The present invention relates to an electromagnetic contactor in which a first frame in which an operation electromagnet is mounted and a second frame in which a contact mechanism is mounted are coupled to each other.
As an electromagnetic contactor of such a type, electromagnetic contactors disclosed in PTLs 1 and 2 have been proposed. An electromagnetic contactor disclosed in PTL 1 is configured to couple, by a bolt, a first frame serving as a lower frame into which a fixed core, an operation coil, and so on, of an operation electromagnet are incorporated to a second frame serving as an upper frame into which a contact mechanism, a contact support, a movable core of the operation electromagnet, and so on, are incorporated.
An electromagnetic contactor disclosed in PTL 2 is configured to provide a joining section between a first frame serving as a lower frame that contains a fixed core and a second frame serving as an upper frame that contains a movable core, fixed contacts, and movable contacts with a clamp wire spring to couple the first frame to the second frame, and to couple the first frame to the second frame by the clamp wire spring.
However, in the electromagnetic contactors disclosed in the above-described PTLs 1 and 2, the first frame serving as a lower frame and the second frame serving as an upper frame are coupled by bolting or by using a clamp wire spring.
Therefore, although the first frame and the second frame can be fixed to each other firmly by a bolt or a clamp wire spring, use of a bolt or a clamp wire spring is required for the coupling of the first frame and the second frame, which causes an unsolved problem of an increase in the number of components.
Recently, first frames and second frames of electromagnetic contactors have been formed by injection-molding fiber-reinforced thermoplastic resin, which is reinforced by glass fiber or the like, and coupling a first frame to a second frame in a snap-fit manner has been conceived.
However, it is difficult to secure toughness of fiber-reinforced thermoplastic resin, and wear of a snap-fit section progresses due to vibration produced in changing an operation electromagnet into a released state by switching the operation electromagnet from an excited state to a non-excited state to separate movable contacts from fixed contacts of the electromagnetic contactor itself and, thus, looseness is produced to the snap-fit section, which causes another unsolved problem of being unable to secure durability.
Accordingly, the present invention is made by focusing on the above-described unsolved problems in the conventional examples, and an object of the present invention is to provide an electromagnetic contactor that is capable of suppressing looseness due to wear of a snap-fit section coupling a first frame to a second frame from being produced.
In order to achieve the object mentioned above, according to an aspect of the present invention, there is provided an electromagnetic contactor, including: a first frame in which an operation electromagnet is mounted; a second frame in which a contact mechanism is mounted; and a snap-fit section that is made up of a fitting protruding section and a hook section formed to one and the other of the first frame and the second frame, respectively, the hook section fitting to the fitting protruding section. The hook section has a flexible projecting plate section formed in a projecting manner to an open end of either the first frame or the second frame and a fitting section formed at a tip of the flexible projecting plate section, the fitting section fitting to the fitting protruding section. The flexible projecting plate section is provided with elasticity that fits the fitting section further to a base side of the fitting protruding section in accordance with progress of wear between the fitting section and the fitting protruding section.
According to the present invention, even when wear progresses between a fitting section of a hook section and a fitting protrusion, which forms a snap-fit section that couples a first frame in which an operation electromagnet is mounted to a second frame in which a contact mechanism is mounted, it is possible to maintain a fitting state between the fitting section of the hook section and the fitting protruding section, and to improve durability in the case of coupling the first frame to the second frame in a snap-fit manner.
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
As illustrated in
In the first frame 11A, an operation electromagnet 12 that is made up of, for example, an AC electromagnet is mounted, as illustrated in
The first frame 11A has a bottomed angular cylindrical section 21 that houses the operation electromagnet 12. As illustrated in
To the middle protruding section 22b of the fixed core 22, a spool 23 around which an excitation coil 23a is wound is mounted, as illustrated in
To both end sections on the narrow width sections 21b and 21c sides of the front ends of the other pair of opposing side walls, for example, the right and left side walls, of the wide width sections 21a of the first frame 11A, for example, four hook sections 26 that extend to the front are formed, as illustrated in
Each hook section 26 is made up of a flexible projecting plate section 26a that extends from the front end of the wide width section 21a to the front, has flexibility, and has a relatively wide width and a fitting section 26b formed to the inner side of the tip portion of the flexible projecting plate section 26a, as illustrated in an enlarged manner in
Each fitting section 26b is formed into a cross-sectional trapezoidal shape with an inclined surface 26c that increases in thickness along the direction from the front end of the flexible projecting plate section 26a toward the rear side, that is, the base side of the flexible projecting plate section 26a, a level surface 26d that extends rearward slightly from the rear end of the inclined surface 26c, a fitting surface 26e that extends from the rear end of the level surface 26d toward the flexible projecting plate section 26a in the direction orthogonal to the flexible projecting plate section 26a to approximately half the thickness of the fitting section 26b, and a circular arc surface 26f that is made up of a round chamfer continuously connected to the outer side of the fitting surface 26e.
Each hook section 26 is formed integrally with the open end face of the first frame 11A in injection-molding fiber-reinforced thermoplastic resin, and the thickness of the flexible projecting plate section 26a being thin causes the flexible projecting plate section 26a to extend in an inwardly inclined manner due to residual stress after injection molding.
Therefore, to fit a hook section 26 to a fitting protruding section 36 as described later, the hook section 26 is fitted to the fitting protruding section 36 with the flexible projecting plate section 26a thereof being bent outward. Thus, elasticity that biases the fitting section 26b to the base side of the fitting protruding section 36 is provided to the flexible projecting plate section 26a.
To the four corners of the bottom of the bottomed angular cylindrical section 21 of the first frame 11A, mounting plate sections 27 each of which has a mounting hole are formed.
The second frame 11B includes an angular cylinder section 30 the shape of which on the coupling section side at which the second frame 11B is coupled to the first frame 11A is identical to the shape of the bottomed angular cylindrical section 21 of the first frame 11A, as illustrated in
The angular cylinder section 30 also has opposing side face plate sections 30a and 30b with which the narrow width sections 31b and 31c are not continuous and that extend to the opposite side to the coupling section side, as illustrated in
On the upper side of the coupling plate sections 30c, a plurality of, for example, three partition walls 34 that partition the interspace between the opposing side faceplate sections 30a and 30b into parallel subspaces are formed, and main circuit load side terminal sections 32b and an auxiliary terminal section 33b are mounted in the subspaces.
Further, to the opposing side face plate sections 30a and 30b, recessed sections 35 that open the side faces from the lower end side are formed at four locations opposed to the hook sections 26 of the first frame 11A, and, on the lower end side of the base of each recessed section 35, a fitting protruding section 36 to which the fitting section 26b of a corresponding hook section 26 formed to the first frame 11A is fitted from the outer side is formed.
Each recessed section 35 has a tool insertion space section 35a formed on the front end side thereof when the fitting section 26b of a hook section 26 is locked to a fitting protruding section 36, as illustrated in
Each fitting protruding section 36 includes a rear end surface 36a that is flush with the rear end surface of a recessed section 35, an inclined surface 36b that is formed in such a way as to gradually increase in thickness outward along the direction from the outer end of the rear end surface 36a toward the front, a level surface 36c that extends from the outer side end section of the inclined surface 36b to the front, and a fitting surface 36d that extends from the front end of the level surface 36c toward the base side of the recessed section 35, as illustrated in an enlarged manner in
A snap-fit section 37 is made up of a hook section 26 formed to the first frame 11A and a fitting protruding section 36 formed to the second frame 11B.
An arc-extinguishing chamber 38 is formed behind the coupling plate sections 30c, and, inside the arc-extinguishing chamber 38, a contact support 39 that holds movable contacts 39a is held slidably in the front and rear direction. To the rear face side of the contact support 39, a movable core 40 that is opposed to the fixed core 22 is coupled by a coupling spring 40a, as illustrated in
In addition, an arc-extinguishing cover 41 is arranged so as to cover the upper face, the front face, and the lower face of the coupling plate section 30c.
The first frame 11A and the second frame 11B are coupled into one body with the hook sections 26 of the first frame 11A being fitted to the fitting protruding sections 36 of the second frame 11B, as illustrated in
When the first frame 11A is coupled to the second frame 11B, the hook sections 26 formed to the first frame 11A are made to face the fitting protruding sections 36 formed to the second frame 11B in such a way that the coil terminal 25 protruding from the first frame 11A faces the main circuit power supply side terminal sections 32a and the auxiliary terminal section 33a of the second frame 11B.
When each hook section 26 is in a free state in which the hook section 26 is not fitted to a corresponding fitting protruding sections 36 of the second frame 11B, the flexible projecting plate section 26a thereof extends in an inwardly inclined manner at a predetermined angle due to residual stress in injection molding, as illustrated in
It is now assumed temporarily that, when the first frame 11A and the second frame 11B are coupled to each other by the hook sections 26 being fitted to the fitting protruding sections 36, there is no interference between the fitting sections 26b of the hook sections 26 and the fitting protruding sections 36. In this case, it is set so that, to cause the flexible projecting plate section 26a of each hook section 26 to be flush with side faces of the first frame 11A and the second frame 11B, the ridgeline between level surface 36c and the fitting surface 36d of the fitting protruding section 36 is located at a position inside the fitting section 26b anterior to the circular arc surface 26f continuously connected to the fitting surface 26e of each hook section 26, as illustrated in
Moving the second frame 11B toward the first frame 11A side with each hook section 26 facing a corresponding fitting protruding section 36 causes the inclined surface 26c of each hook section 26 to contact the ridgeline between the rear end surface 36a and the inclined surface 36b of a corresponding fitting protruding section 36. Further moving the second frame 11B toward the first frame 11A side causes the ridgeline between the inclined surface 26c and the level surface 26d of each hook section 26 to contact the inclined surface 36b of a corresponding fitting protruding section 36 to cause the flexible projecting plate section 26a of the hook section 26 to be bent outward.
Thereafter, the level surface 26d of each hook section 26 is engaged with the level surface 36c of a corresponding fitting protruding section 36, and the fitting surface 26e of the hook section 26 is locked to the fitting surface 36d of the fitting protruding section 36. At this time, when in a state in which no wear has occurred to the fitting surface 36d of each fitting protruding section 36, the first frame 11A and the second frame 11B are coupled to each other with the boundary position between the fitting surface 26e and the circular arc surface 26f of each hook section 26 contacting the ridgeline between the level surface 36c and the fitting surface 36d of a corresponding fitting protruding section 36 and the flexible projecting plate section 26a, for example, being bent outward, as illustrated in
However, when the electromagnetic contactor 10 is operated while the hook sections 26 are in a state of being fitted to the fitting protruding sections 36 as illustrated in
When the electromagnetic contactor 10 is in the released state, supplying AC power to the excitation coil 23a of the operation electromagnet 12 to change the operation electromagnet 12 into an excited state causes the movable core 40 to be attracted to the fixed core 22 against the return spring. Thus, the movable contacts 39a supported by the contact support 39, which is connected to the movable core 40 by the coupling spring 40a, contact the fixed contacts to electrically connect the main circuit power supply side terminal sections 32a and the auxiliary terminal section 33a to the main circuit load side terminal sections 32b and the auxiliary terminal section 33b, respectively, causing the electromagnetic contactor 10 to be brought to a conducting state.
When in the conducting state, breaking the AC power supply to the excitation coil 23a of the operation electromagnet 12 causes attractive force by the fixed core 22 to disappear to cause the movable core 40 to be returned to a released position in front by the return spring. On this occasion, vibration is generated due to the movable core 40 being returned to the released position by the return spring, and the vibration being transmitted to the first frame 11A and the second frame 11B causes wear to be produced to a contact section at which the fitting surface 26e and circular arc surface 26f of each hook section 26 contact the fitting surface 36d of a corresponding fitting protruding section 36, which is a coupling section of the first frame 11A and the second frame 11B.
The conducting state and the released state being repeated causes wear between the fitting surface 26e and circular arc surface 26f of each hook section 26 and the fitting surface 36d of a corresponding fitting protruding section 36 to progress.
The wear is produced to a ridgeline section between the level surface 36c and the fitting surface 36d of each fitting protruding section 36 substantially, and the ridgeline section becomes a circular arc surface that gradually increases in radius due to wear. In this case, since the flexible projecting plate section 26a of each hook section 26 originally extends in an inwardly inclined manner and is caused to be bent, as illustrated in
As wear between each hook section 26 and a corresponding fitting protruding section 36 further progresses, the flexible projecting plate section 26a of the hook section 26 is brought to a state of being inclined, as illustrated in
As described above, even when wear between each hook section 26 and a corresponding fitting protruding section 36 progresses, the flexible projecting plate section 26a becomes inclined in accordance with the wear by elastic force caused by bending of the flexible projecting plate section 26a of the hook section 26, causing the fitting section 26b of the hook section 26 to contact a position further on the base side of the fitting protruding section 36. Therefore, it is possible to suppress a gap from being produced between the fitting surface 26e and circular arc surface 26f of each hook section 26 and the ridgeline section between the level surface 36c and the fitting surface 36d of a corresponding fitting protruding section 36.
Therefore, even when a snap-fit connection is applied to the coupling of the first frame 11A to the second frame 11B, it is possible to surely suppress a coupling state between the first frame 11A and the second frame 11B from changing due to long-time use. Thus, it is possible to suppress occurrences of vibration sound that is produced between the first frame 11A and the second frame 11B when the electromagnetic contactor 10 is switched to the released state.
As a result, the durability of the electromagnetic contactor 10 can be improved, and, without a clamp wire spring or a bolt to coupling the first frame 11A to the second frame 11B being provided as in the afore-described conventional example, it is possible to securely couple the first frame 11A to the second frame 11B by the snap-fit sections, making it possible to decrease the number of components and to reduce the production cost of electromagnetic contactors.
In addition, since inclination due to residual stress after injection molding of fiber-reinforced thermoplastic resin is used to incline the flexible projecting plate section 26a of each hook section 26 inward, no special design is required to incline the flexible projecting plate section 26a , and neither is it required to design a shape that suppresses an inclination of the flexible projecting plate section 26a due to residual stress.
In the above-described embodiment, a case in which, when in a state in which no wear is produced, the flexible projecting plate section 26a is in a state of being bent outward, as illustrated in
Although, in the above-described embodiment, a case in which an AC electromagnet is used as the operation electromagnet 12 was described, the present invention is not limited to the case, and a non-polarized DC electromagnet or a polarized DC electromagnet can also be used. In such a case, a plunger may be coupled to the contact support 39 by a coupling spring.
In the above-described embodiment, a case in which the hook sections 26 and the fitting protruding sections 36 are formed to the first frame 11A and the second frame 11B, respectively, was described. However, the present invention is not limited to the above-described configuration, and the fitting protruding sections 36 and the hook sections 26 may be formed to the first frame 11A and the second frame 11B, respectively.
The number of arranged pairs of a hook section 26 and a fitting protruding section 36 is not limited to four pairs, and an arbitrary number of pairs, such as three pairs and five or more pairs, may be arranged.
Furthermore, although, in the above-described embodiment, a case in which an AC electromagnet is used as the operation electromagnet 12 was described, the present invention is not limited to the case, and a non-polarized DC electromagnet or a polarized DC electromagnet can also be used. In such a case, a plunger may be coupled to the contact support 39 by a coupling spring.
In the above-described embodiment, a case in which the hook sections 26 and the fitting protruding sections 36 are formed to the first frame 11A and the second frame 11B, respectively, was described. However, the present invention is not limited to the above-described configuration, and the fitting protruding sections 36 and the hook sections 26 may be formed to the first frame 11A and the second frame 11B, respectively.
The number of arranged pairs of a hook section 26 and a fitting protruding section 36 is not limited to four pairs, and an arbitrary number of pairs, such as three pairs and five or more pairs, may be arranged.
10 Electromagnetic contactor
11A First frame
11B Second frame
12 Operation electromagnet
13 Contact mechanism
21 Bottomed angular cylindrical section
22 Fixed core
23 Spool
25 Coil terminal
26 Hook section
26
a Flexible projecting plate section
26
b Fitting section
26
c Inclined surface
26
d Level surface
26
e Fitting surface
26
f Circular arc surface
30 Angular cylinder section
32
a Main circuit power supply side terminal section
32
b Main circuit load side terminal section
33
a, 33b Auxiliary terminal section
35 Recessed section
36 Fitting protruding section
36
a Rear end surface
36
b Inclined surface
36
c Level surface
36
d Fitting surface
37 Snap-fit section
39 Contact support
40 Movable core
Number | Date | Country | Kind |
---|---|---|---|
2014-104751 | May 2014 | JP | national |
This application is a continuation application filed under 35 U.S.C. § 111(a), of International Application PCT/JP2015/001949, filed Apr. 7, 2015, and claims foreign priority benefit to Japanese Patent Application No. 2014-104751, filed May 20, 2014, the contents of which are incorporated herein by reference.
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Entry |
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International Search Report dated May 19, 2015, in corresponding International Application No. PCT/JP2015/001949. |
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Number | Date | Country | |
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20160293366 A1 | Oct 2016 | US |
Number | Date | Country | |
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Parent | PCT/JP2015/001949 | Apr 2015 | US |
Child | 15185450 | US |