The present invention relates to a polarized DC electromagnetic device having an outer yoke attached to the outside of a spool around which an excitation coil is wound and having a plunger inserted through the spool, and an electromagnetic contactor using this device.
As a coil terminal of an electromagnetic device, for example, an electromagnetic contactor described in Patent Literature 1 is known.
This coil terminal has a configuration wherein a terminal block is integrally formed in a coil winding frame around which a coil is wound so that the terminal block laterally projects, and a terminal fitting having a lead wire connection portion is attached and fixed to the terminal block.
PTL 1: JP 2008-300328 A
Now, in the coil terminal described in Patent Literature 1 mentioned above, the terminal block is integrally formed in the coil winding frame around which the coil is wound, so that when a fixed core and a movable core are separate as in an alternating-current electromagnet, the movable core can be easily attached to the terminal block. However, when an outer yoke is disposed around the side surface of the coil winding frame as in a polarized DC electromagnet, there are unsolved problems that it takes time to attach the outer yoke to the terminal block and the assembly efficiency of the electromagnetic device deteriorates.
To improve the assembly efficiency of the electromagnetic device, the width dimension of the terminal block needs to be increased, which leads to the increase of the electromagnetic device in size.
Thus, the present invention has been developed in view of the unsolved problems of the above conventional example, and an object thereof is to provide a polarized DC electromagnetic device and an electromagnetic contactor using the same which can improve assembly efficiency without the increase of the electromagnetic device in size.
To achieve the above object, one configuration of a polarized electromagnet according to the present invention includes a spool around which an excitation coil is wound, a plunger which is inserted through a cylindrical portion of the spool and in which a first armature and a second armature are individually attached to both ends protruding from the cylindrical portion, an outer yoke which surrounds opposite side surfaces of the spool so as to attract the first armature and the second armature, an inner yoke disposed inside the outer yoke so as to attract the second armature, and a permanent magnet disposed between the outer yoke and the inner yoke. The spool includes radially protruding flange portions which are respectively formed at both ends of the cylindrical portion, a coil terminal attachment portion formed in the flange portion on the first armature side, and a coil terminal which is attached to the coil terminal attachment portion.
Furthermore, one configuration of an electromagnetic contactor according to the present invention uses the above polarized DC electromagnetic device as an operating electromagnet which performs an opening-closing operation of a movable contact of a contact mechanism.
According to the present invention, a coil terminal attachment portion is formed in a spool so that a coil terminal is attached to this coil terminal attachment portion, and hence an outer yoke can be attached to the spool before the coil terminal is attached, and the coil terminal can be then attached to the coil terminal attachment portion, whereby it is possible to improve assembly efficiency without the increase of a polarized DC electromagnetic device in size.
Furthermore, regarding the configuration of an electromagnetic contactor, it is also possible to improve assembly efficiency without a size increase by using the polarized DC electromagnetic device which is improved in assembly efficiency without a size increase.
One embodiment of the present invention will now be described with reference to the drawings.
As illustrated in
The spool 11 is formed by injection molding of an insulating resin material such as a thermosetting resin material. As illustrated in
Furthermore, at four corners of the front end face of the flange portion 13a, there are formed L-shaped support portions 13c which support corner portions on the sides of constricted portions 36 of opposite plate portions 34 of the outer yoke 31 that will be described later. An upwardly protruding coil terminal attachment portion 15 is integrally formed in the flange portion 13a. A separately formed coil terminal 17 is attached to the coil terminal attachment portion 15.
The coil terminal attachment portion 15 includes, for example, on the upper side of the flange portion 13a, a pair of support pieces 15a and 15b protrusively formed across a space through which the constricted portion 36 of the outer yoke 31 that will be described later can be inserted. As illustrated in
Electrically conductive coupling portions 16a and 16b which serve as binding terminals are attached to the outer side surfaces of the support pieces 15a and 15b. Each of the electrically conductive coupling portions 16a and 16b is made of a spring material. As illustrated in
The coil terminal 17 is injection-molded by an insulating resin material such as a thermosetting resin material, and electrically conductive coil terminal plates 18a and 18b are attached to the coil terminal 17.
As illustrated in
As illustrated in and
As illustrated in
In the front side support plate portions 17f, engaging projecting portions 17j and 17k which are engaged with the semispherical engaging projections 15c and 15d of the coil terminal attachment portion 15 are formed at upper and lower positions with a back-surface given space on the rear surface side. Support portions 17m which support the capacitor connection plate portions 18e of the coil terminal plates 18a and 18b so that the capacitor connection plate portions 18e are exposed forward are formed on the front surface side of the front side support plate portions 17f.
As illustrated in
Therefore, the coil terminal plates 18a and 18b are supported so that the external power source connection portions 18c protrude upward on the base plate 17a, the contact plate portions 18d are exposed in the fit portions 17d and 17e, and the capacitor connection plate portions 18e are exposed forward in the support plate portions 17f of the fit portions 17d and 17e. A capacitor 19 is electrically and mechanically connected, for example, by soldering between the capacitor connection plate portions 18e of the coil terminal plates 18a and 18b. This prevents the coil terminal plates 18a and 18b from coming off the base plate 17a.
As illustrated in
At this time, the support plate portions 17g of the fit portions 17d and 17e contact the back surfaces of the pair of support pieces 15a and 15b, and the engaging projecting portions 17j and 17k formed on the back surface side of the fit portions 17d and 17e are fitted in the semispherical engaging projections 15c and 15d formed on the front surface side of the pair of support pieces 15a and 15b. At the same time, the elastic contact portions 16f of the electrically conductive coupling portions 16a and 16b attached to the support pieces 15a and 15b elastically contact and are thus electrically connected to the contact plate portions 18d of the coil terminal plates 18a and 18b exposed in the fit portions 17d and 17e.
As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
As illustrated in
Next, an assembly method of the above polarized DC electromagnetic device 10 is described.
First, the second armature 24 is coupled to the back end of the plunger 21. While the vertical plate portions 44 formed in the yoke halves 42A and 42B of the inner yoke 41 holding the permanent magnets 51 are inserted in the slot 13d formed in the flange portion 13b of the spool 11, the plunger 21 is inserted through the central opening 12a of the spool 11 so that the second armature 24 contacts the flange portion 13b.
In this state, before the coil terminal 17 is attached to the coil terminal attachment portion 15, the opposite plate portions 34 on the front end sides of the yoke halves 32A and 32B of the outer yoke 31 are attached to the flange portion 13a of the spool 11. At this time, the coil terminal 17 is not connected to the coil terminal attachment portion 15, and hence the upper yoke half 32A can be easily attached to the flange portion 13a.
That is, the opposite plate portion 34 is fixed to the front end side of the flange portion 13a so that the constricted portion 36 of the upper yoke half 32A is inserted between the pair of support pieces 15a and 15b of the coil terminal attachment portion 15. Since the coil terminal attachment portion 15 is not formed in the lower yoke half 32b, the opposite plate portion 34 is directly fixed to the front end side of the flange portion 13a.
In this state, the central plate portions 33 of the yoke halves 32A and 32B are attracted to the permanent magnets 51 held to the yoke halves 42A and 42B of the inner yoke 41, and then the yoke halves 42A and 42B are held to the spool 11 without moving in the forward-backward direction, as illustrated in
At this time, a magnetic path in which magnetic fluxes from the N-poles of the permanent magnets 51 reach the S-poles of the permanent magnets 51 from the central plate portions 33 of the yoke halves 32A and 32B via the opposite plate portions 34, the plunger 21, the second armature 24, and the inner yoke 41 is formed so that the second armature 24 is attracted to the vertical plate portions 44 of the yoke halves 42A and 42B of the inner yoke 41.
While the inner yoke 41 and the outer yoke 31 are attached to the spool 11 as above, the coil terminal 17 is attached to the coil terminal attachment portion 15 of the spool 11.
This attachment of the coil terminal 17 causes the fit portions 17d and 17e of the coil terminal 17 to contact, from above, the ends of the pair of support pieces 15a and 15b protruding above the coil terminal attachment portion 15. In this state, the coil terminal 17 is lowered so that the pair of support pieces 15a and 15b are inserted between the pair of support plate portions 17f and 17g of the fit portions 17d and 17e facing each other.
The engaging projecting portions 17j and 17k are then engaged with the engaging projections 15c and 15d as illustrated in
At this time, the elastic contact portions 16f of the electrically conductive coupling portions 16a and 16b attached to the pair of support pieces 15a and 15b of the coil terminal attachment portion 15 elastically contact and are thus electrically connected to the contact plate portions 18d of the coil terminal plates 18a and 18b exposed in the fit portions 17d and 17e of the coil terminal 17.
Next, an operation in a first embodiment is described.
First, an external DC power source is connected to the external power source connection portions 18c of the coil terminal plates 18a and 18b in the coil terminal 17 of the polarized DC electromagnetic device 10 via a switch that is not illustrated. In this state, it is considered that the switch is off and that no DC electric power is supplied to the coil terminal 17 and the excitation coil 14 is in an electrically nonconductive state.
In this state, the second armature 24 is urged toward the flange portion 13b of the spool 11 by a return spring 55 illustrated by a chain line in
Consequently, a magnetic path in which the magnetic fluxes of the permanent magnets 51 are transmitted to the front-end-side opposite plate portions 34 from the central plate portions 33 of the yoke halves 32A and 32B of the outer yoke 31, pass through the plunger 21 from the opposite plate portions 34, and reach the permanent magnets 51 from the second armature 24 through the vertical plate portion 44 and the horizontal plate portion 43 of the inner yoke 41 is formed so that the second armature 24 is attracted to the vertical plate portions 44 of the yoke halves 42A and 42B of the inner yoke 41.
Thus, as illustrated in
When the switch is turned on from this non-excitation position to supply DC electric power to the external power source connection portions 18c in the coil terminal plates 18a and 18b of the coil terminal 17 so that the excitation coil 14 is electrically conducted, the excitation coil 14 is excited in a polarity reverse to that of the permanent magnet 51. As a result, a magnetic flux flows in the plunger 21 from its lower end side to its upper end side. This magnetic flux flows from the upper opposite plate portion 34 of each of the yoke halves 32A and 32B of the outer yoke 31 close to the upper end side of the plunger 21 to the lower opposite plate portion 35 through the central plate portion 33.
Thus, attraction force works between the first armature 23 and the second armature 24 formed in the plunger 21 and the front and back opposite plate portions 34 and 35 in the yoke halves 32A and 32B of the outer yoke 31. At the same time, repulsion is generated between the lower second armature 24 and the opposite plate portion 35 of each of the yoke halves 42A and 42B of the inner yoke 41.
Thus, the plunger 21 moves backward against the return spring 55 to an excitation position where the first armature 23 and the second armature 24 are attracted to the opposite plate portion 35 side of each of the yoke halves 32A and 32B of the outer yoke 31.
In this way, when the excitation coil 14 is brought into the electrically conducted state and thus brought into an excited state, a magnetic flux running from the back side to the front side flows through the plunger 21. However, since low magnetic resistance of each of the yoke halves 32A and 32B of the outer yoke 31 is set, this magnetic flux also flows to the sides of the yoke halves 32A and 32B, and a concentrated magnetic flux which is formed in the plunger 21 is dispersed to the yoke halves 32A and 32B so that the magnetic flux density balance is optimized.
Thus, electromagnetic efficiency is improved, and the number of winding of the excitation coil 16 which is wound around the spool 11 can be reduced when the same operation force is to be obtained by the plunger 21. Therefore, the polarized DC electromagnetic device 10 can be reduced in size, and a configuration to obtain operation force equivalent to that of an alternating-current operation electromagnetic device can be formed into a size equal to that of the alternating-current operation electromagnetic device to achieve a cost reduction.
The area in which the opposite plate portions 34 and 35 of each of the yoke halves 32A and 32B of the outer yoke 31 face the first armature 23 and the second armature 24 of the plunger 21 is set to be larger than that of the central plate portion 33, so that the magnetic resistance is reduced, and the magnetic flux can be satisfactorily transmitted between the yoke halves.
Furthermore, the thickness of the outer yoke 31 is set to about three times the thickness of the inner yoke 41, and the magnetic resistance of the outer yoke 31 is set to be lower than the magnetic resistance of the inner yoke 41. Therefore, it is possible to certainly prevent the magnetic flux having a polarity reverse to that of the permanent magnet 51 from flowing backward through the permanent magnet 51 when the excitation coil 14 is excited.
In addition, the coil terminal 17 which is attached to the coil terminal attachment portion 15 of the spool 11 is separately configured, so that the yoke half 32A which constitutes the outer yoke 31 can be easily attached to the flange portion 13a of the spool 11 before the coil terminal 17 is attached to the coil terminal attachment portion 15, and the polarized DC electromagnetic device 10 can be configured when the coil terminal 17 is attached to the coil terminal attachment portion 15 later.
Thus, the assembly efficiency of the polarized DC electromagnetic device 10 can be improved, and the width of the region of the spool 11 between the coil terminal attachment portion 15 and the coil terminal 17 through which the yoke half 32A is inserted does not need to be increased, and the width when the coil terminal 17 is attached to the coil terminal attachment portion 15 can be smaller. It is therefore possible to improve the assembly efficiency of the polarized DC electromagnetic device 10 and still reduce the maximum height thereof to achieve a size reduction.
Both winding-start and winding-end ends of the excitation coil 14 are bound to the electrically conductive coupling portions 16a and 16b attached to the pair of support pieces 15a and 15b of the coil terminal attachment portion 15.
When the width when the coil terminal 17 is attached to the coil terminal attachment portion 15, the elastic contact portions 16f formed at the ends of the electrically conductive coupling portions 16a and 16b elastically contact the contact plate portions 18d of the coil terminal plates 18a and 18b exposed in the fit portions 17d and 17e of the coil terminal 17. It is thus possible to electrically connect the excitation coil 14 and the coil terminal plates 18a and 18b with ease only by attaching and fitting the coil terminal 17 to the coil terminal attachment portion 15.
Next, a second embodiment in which the polarized DC electromagnetic device 10 mentioned above is applied to an electromagnetic contactor according to the present invention is described with reference to the
As illustrated in
The polarized DC electromagnetic device 10 described in the above first embodiment is internally attached to the first frame 61A as illustrated in
As illustrated in
A contact mechanism 64 which is turned on and off and driven by the polarized DC electromagnetic device 10 is internally attached to the second frame 61B.
As illustrated in
As illustrated in
On the other hand, as illustrated in
The curved plate portions 67b and 67c of the coupling spring 67 fixed to the upper surface of the first armature 23 are then inserted into the spring housing portions 66c and 66d of the contact support 66, whereby the plunger 21 and the contact support 66 are coupled to each other.
Next, an operation in the above second embodiment is described. While the excitation coil 14 of the polarized DC electromagnetic device 10 is in the electrically nonconductive state and the plunger 21 is at the non-excitation position, the contact support 66 abuts on the inner side of the front end of the second frame 61B so that the movable contact 66a is located forward apart from the first fixed contact 65a and the second fixed contact 65b as illustrated in
From this state, the excitation coil 14 of the polarized DC electromagnetic device 10 is electrically conducted and thus brought into the excited state so that the plunger 21 is moved backward, and the contact support 66 that is coupled by the coupling spring 67 is also moved backward at the same time. Thus, the movable contact 66a of each phase contacts the first fixed contact 65a and the second fixed contact 65b of each phase so that the main circuit power source side terminal 62a and the main circuit load side terminal 62b are brought into a closed state where these terminals are electrically connected via the movable contact 66a.
In this way, according to the second embodiment, the contact support 66 can be moved by the polarized DC electromagnetic device 10 described above in the first embodiment, and the polarized DC electromagnetic device 10 can be as small-sized as a normal alternating-current operation electromagnetic device which generates the same operation force. Hence, it is possible to reduce the height of the first frame 61A which houses this polarized DC electromagnetic device 10.
Therefore, the length of the whole electromagnetic contactor 60 in the forward-backward direction can be reduced, and the height of the polarized DC electromagnetic device 10 up to the end of the coil terminal 17 can be reduced as described above. It is thus possible to reduce the length of the electromagnetic contactor 60 in the forward-backward direction and the upward-downward direction, and reduce the electromagnetic contactor 60 in size.
Moreover, the assembly efficiency of the polarized DC electromagnetic device 10 can be improved, and hence the assembly efficiency of the electromagnetic contactor 60 can also be improved.
10 . . . polarized DC electromagnetic device, 11 . . . spool, 12a . . . central opening, 12 . . . cylindrical portion, 13a and 13b . . . flange portions, 14 . . . excitation coil, 15 . . . coil terminal attachment portion, 15a and 15b . . . support pieces, 16a and 16b . . . electrically conductive coupling portions, 16f . . . elastic contact portion, 17 . . . coil terminal, 17a . . . base plate, 17d and 17e . . . fit portions, 18a and 18b . . . coil terminal plates, 21 . . . plunger, 22 . . . rod-like portion, 23 . . . first armature, 24 . . . second armature, 31 . . . outer yoke, 32A and 32B . . . yoke halves, 33 . . . central plate portion, 34 and 35 . . . opposite plate portions, 41 . . . inner yoke, 42A and 42B . . . yoke halves, 43 . . . horizontal plate portion, 44 . . . vertical plate portion, 51 . . . permanent magnet, 55 . . . return spring, 60 . . . electromagnetic contactor, 61A . . . first frame, 61B . . . second frame, 62a . . . main circuit power source side terminal, 62b . . . main circuit load side terminal, 63a and 63b . . . auxiliary terminals, 66 . . . contact support, 66a . . . movable contact, 66b . . . space portion, 66c and 66d . . . spring housing portions, and 67 . . . coupling spring.
Number | Date | Country | Kind |
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2014-104750 | May 2014 | JP | national |
This application is a continuation application filed under 35 U.S.C. § 111(a), of International Application PCT/JP2015/001948, filed Apr. 7, 2015, and claims foreign priority benefit to Japanese Patent Application No. 2014-104750, filed May 20, 2014, the contents of which are incorporated herein by reference.
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Number | Date | Country | |
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Number | Date | Country | |
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Parent | PCT/JP2015/001948 | Apr 2015 | US |
Child | 15185546 | US |