respectively to the first sides (31a) of the spool frame set 31, a pair of opposite side surfaces 415 corresponding respectively to the second sides (31b) of the spool frame set 31, a pair of barbs 411 disposed respectively on inner surfaces of the sidewalls 414, and a top surface 412 confronting the armature component 43. Each of the sidewalls 414 of the engaging block 41 is formed with a pair of notches 413, and the horizontal sections of the conductive portions 331 of the coil winding pins 33 are disposed respectively within the notches 413 (see
Referring to
Referring to
Further referring to
Subsequently, the common terminals 421 are welded to the middle contact portion 431 of the armature component 43, and the coil terminals 423 are welded to the conductive portions 331 of the coil winding pins 33 at the welding points 424, 425, 426, respectively, using laser welding method. Referring to
When a voltage is applied to the coil terminals 423 to pass electric current through the coil 32′, the electromagnetic unit 3 generates the electromagnetic field so as to attract the right movable contact portions 432 of the armature component 43. Therefore, each of the right movable contact portions 432 is pivoted to a connection position, where the corresponding right movable contact portion 432 is electrically connected to a corresponding one of the fixed contact terminals 422. When no voltage is applied to the coil terminals 423, the electromagnetic field is not generated, and therefore each of the right movable contact portions 432 of the armature component 43 is biased to a disconnection position, where the corresponding right movable contact portion 432 is separated from the corresponding one of the fixed contact terminals 422. Thus, the armature component 43 serves as a switch mechanism.
It should be noted that the electromagnetic unit 3 can also include two pairs of the coil winding pins 33 (not shown), so that the electromagnetic relay of this invention serves as a double-pole-double-throw (DPDT) relay to transmit two control signals. Techniques for transmitting two control signals and the DPDT relay are existing techniques, and descriptions thereof will be omitted herein for the sake of brevity.
In sum, the electromagnetic relay of the present invention has the following advantages. First, because one end of each of the conductive portions 331 of the coil winding pins 33 is aligned with the outer surface of the corresponding one of the mounting frames 311, and the coil winding portions 332 are disposed in the space 316 between the mounting frames 311, it is possible to reduce the size of the electromagnetic unit 3. Second, the welding points 424, 425, 426 can be formed using laser welding method, such that the manufacturing process of the electromagnetic relay is relatively simple. Third, each of the barbs 411 engages a corresponding one of the grooves 314 for preventing separation of the terminal unit 4 from the electromagnetic unit 3, so that the coil terminals 423 can be connected accurately to the coil winding pins 33 during assembly of the electromagnetic relay. Therefore, an automated manufacturing process can be utilized for the electromagnetic relay of the present invention.
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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098102242 | Jan 2009 | TW | national |