The present invention relates to an electromagnetic switch including a main contact mechanism having a pair of fixed contacts and a movable contact, and auxiliary contact mechanisms having fixed contacts and movable contacts, and to a contact position regulating method thereof.
In some cases, a main contact mechanism that carries out conduction and interruption of a large current, and an auxiliary contact mechanism linked to the operation of the main contact mechanism, are provided in an electromagnetic switch such as an electromagnetic relay or electromagnetic contactor. An electromagnetic switch described in PTL 1 is known for providing a main contact mechanism and auxiliary contact mechanism in this way. The electromagnetic switch described in PTL 1 is such that a movable contact coupled by a coupling shaft to a movable plunger of an electromagnet unit is disposed between a pair of fixed contacts to be capable of contacting to and separating from the pair of fixed contacts. Further, an auxiliary contact terminal pusher is disposed to face the leading end of the coupling shaft protruding beyond the movable contact, and an auxiliary contact movable terminal is pressed by the auxiliary contact terminal pusher. The auxiliary contact movable terminal is such that the auxiliary contact is in an off-state in a state wherein the auxiliary contact terminal pusher is not being pressed by the coupling shaft, while the auxiliary contact is in an on-state in a state wherein the auxiliary contact terminal pusher is being pressed by the coupling shaft.
PTL 1: U.S. Pat. No. 7,944,333
However, the heretofore known example described in PTL 1 is such that the auxiliary contact mechanism is disposed in the vicinity of the fixed terminals of the main contact mechanism. Because of this, in order to isolate from the main contact mechanism, the contact size, number of contacts, and contact configuration are limited, and there is an unsolved problem in that the interruption limit value of the auxiliary contact mechanism is small, and contact lifespan is short. Also, there is also an unsolved problem in that the movable contact of the auxiliary contact mechanism is of a cantilever spring structure with low rigidity, there is considerable variation in gap dimension, and it is difficult to obtain mirror contact with the main contact mechanism. Furthermore, there is also an unsolved problem in that contact configuration is limited, and it is therefore not possible to meet the demands of various customers.
Therefore, the invention has been made in view of the unsolved problems of the heretofore known example, and has an object of providing an electromagnetic switch, and contact position regulating method thereof, such that there is considerable freedom of auxiliary contact mechanism configuration, and it is possible to reliably obtain mirror contact of a main contact mechanism and auxiliary contact mechanism.
In order to achieve the heretofore described object, a first aspect of an electromagnetic switch according to the invention is such that a main contact housing portion housing a main contact mechanism having a pair of fixed contacts fixedly disposed to maintain a predetermined interval and a movable contact disposed to be capable of contacting to and separating from the pair of fixed contacts in a contact housing case, an auxiliary contact housing portion housing two or more auxiliary contact mechanisms having fixed contacts and movable contacts disposed to be capable of contacting to and separating from the fixed contacts, and an electromagnet unit having a movable plunger individually coupled to move the movable contact of the main contact mechanism and the movable contacts of the auxiliary contact mechanisms, are disposed in series.
According to the first aspect, a main contact housing portion housing a main contact mechanism and an auxiliary contact housing portion housing a plurality of auxiliary contact mechanisms are disposed in series, and movable contacts of the main contact mechanism and auxiliary contact mechanisms are moved by a movable plunger of an electromagnet unit; thus, it is possible to increase the freedom of the auxiliary contact mechanism configuration, and as the movable contacts of the main contact mechanism and auxiliary contact mechanisms are individually coupled to the movable plunger, it is possible to obtain mirror contact of the main contact mechanism and auxiliary contact mechanisms.
Also, a second aspect of the electromagnetic switch according to the invention is such that the main contact housing portion and auxiliary contact housing portion are disposed in series with the auxiliary contact housing portion on the electromagnet unit side.
According to the second aspect, the auxiliary contact housing portion is disposed between the main contact housing portion and electromagnet unit; thus, it is possible to couple the movable contact of each auxiliary contact mechanism to the movable plunger of the electromagnet unit, and thus possible to dispose the plurality of auxiliary contact mechanisms sandwiching the axial direction of the movable plunger.
Also, a third aspect of the electromagnetic switch according to the invention is such that the auxiliary contact mechanism includes a fixed contact holding portion having insertion holes to hold the fixed contacts by insertion and formed separated in a moving direction of the movable contacts and facing in a direction perpendicular to the moving direction of the movable contacts, a movable contact holding portion holding the movable contacts via contact springs, and a coupling shaft coupled to the electromagnet unit movable plunger moving the movable contact holding portion. Further, the movable contact holding portion is supported by the coupling shaft so that the front and back are reversible as seen from the direction perpendicular to the moving direction, and the fixed contacts are disposed in the mutually facing insertion holes of the fixed contact holding portion so as to face from a side opposite to that of the contact springs on a movable contact side of the movable contact holding portion.
According to the third aspect, it is possible to select the disposition of each fixed contact with respect to the fixed contact holding portion in the direction in which the movable contact can move, and as the front and back of the movable contact holding portion are reversible, it is possible to set the contact configuration freely to an a contact or b contact.
Also, a fourth aspect of the electromagnetic switch according to the invention is such that the movable contact holding portion is configured to hold the movable contact with the contact spring on the electromagnet unit side in one end portion, and hold the movable contact with the contact spring on the main contact housing portion side in another end portion.
According to the fourth aspect, by the pressing force of the contact springs with respect to the movable contact being reversed between one end portion and another end portion of the movable contact holding portion, it is possible for one to be an a contact while the other is a b contact. Moreover, by reversing the front and back of the movable contact holding portion, it is possible to simultaneously change an a contact to a b contact and a b contact to an a contact.
Also, a fifth aspect of the electromagnetic switch according to the invention is such that the movable contact holding portion is configured to hold the movable contact with the contact spring on the electromagnet unit side in both end portions.
According to the fifth embodiment, it is possible for the plurality of auxiliary contact mechanisms to be, for example, mutually identical a contacts. Further, by reversing the front and back of the movable contact holding portion, it is possible to change the plurality of contact mechanisms to identical b contacts.
Also, a sixth aspect of the electromagnetic switch according to the invention is such that the movable contact holding portion is configured to hold the movable contact with the contact spring on the main contact housing portion side in both end portions.
According to the sixth embodiment, it is possible for the plurality of auxiliary contact mechanisms to be mutually identical to b contacts. Further, by reversing the front and back of the movable contact holding portion, it is possible to change the plurality of contact mechanisms to identical a contacts.
Also, a seventh aspect of the electromagnetic switch according to the invention is such that the movable plunger has an extension portion extending into the auxiliary contact housing portion, wherein the movable contact holding portion is screwed to the extension portion, and a position of the movable contact holding portion can be regulated in an axial direction.
According to the seventh aspect, it is possible to regulate the axial direction position of the movable contact holding portion with respect to an extension portion of the movable plunger, and thus possible to regulate the positions of the movable contacts of the auxiliary contact mechanisms with respect to the position of the movable contact of the main contact mechanism.
Also, an eighth aspect of the electromagnetic switch according to the invention is such that a rotation prevention member preventing rotation of the movable contact holding portion is disposed in the auxiliary contact housing portion.
According to the eighth aspect, it is possible to prevent the movable contact holding portion screwed to the movable plunger from rotating when the position is being regulated; thus, preventing the relationship of the movable contact and fixed contacts, in which the movable contact and fixed contacts are facing each other, from deviating.
Also, a ninth aspect of the electromagnetic switch according to the invention is such that the coupling shaft is screwed to the movable plunger, and a position of the coupling shaft can be regulated in the axial direction.
According to the ninth aspect, by the coupling shaft being rotated, the coupling shaft can be moved in the axial direction with respect to the movable plunger, and it is thus possible to carry out accurate mirror contact of the main contact mechanism and plurality of auxiliary contact mechanisms.
Also, a tenth aspect of the electromagnetic switch according to the invention is such that the auxiliary contact mechanism is formed of an a contact that is in contact in an engaged state of the main contact mechanism and a b contact that is in contact in a released state of the main contact mechanism.
According to the tenth aspect, it is possible to simultaneously configure auxiliary contact mechanisms having an a contact and b contact of differing contact configurations.
Also, an eleventh aspect of the electromagnetic switch according to the invention is such that the auxiliary contact mechanisms are formed of a plurality of a contacts.
According to the eleventh aspect, the auxiliary contact mechanisms can be formed of a plurality of a contacts.
Also, a twelfth aspect of the electromagnetic switch according to the invention is such that the auxiliary contact mechanisms are formed of a plurality of b contacts.
According to the twelfth aspect, the auxiliary contact mechanisms can be formed of a plurality of b contacts.
Also, a first aspect of an electromagnetic switch contact position regulating method according to the invention is such that an auxiliary contact housing portion housing two or more auxiliary contact mechanisms having fixed contacts and movable contacts disposed to be capable of contacting to and separating from the fixed contacts, and an electromagnet unit having a movable plunger coupled via a coupling shaft to the movable contact of the main contact mechanism and the movable contacts of the auxiliary contact mechanisms are disposed in series, and a state wherein a movable contact holding portion holding the movable contacts of the auxiliary contact mechanisms is screwed to the movable plunger and the coupling shaft is screwed to the movable plunger is created. In this state, the electromagnetic switch contact position regulating method includes a step of interposing a wipe amount regulating plate between the movable plunger and auxiliary contact housing portion, the wipe amount regulating plate corresponding to an amount of contact wipe between the fixed contacts and movable contacts of the main contact mechanism and auxiliary contact mechanisms at a released time, a step of turning the movable plunger, so that the fixed contacts and movable contacts of the auxiliary contact mechanisms are contacting each other, a step of turning the coupling shaft, so that the fixed contacts and movable contact of the main contact mechanism are contacting each other, and a step of removing the wipe amount regulating plate.
According to the first aspect, it is possible to individually regulate contact between the movable contact and the pair of fixed contacts of the main contact mechanism and contact between the movable contacts and the fixed contacts of the plurality of auxiliary contact mechanisms, and thus possible to reliably regulate mirror contact of the main contact mechanism and plurality of auxiliary contact mechanisms.
Also, a second aspect of the electromagnetic switch contact position regulating method according to the invention is such that a main contact housing portion housing a main contact mechanism having a pair of fixed contacts fixedly disposed maintaining a predetermined interval and a movable contact disposed to be capable of contacting to and separating from the pair of fixed contacts in a contact housing case, an auxiliary contact housing portion housing two or more auxiliary contact mechanisms having fixed contacts and movable contacts disposed to be contacting to and separating from the fixed contacts, and an electromagnet unit having a movable plunger coupled via a coupling shaft to the movable contact of the main contact mechanism and the movable contacts of the auxiliary contact mechanisms are disposed in series, and a state wherein a movable contact holding portion holding the movable contacts of the auxiliary contact mechanisms is screwed to the movable plunger and the coupling shaft is screwed to the movable plunger is created. In this state, the electromagnetic switch contact position regulating method includes a step of interposing a gap regulating plate between the movable plunger and auxiliary contact housing portion, the gap regulating plate corresponding to the gap between the fixed contacts and movable contacts of the main contact mechanism and auxiliary contact mechanisms at a released time, a step of turning the movable plunger, so that the fixed contacts and movable contacts of the auxiliary contact mechanisms are contacting each other, a step of removing the gap regulating plate and interposing a wipe amount regulating plate corresponding to the amount of contact wipe between the fixed contacts and movable contacts of the main contact mechanism and auxiliary contact mechanisms, a step of turning the coupling shaft, so that the fixed contacts and movable contact of the main contact mechanism are contacting each other, and a step of removing the wipe amount regulating plate.
According to the invention, a main contact housing portion that houses a main contact mechanism, an auxiliary contact housing portion that houses a plurality of auxiliary contact mechanisms, and an electromagnet unit having a movable plunger that individually couples and moves movable contacts of the main contact mechanism and plurality of auxiliary contact mechanisms, are arrayed in series.
Because of this, there is considerable freedom of auxiliary contact mechanism contact configuration, and it is possible to reliably obtain mirror contact of the main contact mechanism and auxiliary contact mechanisms.
Also, according to the electromagnetic switch contact position regulating method, it is possible to regulate the contact positions of the movable contacts of the main contact mechanism and plurality of auxiliary contact mechanisms so that it is possible to reliably carry out mirror contact wherein the contacts with the fixed contacts of the movable contact of the main contact mechanism and movable contacts of the plurality of auxiliary contact mechanisms are carried out simultaneously.
Hereafter, based on the drawings, a description will be given of embodiments of the invention.
The contact device 2 has an arc extinguishing chamber 4 acting as a contact housing case. The arc extinguishing chamber 4 is configured of a bottomed cylindrical tub-form body 4a formed of a ceramic, the lower end of which is opened, and a metal joining member 4b fixed in a hermetic state to the opened end surface. Further, the joining member 4b is fixed in a hermetic state by brazing, welding, or the like, to the upper surface of an upper magnetic yoke 42, to be described hereafter, of the electromagnet unit 3.
The arc extinguishing chamber 4 is divided horizontally by an isolating partition plate 5 fixed so as to close off the lower surface of the tub-form body 4a, wherein the upper portion is a main contact housing portion 6, and the lower portion is an auxiliary contact housing portion 7. The main contact housing portion 6 and auxiliary contact housing portion 7 are disposed in series with the electromagnet unit 3. An insertion hole 5a through which is inserted a coupling shaft 14, to be described hereafter, is formed in a central portion of the partition plate 5.
The main contact housing portion 6 houses in the interior thereof a main contact mechanism 10. The main contact mechanism 10 includes a pair of fixed contacts 11a and 11b made of a conductive metal, for example copper, and a movable contact 12 made of a conductive metal, for example copper, disposed so as to be capable of contacting to and separating from the pair of fixed contacts 11a and 11b.
Through holes 13a and 13b formed maintaining a predetermined interval in a longitudinal direction are provided in the upper surface of the tub-form body 4a, and the pair of fixed contacts 11a and 11b is inserted through the through holes 13a and 13b and fixed in a hermetic state by brazing, welding, or the like.
The upper ends of the pair of fixed contacts 11a and 11b protrude upward from the upper surface of the tub-form body 4a, and are connected to an unshown external connection terminal. The lower ends of the pair of fixed contacts 11a and 11b protrude inward to a predetermined length from the upper surface of the tub-form body 4a.
Also, the movable contact 12 is formed of a flattened cuboid plate portion, as is clear by also referring to
The auxiliary contact housing portion 7 has a fixed contact holding portion 21 shown in
The fixed contact holding portion 21 is disposed on the inner peripheral surface of the joining member 4b, as shown in
Further, a pair of fixed contacts 26a and 26b is inserted into and held in one pair selected from the front side mutually facing contact insertion holes 24a1 and 24b1 and contact insertion holes 24a2 and 24b2, as shown in
In the same way, a pair of fixed contacts 27a and 27b is inserted into and held in one pair selected from the front side mutually facing contact insertion holes 25a1 and 25b1 and contact insertion holes 25a2 and 25b2, as shown in
The movable contact holding portion 22 has a holding plate portion 28, extending in a direction perpendicular to the movable contact 12 of the main contact mechanism 10, disposed around the coupling shaft 14, as shown in
Contact holding holes 31a and 31b are formed in front and back end portion sides in the movable contact holding portion 22, penetrating in a left-right direction, as shown in
Further, a first auxiliary contact mechanism 34A is configured of the fixed contacts 26a and 26b and movable contact 32a, while a second auxiliary contact mechanism 34B is configured of the fixed contacts 27a and 27b and the movable contact 32b. Consequently, the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B are formed in positions of front-back symmetry sandwiching the coupling shaft 14.
Further, when the main contact mechanism 10 is in a released state wherein the movable contact 12 is separated downward from the fixed contacts 11a and 11b maintaining a predetermined gap, the first auxiliary contact mechanism 34A is of an a contact configuration wherein the movable contact 32a is separated from the fixed contacts 26a and 26b maintaining a predetermined gap.
Also, when the main contact mechanism 10 is in a released state, the second auxiliary contact mechanism 34B is of a b contact configuration wherein the movable contact 32b is contacting the fixed contacts 27a and 27b with the contact pressure of the contact spring 33b.
The electromagnet unit 3 has a magnetic yoke 41 of a flattened bottomed cylindrical form, and a disk form upper magnetic yoke 42 that closes off the opened end of the magnetic yoke 41, as shown in
A cylindrical exciting coil 43 is disposed in the interior of the magnetic yoke 41, and a cap 44 formed in a bottomed cylindrical body form of a non-magnetic metal is disposed on the inner peripheral surface of the exciting coil 43.
A flange portion 44a extending outward is formed on the upper end of the cap 44, and the flange portion 44a is fixed in a hermetic state to the lower surface of the upper magnetic yoke 42 by brazing, welding, or the like.
The columnar movable plunger 45 is disposed so as to be movable in an up-down direction in the interior of the cap 44. The coupling shaft 14 is fitted into, and fixed in, an upper central position of the movable plunger 45. Also, the cylindrical body 29 is fixed around the coupling shaft 14 on the upper surface of the movable plunger 45.
Consequently, a sealed space is configured of the main contact housing portion 6, auxiliary contact housing portion 7, and cap 44, and an arc extinguishing gas such as hydrogen gas, nitrogen gas, a mixed gas of hydrogen and nitrogen, air, or SF6 is encapsulated inside the sealed space.
Also, an insertion hole 42a through which are inserted the coupling shaft 14 and cylindrical body 29 is formed in a central portion of the upper magnetic yoke 42.
Next, a description will be given of an operation of the first embodiment.
Herein, it is assumed that the fixed contact 11a of the main contact mechanism 10 is connected via an external connection terminal (not shown) to, for example, a power supply source that supplies a large current, while the fixed contact 11b is connected via an external connection terminal (not shown) to a load.
In this state, the exciting coil 43 in the electromagnet unit 3 is in a non-exciting state, and no exciting force causing the movable plunger 45 to move is being generated in the electromagnet unit 3.
In this state, the movable plunger 45 is urged in a downward direction away from the upper magnetic yoke 42 by the return spring 30, and contacts a bottom portion of the cap 44, as shown in
In the released state of the main contact mechanism 10, the first auxiliary contact mechanism 34A is in an opened contact state wherein the movable contact 32a is separated downward by a predetermined gap from the fixed contacts 26a and 26b, and the fixed contacts 26a and 26b are electrically cut off from each other, as shown in
In contrast, the second auxiliary contact mechanism 34B is in a closed contact state wherein the movable contact 32b is contacting the fixed contacts 27a and 27b due to the contact pressure of the contact spring 33b, as shown in
On energizing the exciting coil 43 of the electromagnet unit 3 in the opened contact state of the main contact mechanism 10, an exciting force is generated in the electromagnet unit 3, and the movable plunger 45 is pressed upward against the return spring 30. In response to this, the movable contact 12 of the main contact mechanism 10 coupled via the coupling shaft 14 to the movable plunger 45 moves upward, and the movable contact 12 contacts the lower surfaces of the fixed contacts 11a and 11b with the contact pressure of the contact spring 17.
Because of this, a large current i of the external power supply source is supplied to the load via an external connection terminal (not shown), the fixed contact 11a, the movable contact 12, the fixed contact 11b, and an external connection terminal (not shown), creating an engaged state.
In the engaged state of the main contact mechanism 10, the first auxiliary contact mechanism 34A is in a closed contact state wherein the movable contact 32a is contacting the fixed contacts 26a and 26b with the contact pressure of the contact spring 33b, while the second auxiliary contact mechanism 34B is in an opened contact state wherein the movable contact 32b is separated downward by a predetermined gap from the fixed contacts 27a and 27b.
When interrupting the supply of current to the load in the closed contact state of the main contact mechanism 10, the energizing of the exciting coil 43 of the electromagnet unit 3 is stopped.
Because of this, there is no longer an exciting force in the electromagnet unit 3 causing the movable plunger 45 to move upward; thus, the movable plunger 45 descends due to the urging force of the return spring 30.
By the movable plunger 45 descending in this way, the movable contact 12 coupled via the coupling shaft 14 is contacting the fixed contacts 11a and 11b until there is no longer any contact pressure from the contact spring 17. Subsequently, an opened contact state wherein the movable contact 12 separates downward from the fixed contacts 11a and 11b is created at the point at which there ceases to be contact pressure from the contact spring 17.
On the opened contact state being created, an arc is generated between the fixed contacts 11a and 11b and movable contact 12. The arc generated is extended by the magnetic force of an unshown arc extinguishing permanent magnet, and extinguished.
In the first embodiment, a description has been given of a case of adopting a 1a1b contact configuration, wherein the first auxiliary contact mechanism 34A is of an a contact configuration and the second auxiliary contact mechanism 34B is of a b contact configuration.
However, the invention is such that it is possible, by disposing the movable contact holding portion 22 with the front and back reversed, and causing the fixed contacts 26a, 26b and 27a, 27b to be inserted into and held in the electromagnet unit 3 side contact insertion holes 24a2, 24b2 and 25a2, 25b2, to change the first auxiliary contact mechanism 34A to a b contact configuration and change the second auxiliary contact mechanism 34B to an a contact configuration.
Furthermore, in order to change the first auxiliary contact mechanism 34A from an a contact configuration to a b contact configuration, firstly, the up-down relationship of the movable contact 32a and contact spring 33a is reversed, putting the contact spring 33a on the electromagnet unit 3 side and the movable contact 32a on the main contact housing portion 6 side. In accordance with this, it is sufficient that the fixed contacts 26a and 26b are inserted into the electromagnet unit 3 side contact insertion holes 25a2 and 25b2. Because of this, the contact configuration of the first auxiliary contact mechanism 34A can be arbitrarily changed to one of an a contact or b contact.
Furthermore, in order to change the second auxiliary contact mechanism 34B from a b contact configuration to an a contact configuration, the up-down relationship of the movable contact 32b and contact spring 33b is reversed, putting the contact spring 33b on the electromagnet unit 3 side and the movable contact 32b on the main contact housing portion 6 side. In accordance with this, it is sufficient that the fixed contacts 27a and 27b are inserted into the main contact housing portion 6 side contact insertion holes 25a1 and 25b1. Because of this, the contact configuration of the second auxiliary contact mechanism 34B can be arbitrarily changed to one of an a contact or b contact.
In this way, according to the first embodiment, the main contact housing portion 6, auxiliary contact housing portion 7, and electromagnet unit 3 are disposed in series in that order. Because of this, the movable contacts 12, 32a, and 32b of the main contact housing portion 6 and auxiliary contact housing portion 7 can be moved by the one movable plunger 45, while reliably segregating the main contact housing portion 6 and auxiliary contact housing portion 7 in the axial direction.
Further, the coupling of the movable contacts 12, 32a, and 32b of the main contact housing portion 6 and auxiliary contact housing portion 7 with the movable plunger 45 is carried out via the individual coupling shaft 14 and cylindrical body 29. Because of this, the gaps between the fixed contacts 11a, 11b and 26a, 26b, 27a, 27b in the main contact mechanism 10 and auxiliary contact mechanisms 34A and 34B and the movable contacts 12 and 32a, 32b can be individually regulated.
Also, the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B can be disposed in parallel in positions of front-back symmetry sandwiching the coupling shaft 14 and cylindrical body 29 in the auxiliary contact housing portion 7. Because of this, the two auxiliary contact mechanisms 34A and 34B can be operated without mutual interference, and it is thus possible to increase the interruption limit.
Furthermore, the main contact housing portion 6 and auxiliary contact housing portion 7 can be separated with the partition plate 5, and it is thus possible to reliably prevent the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B being affected by metal vapor arising when an arc is generated in the main contact mechanism 10. Consequently, it is possible to increase the lifespan of the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B, and thus possible to maintain contact reliability.
Furthermore, the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B are such that an a contact configuration can be changed to a b contact configuration and a b contact configuration changed to an a contact configuration. In order to do this, it is sufficient that the insertion positions of the fixed contacts 26a, 26b and 27a, 27b in the contact insertion holes of the fixed contact holding portion 21 are changed, and that the front and back of the movable contact holding portion 22 are reversed, thus reversing the up-down positional relationship of the movable contacts 32a and 32b with the contact springs 33a and 33b in the movable contact holding portion 22 of the movable contacts 32a and 32b.
Furthermore, an a contact configuration can be adopted for both the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B. In order to do this, it is sufficient that the movable contacts 32a and 32b are disposed on the main contact housing portion 6 side in the movable contact holding portion 22, the contact springs 33a and 33b are disposed and held on the electromagnet unit 3 side, and the fixed contacts 26a, 26b and 27a, 27b are disposed in the main contact housing portion 6 side contact insertion holes 24a1, 24b1 and 25a1, 25b1.
In the same way, a b contact configuration can be adopted for both the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B. In order to do this, it is sufficient that the movable contacts 32a and 32b are disposed on the electromagnet unit 3 side in the movable contact holding portion 22, the contact springs 33a and 33b are disposed and held on the main contact housing portion 6 side, and the fixed contacts 26a, 26b and 27a, 27b are disposed in the electromagnet unit 3 side contact insertion holes 24a2, 24b2 and 25a2, 25b2.
In this way, according to the first embodiment, the contact configurations of the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B can be set to be either an a contact configuration or b contact configuration, and it is thus possible to increase the freedom of the contact configuration considerably in comparison with the heretofore known example.
Next, based on
The second embodiment is such that the gap between the fixed contacts and movable contact of the main contact mechanism and the gaps between the fixed contacts and movable contacts of the auxiliary contact mechanisms can be individually regulated.
That is, the second embodiment is such that, in the configuration of
As configurations other than the heretofore described configurations are the same as in the first embodiment, the same reference signs are given to portions the same as in the first embodiment, and a detailed description thereof will be omitted.
According to the second embodiment, in the same way as the first embodiment, it is possible to dispose the plurality of auxiliary contact mechanisms 34A and 34B in the auxiliary contact housing portion 7, and possible to increase the freedom of the contact configurations of the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B.
Also, according to the second embodiment, the coupling shaft 14 is screwed to the movable plunger 45, and the movable contact holding portion 22 of the auxiliary contact mechanisms 34A and 34B is screwed to the extension portion 53 of the movable plunger 45.
Consequently, it is possible to arbitrarily regulate the gap between the fixed contacts 11a and 11b of the main contact mechanism 10 and the movable contact 12, and possible to arbitrarily regulate the gaps between the fixed contacts 26a, 26b and 27a, 27b of the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B and the movable contacts 32a and 32b.
Next, based on
With
Firstly, when the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B are of an a contact configuration, a contact wipe amount regulating plate 61 of, for example, a U-form or half-moon form is interposed between the upper magnetic yoke 42 and the upper end of the movable plunger 45 first, before the cap 44 is mounted, as shown in
In this state, by the movable plunger 45 being caused to rotate in a clockwise direction as seen in plan view, the movable contact holding portion 22 rises, and the movable contacts 32a and 32b contact the fixed contacts 26a, 26b and 27a, 27b with a predetermined contact pressure of the contact springs 33a and 33b, as shown in
Next, with the movable plunger 45 in a fixed state, a tool 62 such as a screwdriver is inserted into the internal thread 52 of the movable plunger 45, and the coupling shaft 14 is rotated in a counterclockwise direction as seen in plan view, as shown in
Next, the contact wipe amount regulating plate 61 is removed, thus finishing the gap position regulation of the main contact mechanism 10 and auxiliary contact mechanisms 34A and 34B, as shown in
After the gap position regulation is finished, the cap 44 is fixed in a hermetic state to the lower surface of the upper magnetic yoke 42 so as to enclose the movable plunger 45.
In this way, it is possible to complete regulation of the contact wipe amount of the main contact mechanism 10, and of the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B. Because of this, it is possible to accurately regulate the gaps between the fixed contacts and movable contacts of the main contact mechanism 10 and the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B. Consequently, it is possible to obtain accurate mirror contact of the main contact mechanism. 10 and the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B.
Meanwhile, when the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B are of a b contact configuration, a gap regulating plate 71 of, for example, a U-form or half-moon form, having a thickness the same as a predetermined gap formed between the fixed contacts 26a, 26b and 27a, 27b and the movable contacts 32a and 32b in the b contact configuration, is interposed between the upper magnetic yoke 42 and the upper end of the movable plunger 45 first, before the cap 44 is mounted, as shown in
In this state, by the movable plunger 45 being caused to rotate in a clockwise direction as seen in plan view, the movable contact holding portion 22 rises, bringing the movable contacts 32a and 32b into an initial contact state contacting the fixed contacts 26a, 26b and 27a, 27b, as shown in
Next, the gap regulating plate 71 is pulled out, and the contact wipe amount regulating plate 61 of, for example, a U-form or half-moon form, corresponding to a contact wipe amount representing the amount of movement of the movable contact holding portion 22 from the movable contacts 32a and 32b first contacting the fixed contacts 26a, 26b and 27a, 27b until a completely closed state, is interposed in place of the gap regulating plate 71, as shown in
Next, with the movable plunger 45 in a fixed state, the tool 62, such as a screwdriver, is inserted into the internal thread 52 of the movable plunger 45, and the coupling shaft 14 is rotated in a counterclockwise direction as seen in plan view, because of which the movable contact 12 of the main contact mechanism 10 is brought into an initial contact state contacting the fixed contacts 11a and 11b.
Next, the contact wipe amount regulating plate 61 is removed, thus finishing the contact wipe amount regulation of the main contact mechanism 10 and auxiliary contact mechanisms 34A and 34B, as shown in
After the contact wipe amount regulation is finished, the cap 44 is fixed in a hermetic state to the lower surface of the upper magnetic yoke 42 so as to enclose the movable plunger 45.
In this way, it is possible to complete contact wipe amount regulation and gap regulation of the main contact mechanism 10, and of the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B. Because of this, it is possible to accurately regulate the amount of gap and amount of contact wipe between the fixed contacts and movable contacts of the main contact mechanism 10 and the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B having a b contact configuration. Consequently, it is possible to obtain accurate mirror contact of the main contact mechanism 10 and the first auxiliary contact mechanism 34A and second auxiliary contact mechanism 34B.
Furthermore, in the embodiments, a description has been given of a case wherein the invention is applied to an electromagnetic contactor but, not being limited to this, the invention is also applicable to any electromagnetic switch including an electromagnetic relay or other instrument that electromagnetically carries out a switching operation.
According to the invention, it is possible to provide an electromagnetic switch, and contact position regulating method thereof, such that there is considerable freedom of auxiliary contact mechanism configuration, and it is possible to reliably obtain mirror contact of a main contact mechanism and auxiliary contact mechanisms.
Number | Date | Country | Kind |
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2012-103971 | Apr 2012 | JP | national |
The present application is a continuation application of PCT International Application No. PCT/JP2013/002475 filed Apr. 11, 2013, and claims priority from Japanese Application No. 2012-103971 filed Apr. 27, 2012.
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Number | Date | Country | |
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20150022292 A1 | Jan 2015 | US |
Number | Date | Country | |
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Parent | PCT/JP2013/002475 | Apr 2013 | US |
Child | 14508577 | US |