The present disclosure generally relates to electromagnetic relays and electromagnetic devices and in particular to an electromagnetic relay which opens and closes a contact unit in accordance with excitation/non-excitation of an electromagnet, and an electromagnetic device including the electromagnet.
An electromagnetic relay disclosed in Patent Literature 1 exemplifies a prior art. This electromagnetic relay includes: an armature which is slidably inserted into a coil block with opposite ends thereof protruded therefrom; a pair of yokes placed facing opposite surfaces of the opposite ends of the coil block; and a permanent magnet held between the pair of yokes. Further, the electromagnetic relay includes: a card linked to the armature; a pair of movable springs between which the cart extends; movable contacts fixed to one ends of the movable springs; and fixed contacts placed facing the movable contacts.
In the electromagnetic relay disclosed in Patent Literature 1, an electromagnet block constituted by the coil block, the armature, the pair of yokes, and the permanent magnet, and a contact mechanism unit constituted by the card, the pair of movable springs, the pair of movable contacts, and the pair of fixed contacts are provided upright on one surface side of the base. In this electromagnetic relay, on the one surface side of the base, all of the fixed contacts, the movable contacts, the yokes, and the armature are arranged in one direction (a width direction of the base).
Patent Literature 1: JP 2011-77141 A
An object of the present disclosure would be to propose an electromagnetic relay excellent in workability of assembling operation.
An electromagnetic relay according to one aspect of the present disclosure includes: at least one contact unit; an electromagnet; an armature unit; and a base. The at least one contact unit includes a fixed contact and a movable spring including a movable contact. The electromagnet includes a coil and is excited by a coil current flowing through the coil. The armature unit is movable in accordance with excitation of the electromagnet to allow the movable contact to move between a closed position in contact with the fixed contact and an open position away from the fixed contact. The base holds the contact unit and the electromagnet on a certain surface side. The movable contact is placed between the base and the fixed contact in an arrangement direction in which the base and the electromagnet are arranged. The armature unit includes a press part which causes movement of the movable contact by applying a pressing force to a certain surface facing the fixed contact, of the movable spring.
An electromagnetic device according to one aspect of the present disclosure includes: an electromagnet; and an armature unit. The electromagnet includes a coil and a yoke provided to protrude from the coil. The armature unit includes an armature at least part of which has an area facing the yoke, and a holder holding the armature. The armature moves in a direction in which the area moves toward the yoke or in a direction in which the area moves away from the yoke, when the electromagnet is excited. The holder includes a separator which has electrically insulating properties and separates at least part of the area of the armature facing the yoke from the yoke when the area moves toward the yoke.
An electromagnetic relay according to one aspect of the present disclosure includes: the electromagnetic device; and a contact unit. The contact unit includes a fixed contact, and a movable contact movable in accordance with movement of the armature unit between a closed position in contact with the fixed contact and an open position away from the fixed contact.
An electromagnetic device according to one aspect of the present disclosure includes: an electromagnet; an armature; a permanent magnet; and an auxiliary yoke. The electromagnet includes a coil and a yoke. The permanent magnet includes poles one of which faces the armature. The auxiliary yoke includes a first surface and a second surface. The first surface faces the other of the poles of the permanent magnet and crosses a magnetic pole direction of the permanent magnet. The second surface faces the yoke. The armature moves toward or away from the yoke when the electromagnet is excited. The second surface of the auxiliary yoke faces the yoke in a range of at least part of a movable range of the armature moving in response to the excitation.
An electromagnetic relay according to one aspect of the present disclosure includes: the electromagnetic device; and a contact unit. The contact unit includes a fixed contact, and a movable contact movable in accordance with movement of the armature between a closed position in contact with the fixed contact and an open position away from the fixed contact.
(1) Outline of Embodiment 1
The following embodiment is just one of various embodiments of the present disclosure. The following embodiment may be modified in various ways depending on the design and the like so long as the objects of the present disclosure can be achieved. In addition,
Hereinafter, upward, downward, left, right, forward, and rearward directions of the electromagnetic relay 1 and the electromagnetic device 3 of the present embodiment will be described by defining upward, downward, left, right, forward, and rearward arrows illustrated in
As shown in
It is assumed that the electromagnetic relay 1 of the present embodiment is configured as a so-called safety relay having a normally open contact, which closes a contact when the electromagnet 5 is excited, and a normally closed contact, which closes a contact when the electromagnet 5 is not excited, and capable of detecting occurrence of an abnormality such as contact welding. Therefore, the number of contact units 2 is two. The two contact units 2 are a first contact unit 2A corresponding to the normally open contact and a second contact unit 2B corresponding to the normally closed contact. However, the electromagnetic relay 1 is not limited to a safety relay, and the number of contact units 2 may be one or three or more.
As shown in
The certain surface 40 of the base 4B extends in a plane including the forward and rearward directions and the left and right directions in
The movable contact 26 is placed between the base 4B and the fixed contact 21 in an arrangement direction in which the base 4B and the electromagnet 5 are arranged (the upward and rearward directions in
According to this configuration, for example, the movable contact 26, the fixed contact 21, and the armature unit 6 can be attached to the base 4B in this order from above the base 4B along the arrangement direction in which the base 4B and the electromagnet 5 are arranged (the upward and rearward directions in
As shown in
The armature unit 6 includes an armature 7 at least part of which has an area (second area 72) facing the yoke 52, and a holder 8 holding the armature 7. When the electromagnet 5 is excited, the armature 7 moves in a direction in which the area (second area 72) moves toward the yoke 52 or in a direction in which the area (second area 72) moves away from the yoke 52.
In the present embodiment, the holder 8 has a separator 85 which has electrically-insulating properties and separates at least part of the area (second area 72) of the armature 7 facing the yoke 52 from the yoke 52 when the area moves toward the yoke 52.
According to this configuration, the holder 8 holding the armature 7 also includes the separator 85 functioning as a magnetic gap. Therefore, it is possible to provide the electromagnetic device 3 having a magnetic gap with simplified configuration.
(2) Details of Embodiment 1
(2.1) Overall Configuration
Hereinafter, the electromagnetic relay 1 of the present embodiment will be described in detail with reference to
(2.2) Contact Unit
(2.2.1) Configuration of Contact Unit
As shown in
(2.2.2) First Contact Unit
First, the first contact unit 2A will be described mainly referring to
As shown in
Specifically, the fixed terminal 20 of the first contact unit 2A is formed of electrically conductive material. The fixed terminal 20 includes a fixed contact 21, an upright part 22, an upper wall part 23, and a terminal piece 24. The upright part 22, the upper wall part 23, and the terminal piece 24 are formed by bending a single plate member (such as a copper alloy plate). That is, the upright part 22, the upper wall part 23, and the terminal piece 24 are formed as an integral part.
The upright part 22 is formed in a substantially rectangular plate shape, and is placed so that a thickness direction thereof extends in the forward and rearward directions. The upper wall part 23 is formed in a substantially rectangular plate shape, and protrudes rearward from a right end of an upper part of the upright part 22 (see
In the present embodiment, as an example, the fixed contact 21 is separate from the upper wall part 23 and is fixed by swaging or the like, but may be formed integrally with the upper wall part 23.
The movable spring 25 of the first contact unit 2A is a leaf spring made of an electrically conductive thin plate, and is formed to have a substantially L-shape when viewed in the left and right directions.
As shown in
The lateral piece 251 is formed in a substantially rectangular plate shape elongated in the forward and rearward directions, and is placed so that a thickness direction thereof extends substantially in the upward and downward directions. As shown in
The vertical piece 252 is formed in a substantially rectangular plate shape and protrudes downward from a rear end of the lateral piece 251. The vertical piece 252 is fixed to the support terminal 27 by, for example, swaging and fixing so that the thickness direction thereof extends in the forward and rearward directions.
The protruded piece 253 protrudes leftward from a left edge near the distal end of the lateral piece 251. The protruded piece 253 is formed in a rectangular plate shape, and a thickness direction thereof extends in the upward and downward directions. The protruded piece 253 serves as part with which a second protrusion 802 of a first press part 80A of the holder 8, which will be described later, comes into contact from above.
In the present embodiment, in one example, the first movable contact 26A is separate from the lateral piece 251 and is fixed by swaging or the like, but may be formed integrally with the lateral piece 251.
The support terminal 27 of the first contact unit 2A is configured to support the movable spring 25. The support terminal 27 includes a terminal piece 270 to be led out from the housing 4.
The terminal piece 270 is formed in a strip shape elongated in the upward and downward directions.
In the first contact unit 2A configured as described above, when the electromagnet 5 is in the non-excited state, the certain surface 250 (upper surface) of the movable spring 25 continues to be pressed by the first press part 80A of the holder 8, as shown in
In the first contact unit 2A, when the electromagnet 5 is in the excited state, the pressing force from the first press part 80A of the holder 8 is eliminated as shown in
(2.2.3) Second Contact Unit
Next, the second contact unit 2B will be described mainly referring to
In the present embodiment, the second contact unit 2B has substantially the same configuration as the first contact unit 2A. Therefore, in the following description, in order to simplify the description, common reference numerals are given to common structures to avoid redundant explanations as appropriate.
As shown in
Specifically, the fixed terminal 20 of the second contact unit 2B is formed of electrically conductive material. The fixed terminal 20 includes a fixed contact 21, an upright part 22, an upper wall part 23, and a terminal piece 24. As shown in
The movable spring 25 of the second contact unit 2B is a leaf spring made of an electrically conductive thin plate, and is formed to have a substantially L-shape when viewed in the left and right directions. As shown in
The movable contact 26 of the first contact unit 2A is configured to make contact with the fixed contact 21 at one contact point. It is assumed that the first contact 2A corresponds to a normally open contact and is inserted into an electric path to which a load is connected, for example. Therefore, the first contact unit 2A is configured to reduce a resistance for current as much as possible.
On the other hand, the movable contacts 26 of the second contact unit 2B are configured to make contact with the fixed contact 21 at two contact points. This is because it is assumed that the second contact unit 2B corresponds to a normally closed contact, and is connected to a detection circuit for detecting an abnormality such as contact welding, for example. Therefore, even if a foreign substance or the like adheres to one of the pair of second movable contacts 26B, the other makes contact with the fixed contact 21. Thus, the contact reliability is enhanced, and the detection circuit can more reliably detect an abnormality. Further, the movable contact 26 of the second contact unit 2B may be provided so as to make contact with the fixed contact 21 at one contact point, similarly to the movable contact 26 of the first contact unit 2A.
Also in the second contact unit 2B, similarly to the first contact unit 2A, the pair of second movable contacts 26B are placed to face the fixed contact 21 in the upward and downward directions. A positional relationship between the pair of second movable contacts 26B and the fixed contact 21 is that the pair of second movable contacts 26B is on the lower side and the fixed contact 21 is on the upper side.
In the present embodiment, as one example, the fixed contact 21 of the second contact unit 2B is separate from the upper wall part 23 and is fixed by swaging or the like, but may be formed integrally with the upper wall part 23. The pair of second movable contacts 26B of the second contact unit 2B is separate from the lateral piece 251 and is fixed by swaging or the like, but may be formed integrally with the lateral piece 251.
In the second contact point 2B configured as described above, when the electromagnet 5 is in the excited state, the certain surface 250 (upper surface) of the movable spring 25 continues to be pressed by the second press part 80B of the holder 8 to be described later, as shown in
Further, in the second contact unit 2B, when the electromagnet 5 is in the non-excited state, a pressing force from the second press part 80B of the holder 8 is eliminated as shown in
(2.3) Electromagnetic Device
(2.3.1) Configuration of Electromagnetic Device
As shown in
The rotation axis A1 illustrated by a dashed line in
(2.3.2) Electromagnet
First, the electromagnet 5 will be described mainly with reference to
The yoke 52 is a magnetic material, and forms a magnetic path through which a magnetic flux passes. The yoke 52 is formed in a substantially U-shaped plate shape elongated in the left and right directions as a whole.
The coil 50 is formed by winding an electrically conductive wire around a coil bobbin 51. The coil bobbin 51 is formed of an electrically insulating material such as a synthetic resin material. The coil bobbin 51 is formed in a substantially cylindrical shape elongated in the left and right directions. The coil bobbin 51 is placed to have an axial direction coinciding with the left and right directions. The axial direction of the coil bobbin 51 corresponds to an axial direction A2 of the coil 50 (see
As shown in
The coil bobbin 51 includes holding pedestals 511 which have substantially rectangular plate shapes and are provided at both ends in the left and right directions and below the pair of extended parts 520. Each holding pedestal 511 is formed continuously from a lower edge of the through hole 510 so as to have an upper surface flush with an inner bottom surface of the through hole 510. The holding pedestals 511 preferably support the pair of extended parts 520.
The pair of coil terminals 53 are held by the coil bobbin 51 and connected to the coil 50. Specifically, one of the pair of coil terminals 53 is electrically connected to one end of the electrically conductive wire wound around the coil bobbin 51, and the other of the pair of coil terminals 53 is electrically connected to the other end of the electrically conductive wire. Further, terminal holding blocks 512 which have rectangular parallelepiped shapes and are provided on lower surfaces of front end parts of the holding pedestals 511 of the coil bobbin 51 hold the coil terminals 53, individually.
Each of the coil terminals 53 includes a first terminal piece 531, which is long in the forward and rearward directions and is held by a corresponding terminal holding block 512 which penetrating it in the forward and rearward directions. A rear end of the first terminal piece 531 is bent downward and protrudes from the terminal holding block 512. The electrically conductive wire wound around the coil bobbin 51 is connected to an electrically conductive wire end part exposed from the terminal holding block 512. Each coil terminal 53 further includes a second terminal piece 532 extending downward from a front end of the first terminal piece 531. The second terminal piece 532 is part to be led out from the housing 4 to the outside.
In the electromagnet 5 configured as described above, when a voltage is applied between both ends of the coil 50, that is, to the pair of coil terminals 53, a current (coil current) flows through the coil 50 to excite the electromagnet 5. While the coil current is not flowing, the electromagnet 5 is in the non-excited state.
In the present embodiment, the pair of coil terminals 53 and the yoke 52 are integrally molded with the coil bobbin 51. Therefore, it is excellent in workability of assembling operation of the electromagnet 5 relative to the base 4B of the housing 4.
(2.3.3) Armature Unit
Next, the armature unit 6 will be described mainly with reference to
The armature 7 is, for example, a member made of soft iron. The armature 7 is held by the holder 8. The armature 7 as a whole is formed in a substantially U-shaped plate shape that is long in the left and right directions. Specifically, as shown in
The body piece 73 is accommodated in the holder 8. The body piece 73 has a rectangular plate shape, and is placed to have a thickness direction extending in the upward and downward directions. The pair of leg pieces 70 are formed so as to extend rearward from the both ends of the body piece 73. The pair of leg pieces 70 have rectangular plate shapes, and are placed to have thickness directions extending in the upward and downward directions. A rear end part of each leg piece 70 is placed to protrude from the holder 8. A lower surface of each leg piece 70 is substantially exposed from the holder 8.
The armature 7 is placed to have at least part thereof having an area facing the yoke 52. In the present embodiment, the lower surfaces of the individual leg pieces 70 exposed from the holder 8 are areas facing the yoke 52 (the extended parts 520). Hereinafter, a right leg piece 70 of the pair of leg pieces 70 may be referred to as a first leg piece 70A, and the area facing a right one of the extended parts 520 of the yoke 52 may be referred to as a first area 71 (see
The permanent magnet 9 is formed in a rectangular parallelepiped shape. The permanent magnet 9 is held by the holder 8. The permanent magnet 9 is placed to have opposite polarities in the upward and downward directions different from each other. In the present embodiment, the permanent magnet 9 is placed so that its N pole is directed upward and its S pole is directed downward, as shown in
The holder 8 is formed to be long in the left and right directions, and have a flat substantially rectangular cylindrical shape. The holder 8 is formed of, for example, an electrically insulating material such as a synthetic resin material. The holder 8 is configured to hold both the armature 7 and the permanent magnet 9 integrally. Specifically, the holder 8 includes a first holding block 81 for holding the armature 7, a second holding block 82 for holding the permanent magnet 9, and a pair of press parts 80. The first holding block 81, the second holding block 82, and the pair of press parts 80 are formed as an integral part. The armature 7 and the permanent magnet 9 are in contact with each other inside the holder 8 (see
The first holding block 81 is formed in a flat rectangular cylindrical shape that is long in the left and right directions. As shown in
The first holding block 81 includes first insertion pieces 810 individually protruding downward from left and right ends thereof. The first holding block 81 includes the axle 813 protruding outward (forward and rearward) from a center in the left and right directions of the bottom. A central axis of the axle 813 corresponds to the rotation axis A1 about which the armature unit 6 swings with respect to the electromagnet 5 in response to excitation/non-excitation of the electromagnet 5. In other words, the axle 813 is pivotally supported to allow the armature unit 6 to swing with respect to the base 4B of the housing 4.
Further, the first holding block 81 includes the separator 85 (see
In the present embodiment, as an example, the separator 85 is placed to separate one of the first area 71 and the second area 72 of the armature 7 (second area 72) from the yoke 52. Therefore, manufacture of the armature unit 6 is easier than that of configuration in which both of the first area 71 and the second area 72 are separated from each other.
The separator 85 is placed to separate at least part of the second area 72 of the armature 7 from the yoke 52 when the second area 72 moves toward the yoke 52. In the present embodiment, as an example, the separator 85 is placed to separate a whole of the second area 72 of the armature 7 from the yoke 52 when the second area 72 moves toward the yoke 52. The separator 85 is placed to separate the second area 72 of the armature 7 from the yoke 52 by making contact with at least part of the yoke 52 facing the second area 72 of the armature 7.
In the present embodiment, as an example, the separator 85 is placed only at an outer end (left end) of both ends (left and right ends) of the second area 72 in a radial direction of the rotation axis A1. That is, the separator 85 is placed to separate the second area 72 from the yoke 52 by making contact with the yoke 52 facing the outer end (left end). For this reason, for example, a magnetic gap can be formed with higher accuracy compared to a configuration in which the separator 85 is placed at an inner end (right end) of the both ends of the second area 72 of the armature 7, that is, a configuration in which the separator 85 separates the second area 72 from the yoke 52 by making contact with the yoke 52 facing the inner end (right end). That is, a configuration facilitating separation of the armature 7 from the yoke 52 is adopted.
More specifically, the separator 85 is formed as a protruding piece that protrudes rightward from a left edge of the second opening 812 and extends lengthwise in the forward and rearward directions. In other words, the separator 85 is configured to form a step under the second area 72 of the armature 7.
The separator 85 configured as described above suppresses deterioration of opening characteristic of the electromagnetic relay 1 due to difficulty in separation between the second area 72 of the armature 7 and the left extended part 520 of the yoke 52 caused by residual magnetization when the electromagnet 5 is switched from the excited state to the non-excited state.
The second holding block 82 is integral with the bottom of the first holding block 81. The second holding block 82 is formed in a substantially rectangular box shape. The second holding block 82 accommodates therein and holds the permanent magnet 9. As shown in
The second holding block 82 is placed closer to a left side of the first holding block 81 than the axle 813 of the first holding block 81 is. Therefore, the permanent magnet 9 accommodated in the second holding block 82 is positioned left with respect to the rotation axis A1. Therefore, for example, as compared with a case where the permanent magnet 9 is located at substantially the same position as the rotation axis A1, swinging of the armature unit 6 in response to the excitation/non-excitation of the electromagnet 5 can be performed with higher accuracy through the permanent magnet 9. In addition, for example, as compared with a case where two permanent magnets 9 are provided and the two permanent magnets 9 are arranged in bilateral symmetry with respect to the rotation axis A1, swing of the armature unit 6 can be performed more accurately by using one permanent magnet 9 with the number of parts reduced.
The pair of press parts 80 are provided integrally with the left and right end parts of the first holding block 81. Each press part 80 is part that applies a pressing force to the certain surface 250 of the movable spring 25 to move the movable contact 26. Hereinafter, the press part 80 protruding rightward from the right end part of the first holding block 81 may be referred to as a first press part 80A. The press part 80 protruding leftward from the left end part of the first holding block 81 may be referred to as a second press part 80B.
Each press part 80 is formed in an elongated rectangular parallelepiped shape. As shown in
On the other hand, as shown in
Each press part 80 includes a second insertion piece 804 with a rectangular plate shape at a position spaced apart from the first holding block 81 by a predetermined distance. The second insertion piece 804 is placed to have a thickness direction extending in the left and right directions.
In the armature unit 6 configured as described above, each press part 80 applies a pressing force to a certain surface 250 of a corresponding movable spring 25, thereby moving the movable contact 26 to the open position. In addition, each press part 80 eliminates the pressing force to the certain surface 250 of the corresponding movable spring 25, thereby moving the movable contact 26 to the closed position. In particular, since the armature unit 6 is of the seesaw type, when one of the first press part 80A and the second press part 80B moves toward the certain surface 250 of the corresponding movable spring 25, the other moves away from the certain surface 250 of the corresponding movable spring 25.
In the present embodiment, the armature 7 and the permanent magnet 9 are integrally molded with the holder 8. Therefore, it is excellent in workability of assembling operation regarding the armature unit 6 with respect to the base 4B of the housing 4.
The separator 85 of the present embodiment is provided for not the first area 71 and the second area 72 of the armature 7 both but the second area 72 only. Therefore, a first interval D1 between the first area 71 and the yoke 52 when the first area 71 is in a closest position to the yoke 52 (see
(2.4) Housing
The housing 4 is made of an electrically insulating material such as a synthetic resin material. As shown in
As shown in
Specifically, as shown in
The first accommodation part 401 is positioned at a right end of the certain surface 40 of the base 4B. The second accommodation part 402 is positioned at a left end of the certain surface 40 of the base 4B. The third accommodation part 403 is positioned between the first accommodation part 401 and the second accommodation part 402 on the certain surface 40 of the base 4B. In the third accommodation part 403, the armature unit 6 of the electromagnetic device 3 and the electromagnet 5 of the electromagnetic device 3 are accommodated to be arranged so that the armature unit 6 is on a front side and the electromagnet 5 is on a rear side.
Therefore, the first contact unit 2A accommodated in the first accommodation part 401 and the electromagnet 5 accommodated in the third accommodation part 403 are arranged on a plane (here, on the certain surface 40) intersecting the above-mentioned arrangement direction (the upward and downward directions) on the certain surface 40 side of the base 4B. Similarly, the second contact unit 2B accommodated in the second accommodation part 402 and the electromagnet 5 accommodated in the third accommodation part 403 are arranged on a plane (here, on the certain surface 40) intersecting the above-mentioned arrangement direction (the upward and downward directions) on the certain surface 40 side of the base 4B. Therefore, the electromagnetic relay 1 can be downsized (in particular, decreased in height).
Further, the electromagnet 5 accommodated in the third accommodation part 403 is positioned between the first contact unit 2A and the second contact unit 2B. Therefore, the electromagnetic relay 1 is further downsized (in particular, decreased in height).
In particular, as shown in
Between the first accommodation part 401 and the third accommodation part 403, a first partition 41 having a substantially rectangular plate shape protrudes upright from the certain surface 40 of the base 4B. Between the second accommodation part 402 and the third accommodation part 403, a second partition 42 having a substantially rectangular plate shape protrudes upright from the certain surface 40 of the base 4B. The first partition 41 and the second partition 42 are arranged so that their thickness directions extend along the left and right directions. As shown in
In the third accommodation part 403, a third partition 43 having a substantially rectangular plate shape for separating the electromagnet 5 and the armature unit 6 from each other protrudes upright from the certain surface 40 of the base 4B. The third partition 43 is placed so that its thickness direction extends along the forward and rearward directions. As shown in
As shown in
As shown in
As shown in
As shown in
(3) Explanation of Operation of Embodiment 1
Hereinafter, the operation of the electromagnetic relay 1 according to the present embodiment will be described by referring to
First, a magnetic path during the non-excited state of the electromagnet 5 will be described. A magnetic flux generated from the N pole of the permanent magnet 9 passes through the armature 7 and falls from the right end of the armature 7 to the right extended part 520 of the yoke 52 (see a magnetic path indicated by a dotted arrow B1 in
In the first inclined state, as shown in
When, for example, a switch (not shown) connected in series to the coil 50 is switched from an off state to an on state in a condition where the electromagnet 5 is in the non-excited state, a voltage is applied between the pair of coil terminals 53, and a coil current flows through the coil 50. Then, the electromagnet 5 is excited, and as shown in
In the second inclined state, the second area 72 of the armature 7 is located closer to (the left extended part 520 of) the opposite yoke 52 than in the first inclined state, but is not in contact with the extended part 520. This is because the separator 85 of the holder 8 prevents contact between the second area 72 and the extended part 520 (see
When the switch connected in series to the coil 50 is switched from the on state to the off state in a condition where the electromagnet 5 is in the excited state, the coil current does not flow through the coil 50, and the electromagnet 5 becomes the non-excited state. In this regard, if the separator 85 is not provided and the second area 72 of the armature 7 is in contact with the extended part 520 of the yoke 52 in the second inclined state, the second area 72 is unlikely to be separated from the yoke 52 due to existence of residual magnetization in the yoke 52 even if the coil current does not flow. In this respect, in the present embodiment, since the separator 85 is provided as the magnetic gap, it is possible to suppress difficulty in separating the second area 72 from the yoke 52, and to reduce deterioration of the opening characteristic of the electromagnetic relay 1.
Patent Literature 1 will now be described. According to the electromagnetic relay described in Patent Literature 1, a residual plate made of a non-magnetic stainless steel thin plate as a magnetic gap is fixed to and integrated with a projecting end surface of a yoke attracting an armature. Therefore, it is prevented that the armature and the yoke are unlikely to be separated from each other due to residual magnetization and the open characteristic of the relay is deteriorated. However, in the electromagnetic relay described in Patent Literature 1, to provide the magnetic gap, it is necessary to fix and integrate the residual plate to and with the yoke. Therefore, there is a problem that the number of parts increases, and simplification of the configuration is desired. In contrast, according to the present embodiment, since the separator 85 is provided, it is possible to provide a magnetic gap while simplifying the configuration.
In particular, in the present embodiment, since the holder 8 having electrically insulating properties (for example, made of a synthetic resin) holds the armature 7 and includes the separator 85, it is possible to provide a magnetic gap while simplifying the configuration. In addition, since the holder 8 of the present embodiment holds not only the armature 7 but also the permanent magnet 9, the configuration is further simplified.
Each of the press parts 80 of the present embodiment is configured to cause movement of the movable contact 26 to the open position by applying the pressing force to the certain surface 250 of the corresponding movable spring 25. Therefore, for example, even if welding occurs between the movable contact 26 and the fixed contact 21, they can be separated from each other by the pressing force causing movement to the open position. Therefore, for example, as compared with a configuration in which the movable contact 26 is moved to the closed position by applying a pressing force to the certain surface 250 of the movable spring 25, reliability between the contacts can be enhanced.
Further, each press part 80 of the present embodiment is configured to cause movement of the movable contact 26 to the closed position by eliminating the pressing force to the certain surface 250 of the corresponding movable spring 25. Therefore, for example, even if the movable contact 26 and/or the fixed contact 21 are worn due to aging, the closed state between the contacts can be maintained. Therefore, the reliability between the contacts can be enhanced. That is, for example, even in a configuration in which the movable contact is moved to the closed position by applying a pressing force, the closed state between the contacts can be maintained even when they are worn as long as depth of wear is smaller than a predetermined amount (for example, corresponding to a distance of OT (Over Travel)). However, according to this configuration, a gap may be developed between the contacts when depth of wear exceeds the predetermined amount. However, in the present embodiment, since the movable contact 26 is moved to the closed position by eliminating the pressing force, the closed state between the contacts can be maintained by the elastic restoring force of the movable spring 25 even if depth of wear exceeds the predetermined amount.
(4) Assembly Procedure of Embodiment 1
Hereinafter, an example of the assembly procedure of the electromagnetic relay 1 of the present embodiment will be described with reference to
First, as shown in
Next, the pair of fixed terminals 20 are attached to the base 4B by, for example, press-fit fixing. More specifically, the upright part 22 of the fixed terminal 20 of the first contact unit 2A is inserted (press-fitted) into the first slot 46 of the first accommodation part 401 of the base 4B, and the terminal piece 24 is led out to the outside of the housing 4 from the lead-out opening 460 of the first slot 46. In addition, the upright part 22 of the fixed terminal 20 of the second contact unit 2B is inserted (press-fitted) into the first slot 46 in the second accommodation part 402 of the base 4B, and the terminal piece 24 is led out to the outside of the housing 4 from the lead-out opening 460 of the first slot 46.
Subsequently, as shown in
Then, as shown in
In this regard, a front end and a rear end of the axle 813 of the holder 8 move downward while displacing the front wall 44 and a top end of the third partition 43 to separate the front wall 44 and the top end of the third partition 43 from each other in the forward and rearward directions. In short, the front wall 44 and the top end of the third partition 43 are elastically deformed in the forward direction and the rearward direction, respectively. Thereafter, the front end and the rear end of the axle 813 reach the bearing holes 440 and 430 and are fitted thereinto. Thereby the front wall 44 and the third partition 43 are elastically restored. As a result, the armature unit 6 is attached to the base 4B to be allowed to swing.
In this regard, at the right end of the armature unit 6, the first press part 80A is accommodated in the cutout 410 of the first partition 41, and is positioned to allow a top end of the first press part 80A to face the certain surface 250 of the movable spring 25. The right first insertion piece 810 of the first holding block 81 is inserted into an insertion opening 4031 (see
On the other hand, also at the left end of the armature unit 6, the second press part 80B is accommodated in the cutout 420 of the second partition 42, and is positioned to allow a top end of the second press part 80B to face the certain surface 250 of the movable spring 25. The left first insertion piece 810 of the first holding block 81 is inserted into an insertion opening 4031 (see
Finally, the cover 4A is attached so as to cover, from above, the base 4B to which the contact units 2 and the electromagnetic device 3 are attached, and thus assembly of the electromagnetic relay 1 is completed.
In the electromagnetic relay 1 of the present embodiment, the movable contact 26 is placed between the base 4B and the fixed contact 21 in the arrangement direction in which the base 4B and the electromagnets 5 are arranged (the upward and downward directions in the illustrations). Therefore, as described above, for example, the movable spring 25 including the movable contact 26, the fixed terminal 20 including the fixed contact 21, the electromagnet 5, and the armature unit 6 can be attached to the base 4B in this order from above the base 4B. Therefore, it is excellent in workability of assembling operation. In particular, considering the automation of the assembly of the electromagnetic relay 1, the contact unit 2 and the armature unit 6 can be attached sequentially in the arrangement direction (the upward and downward directions in the illustrations) like the present embodiment. This can improve the productivity of the electromagnetic relay 1.
(5) Variations of Embodiment 1
Several variations are listed below. Hereinafter, the embodiment described above will be referred to as a “basic example”.
In the basic example, the first press part 80A includes two protrusions which are the first protrusion 801 and the second protrusion 802, and is configured to make contact with the movable spring 25 with these protrusions. However, the first press part 80A is not limited to this configuration, but may include a single protrusion like the second press part 80B and be configured to make contact with the movable spring 25 with the protrusion.
In the basic example, as shown in
In the basic example, as shown in
In the basic example, the armature unit 6 is supported on the base 4B to be allowed to swing, by fitting the axle 813 of the holder 8 into the bearing holes 430 and 440 of the base 4B, but may no be limited to this configuration. The holder 8 may be provided with bearing holes, and the base 4B may be provided with an axle to be fitted into the bearing holes of the holder 8.
In the basic example, the separator 85 is configured so separate the entire second area 72 from the yoke 52 while the electromagnet 5 is in the excited state. However, the separator 85 is not limited to this, but may be configured to separate the left end of the second area 72 from the yoke 52 and allow the right end of the second area 72 to be in contact with the yoke 52, for example.
In the basic example, the separator 85 is formed as a protruded piece slightly protruding rightward from the left edge of the second opening 812. However, the separator 85 is not limited to this, but may be formed to cover the entire second area 72, for example.
In the basic example, the separator 85 is placed to correspond only to the second area 72. However, the separator 85 is not limited to this, but may be provided to correspond to the first area 71 additionally. That is, the number of separators 85 is not limited to one.
(1) Outline of Embodiment 2
The following embodiment is just one of various embodiments of the present disclosure. The following embodiment may be modified in various ways depending on the design and the like so long as the objects of the present disclosure can be achieved. In addition,
Hereinafter, upward, downward, left, right, forward, and rearward directions of the electromagnetic device 3X and the electromagnetic relay 1X of the present embodiment will be described by defining upward, downward, left, right, forward, and rearward arrows illustrated in
As shown in
As shown in
As shown in
The electromagnetic relay 1X of the present embodiment includes, for example, the electromagnetic device 3X and two contact units 2. Each contact unit 2 includes a fixed contact 21 and a movable contact 26 movable in accordance with movement of the armature 7 between a closed position in contact with the fixed contact 21 and an open position away from the fixed contact 21.
JP 2005-63940 A discloses an electromagnetic relay. This electromagnetic relay includes a base, a multiple contact mechanism, a card as a movable object for switching contacts, an electromagnet block, a card driving movable block rotatably supported by the base and placed facing the electromagnet block, a cover case, and the like. The movable block includes a block body molded of resin, an iron piece (armature) fitted and fixed to a front surface of the block body, a permanent magnet attracted and fixed to a center of a front surface of the iron piece, a fulcrum axle made of metal, and the like. In response to excitation or non-excitation of the electromagnet block, the iron piece is attracted to and separated from a yoke of the electromagnet block, whereby contact switching is performed. However, in a magnetic circuit formed by the armature, the permanent magnet, and the yoke, magnetic efficiency is likely to decrease with increase in magnetic flux leakage. Therefore, reduction of leakage of the magnetic flux is desired
According to the configuration of the present embodiment, the second surface Y12 of the auxiliary yoke Y1 faces the yoke 52 in the range of at least part of the movable range of the armature 7 moving in response to the excitation of the electromagnet 5. Therefore, a magnetic circuit is constituted by the yoke 52, the second surface Y12 (left side surface) of the auxiliary yoke Y1, the first surface Y11 (the upper surface) of the auxiliary yoke Y1, the magnetic pole surface of the second magnetic pole of the permanent magnet 9, and the magnetic pole surface of the first magnetic pole of the permanent magnet 9. Therefore, for example, as compared with a case where the auxiliary yoke Y1 is not provided (see
It is assumed that the electromagnetic relay 1X of the present embodiment is configured as a so-called safety relay having a normally open contact, which closes a contact when the electromagnet 5 is excited, and a normally closed contact, which closes a contact when the electromagnet 5 is not excited, and capable of detecting the occurrence of abnormalities such as contact welding. Therefore, the number of contact units 2 is two. The two contact units 2 are a first contact unit 2A corresponding to the normally open contact and a second contact unit 2B corresponding to the normally closed contact. However, the electromagnetic relay 1X is not limited to a safety relay, and the number of contact units 2 may be one or three or more.
(2) Details of Embodiment 2
(2.1) Overall Configuration
Hereinafter, the electromagnetic relay 1X of the present embodiment will be described in detail with reference to
(2.2) Contact Unit
(2.2.1) Configuration of Contact Unit
As shown in
(2.2.2) First Contact Unit
First, the first contact unit 2A will be described mainly referring to
As shown in
Specifically, the fixed terminal 20 of the first contact unit 2A is formed of electrically conductive material. The fixed terminal 20 includes a fixed contact 21, an upright part 22, an upper wall part 23, and a terminal piece 24. The upright part 22, the upper wall part 23, and the terminal piece 24 are formed by bending a single plate member (such as a copper alloy plate). That is, the upright part 22, the upper wall part 23, and the terminal piece 24 are formed as an integral part.
The upright part 22 is formed in a substantially rectangular plate shape, and is placed so that a thickness direction thereof extends in the forward and rearward directions. The upper wall part 23 is formed in a substantially rectangular plate shape, and protrudes rearward from a right end of an upper part of the upright part 22. However, the upper wall part 23 is slightly inclined with respect to the horizontal direction. Specifically, in the open position where the first movable contact 26A and the fixed contact 21 are separated from each other, the upper wall part 23 is slightly inclined in a direction away from the movable contact 26 as moving forward. As shown in
In the present embodiment, as an example, the fixed contact 21 is separate from the upper wall part 23 and is fixed by swaging or the like, but may be formed integrally with the upper wall part 23.
The movable spring 25 of the first contact unit 2A is a leaf spring made of an electrically conductive thin plate, and is formed to have a substantially L-shape when viewed in the left and right directions.
As shown in
The lateral piece 251 is formed in a substantially rectangular plate shape elongated in the forward and rearward directions, and is placed so that a thickness direction thereof is slightly inclined with respect to the upward and downward directions. Here, the lateral piece 251 is also slightly inclined with respect to the support terminal 27 in its design shape. In the open position in which the first movable contact 26A and the fixed contact 21 are separated from each other, the lateral piece 251 is slightly inclined in a direction away from the fixed contact 21 as moving forward.
Further, the lateral piece 251 includes a step part 254 in a vicinity of the first movable contact 26A. That is, the lateral piece 251 includes a first part 251A that extends straight forward while tilting downward from the upper end of the support terminal 27, a second part 251B that extends forward while tilting upward once, and a third part 251C that extends forward while tilting downward again. The first part 251A and the third part 251C are inclined substantially in parallel. Further, the third part 251C is inclined in parallel with the upper wall part 23 to which the fixed contact 21 is attached in the closed position in which the first movable contact 26A and the fixed contact 21 are in contact. That is, the step part 254 is formed by a difference in height between the first part 251A and the third part 251C due to the second part 251B. The step part 254 shields the first movable contact 26A from an abrasion powder which may be produced when the first press part 80A of the holder 8 made of synthetic resin makes contact with the movable spring 25 many times, thereby suppressing spread of the abrasion powder.
As shown in
The protruded piece 253 protrudes leftward from a left edge near the distal end of the lateral piece 251 (a distal end of the first part 251A). The protruded piece 253 is formed in a rectangular plate shape, and a thickness direction thereof extends in the upward and downward directions. The protruded piece 253 serves as part with which a second protrusion 802 of a first press part 80A of the holder 8, which will be described later, comes into contact from above.
In the present embodiment, in one example, the first movable contact 26A is separate from the lateral piece 251 and is fixed by swaging or the like, but may be formed integrally with the lateral piece 251.
The support terminal 27 of the first contact unit 2A is configured to support the movable spring 25. The support terminal 27 includes a terminal piece 270 to be led out from the housing 4. The terminal piece 270 is formed in a strip shape elongated in the upward and downward directions.
As shown in
In the first contact unit 2A configured as described above, when the electromagnet 5 is in the non-excited state, the certain surface 250 (upper surface) of the movable spring 25 continues to be pressed by the first press part 80A of the holder 8, as shown in
In the first contact unit 2A, when the electromagnet 5 is in the excited state, the pressing force from the first press part 80A of the holder 8 is eliminated as shown in
(2.2.3) Second Contact Unit
Next, the second contact unit 2B will be described mainly referring to
In the present embodiment, the second contact unit 2B has substantially the same configuration as the first contact unit 2A. Therefore, in the following description, in order to simplify the description, common reference numerals are given to common structures to avoid redundant explanations as appropriate.
As shown in
Specifically, the fixed terminal 20 of the second contact unit 2B is formed of electrically conductive material. The fixed terminal 20 includes a fixed contact 21, an upright part 22, an upper wall part 23, and a terminal piece 24. As shown in
The movable spring 25 of the second contact unit 2B is a leaf spring made of an electrically conductive thin plate, and is formed to have a substantially L-shape when viewed in the left and right directions. As shown in
Here, the movable contact 26 of each of the first contact unit 2A and the second contact unit 2B is configured to make contact with the fixed contact 21 at one contact point. It is assumed that the first contact unit 2A corresponds to a normally open contact and is inserted into an electric path to which a load is connected, for example. Therefore, it is desirable that the first contact unit 2A allows contact at one contact point so as to minimize a resistance for current. However, the movable contact 26B of the second contact unit 2B may be configured to make contact with the fixed contact 21 at two contact points. The second contact unit 2B corresponds to a normally closed contact, and is assumed to be connected to a detection circuit for detecting an abnormality such as contact welding, for example. Therefore, in a case where the number of movable contacts 26B of the second contact unit 2B is set to two, even if a foreign substance or the like adheres to one of a pair of second movable contacts 26B, the other makes contact with the fixed contact 21. Thus, the contact reliability is enhanced, and the detection circuit can more reliably detect an abnormality.
Also in the second contact unit 2B, similarly to the first contact unit 2A, the second movable contact 26B is placed to face the fixed contact 21 in the upward and downward directions. A positional relationship between the second movable contact 26B and the fixed contact 21 is that the second movable contact 26B is on the lower side and the fixed contact 21 is on the upper side.
Also, in the second contact unit 2B, the lateral piece 251 is slightly inclined with respect to the support terminal 27 in its design shape. In the open position in which the second movable contact 26B and the fixed contact 21 are separated from each other, the lateral piece 251 is slightly inclined in a direction away from the fixed contact 21 as moving forward. The lateral piece 251 includes a step part 254 in a vicinity of the second movable contact 26B.
In the present embodiment, as one example, the fixed contact 21 of the second contact unit 2B is separate from the upper wall part 23 and is fixed by swaging or the like, but may be formed integrally with the upper wall part 23. The second movable contact 26B of the second contact unit 2B is separate from the lateral piece 251 and is fixed by swaging or the like, but may be formed integrally with the lateral piece 251.
In the second contact point 2B configured as described above, when the electromagnet 5 is in the excited state, the certain surface 250 (upper surface) of the movable spring 25 continues to be pressed by the second press part 80B of the holder 8 to be described later, as shown in
Further, in the second contact unit 2B, when the electromagnet 5 is in the non-excited state, a pressing force from the second press part 80B of the holder 8 is eliminated as shown in
(2.3) Electromagnetic Device
(2.3.1) Configuration of Electromagnetic Device
As shown in
The rotation axis A1 illustrated by a dashed line in
(2.3.2) Electromagnet
First, the electromagnet 5 will be described mainly with reference to
The yoke 52 is a magnetic material, and forms a magnetic path through which a magnetic flux passes. The yoke 52 is formed in a substantially U-shaped plate shape elongated in the left and right directions as a whole.
The coil 50 is formed by winding an electrically conductive wire around a coil bobbin 51. The coil bobbin 51 is formed of an electrically insulating material such as a synthetic resin material. The coil bobbin 51 is formed in a substantially cylindrical shape elongated in the left and right directions. The coil bobbin 51 is placed to have an axial direction coinciding with the left and right directions. The axial direction of the coil bobbin 51 corresponds to an axial direction A2 of the coil 50 (see
As shown in
The coil bobbin 51 includes holding pedestals 511 which have substantially rectangular plate shapes and are provided at both ends in the left and right directions and below the pair of protruded parts 520. Each holding pedestal 511 is formed continuously from a lower edge of the through hole 510 so as to have an upper surface flush with an inner bottom surface of the through hole 510. The holding pedestals 511 preferably support the pair of protruded parts 520.
The pair of coil terminals 53 are held by the coil bobbin 51 and connected to the coil 50. Specifically, one of the pair of coil terminals 53 is electrically connected to one end of the electrically conductive wire wound around the coil bobbin 51, and the other of the pair of coil terminals 53 is electrically connected to the other end of the electrically conductive wire. Further, a terminal holding blocks 512 which have rectangular parallelepiped shapes and are provided on lower surfaces of front end parts of the holding pedestals 511 of the coil bobbin 51 hold the coil terminals 53, individually.
Each of the coil terminals 53 includes a first terminal piece 531, which is long in the forward and rearward directions and is held by a corresponding terminal holding block 512 which penetrating it in the forward and rearward directions. A rear end of the first terminal piece 531 is bent downward and protrudes from the terminal holding block 512. The electrically conductive wire wound around the coil bobbin 51 is connected to an electrically conductive wire end part exposed from the terminal holding block 512. Each coil terminal 53 further includes a second terminal piece 532 extending downward from a front end of the first terminal piece 531. The second terminal piece 532 is part to be led out from the housing 4 to the outside.
In the electromagnet 5 configured as described above, when a voltage is applied between both ends of the coil 50, that is, to the pair of coil terminals 53, a current (coil current) flows through the coil 50 to excite the electromagnet 5. While the coil current is not flowing, the electromagnet 5 is in the non-excited state.
In the present embodiment, the pair of coil terminals 53 and the yoke 52 are integrally molded with the coil bobbin 51. Therefore, it is excellent in workability of assembling operation of the electromagnet 5 relative to the base 4B of the housing 4.
(2.3.3) Armature Unit
Next, the armature unit 6 will be described mainly with reference to
The armature 7 is, for example, a member made of soft iron. The armature 7 is held by the holder 8. The armature 7 as a whole is formed in a substantially U-shaped plate shape that is long in the left and right directions. Specifically, as shown in
The body piece 73 is accommodated in the holder 8. The body piece 73 has a rectangular plate shape, and is placed to have a thickness direction extending in the upward and downward directions. The pair of leg pieces 70 are formed so as to extend rearward from the both ends of the body piece 73. The pair of leg pieces 70 have rectangular plate shapes, and are placed to have thickness directions extending in the upward and downward directions. A rear end part of each leg piece 70 is placed to protrude from the holder 8. A lower surface of each leg piece 70 is substantially exposed from the holder 8.
The armature 7 is placed to have at least part thereof having an area facing the yoke 52. In the present embodiment, the lower surfaces of the individual leg pieces 70 exposed from the holder 8 are areas facing the yoke 52 (the protruded parts 520). Hereinafter, a right leg piece 70 of the pair of leg pieces 70 may be referred to as a first leg piece 70A, and the area facing a right one of the protruded parts 520 of the yoke 52 may be referred to as a first area 71 (see
The permanent magnet 9 is formed in a rectangular parallelepiped shape which is flat in the upward and downward directions. The permanent magnet 9 is held by the holder 8. The permanent magnet 9 is placed to have opposite polarities in the upward and downward directions different from each other. In the present embodiment, the permanent magnet 9 is placed so that its N pole is directed upward and its S pole is directed downward, as shown in
The auxiliary yoke Y1 is formed in a flat rectangular parallelepiped shape which is thin in the upward and downward directions. The auxiliary yoke Y1 is a plate member formed of electromagnetic soft iron defined in JIS C 2504, for example. The auxiliary yoke Y1 includes a first surface Y11 (upper surface) and a second surface Y12 (left side surface). The first surface Y11 is a surface facing the second magnetic pole surface 92 on the S pole of the permanent magnet 9 and intersecting the magnetic pole direction of the permanent magnet 9. The second surface Y12 is a surface directed to the left protruded part 520 of the yoke 52.
Here, the auxiliary yoke Y1 has substantially the same shape and substantially the same size as the permanent magnet 9. Specifically, a dimensional relationship is defined so that a thickness of the auxiliary yoke Y1 is substantially equal to a thickness of the permanent magnet 9. Further, a dimensional relationship is defined so that the areas of individual upper and lower end surfaces of the auxiliary yoke Y1 are substantially equal to the areas of individual upper and lower end surfaces of the permanent magnet 9.
The auxiliary yoke Y1 is placed below the permanent magnet 9. The auxiliary yoke Y1 is held by the holder 8 together with the permanent magnet 9 so that the upper surface of the auxiliary yoke Y1 is in substantial plane contact with the lower surface of the permanent magnet 9. The auxiliary yoke Y1 and the permanent magnet 9 are arranged to overlap each other so that the auxiliary yoke Y1 is hidden when viewed from above the permanent magnet 9. In short, the permanent magnet 9 is placed to cover the first surface Y11 of the auxiliary yoke Y1. It is preferable that the auxiliary yoke Y1 is fixed to the lower surface of the permanent magnet 9 by an adhesive or the like until the permanent magnet 9 has a magnetic force through a magnetization process of the permanent magnet 9 in manufacturing the armature unit 6.
The holder 8 is formed to be long in the left and right directions and have a flat substantially rectangular cylindrical shape. The holder 8 is formed of, for example, an electrically insulating material such as a synthetic resin material. The holder 8 is configured to hold the armature 7, the permanent magnet 9, and the auxiliary yoke Y integrally. Specifically, the holder 8 includes a first holding block 81 for holding the armature 7, a second holding block 82 for holding the permanent magnet 9 and the auxiliary yoke Y, and a pair of press parts 80. The first holding block 81, the second holding block 82, and the pair of press parts 80 are formed as an integral part. The armature 7 and the permanent magnet 9 are in contact with each other inside the holder 8 (see
The first holding block 81 is formed in a flat rectangular cylindrical shape that is long in the left and right directions. As shown in
The first holding block 81 includes first insertion pieces 810 individually protruding downward from left and right ends thereof. The first holding block 81 includes the axle 813 protruding outward (forward and rearward) from a center in the left and right directions of the bottom. A central axis of the axle 813 corresponds to the rotation axis A1 about which the armature unit 6 swings with respect to the electromagnet 5 in response to excitation/non-excitation of the electromagnet 5. In other words, the axle 813 is pivotally supported to allow the armature unit 6 to swing with respect to the base 4B of the housing 4.
Further, the first holding block 81 includes the separator 85 (see
More specifically, the separator 85 is formed as a protruding piece that protrudes rightward from a left edge of the second opening 812 and extends lengthwise in the forward and rearward directions. In other words, the separator 85 is configured to form a step under the second area 72 of the armature 7.
The separator 85 configured as described above suppresses deterioration of opening characteristic of the electromagnetic relay 1X due to difficulty in separation between the second area 72 of the armature 7 and the left protruded part 520 of the yoke 52 caused by residual magnetization when the electromagnet 5 is switched from the excited state to the non-excited state.
The second holding block 82 is integral with the bottom of the first holding block 81. The second holding block 82 is formed in a substantially rectangular box shape having an open lower surface. The second holding block 82 accommodates therein and holds the permanent magnet 9 and the auxiliary yoke Y1 As shown in
The second holding block 82 includes a plurality of press-fit projections (not shown) on inner surfaces of a left wall and a rear wall thereof, respectively. Each press-fit projection is formed in a rib shape extending along the upward and downward directions. In manufacture of the armature unit 6, the press-fit projection can be in contact with side surfaces of the permanent magnet 9 and the auxiliary yoke Y1 which are inserted into the second holding block 82 from below, thereby achieving press-fit fixing. Therefore, the permanent magnet 9 and the auxiliary yoke Y1 are suppressed from being easily detached from the second holding block 82.
The second holding block 82 includes a window hole 823 penetrating in the forward and rearward directions at a front wall thereof. The window hole 823 has a rectangular opening in a front view. The window hole 823 is positioned in a position to allow a boundary surface where the permanent magnet 9 and the auxiliary yoke Y1 are in contact with each other, to be visible from the side. The window hole 823 allows visual inspection of appearances of the permanent magnet 9 and the auxiliary yoke Y1, for example, in manufacture (or usage) of the armature unit 6 or the electromagnetic device 3X. For example, it is possible to inspect arrangement of the permanent magnet 9 and the auxiliary yoke Y1 in the second holding block 82 and surfaces of members of the permanent magnet 9 and the auxiliary yoke Y1.
The second holding block 82 is placed closer to a left side of the first holding block 81 than the axle 813 of the first holding block 81 is. Therefore, a center of gravity of each of the permanent magnet 9 and the auxiliary yoke Y1 accommodated in the second holding block 82 is positioned left with respect to the rotation axis A1. Therefore, for example, as compared with a case where the center of gravity of each of the permanent magnet 9 and the auxiliary yoke Y1 overlaps the rotation axis A1, swing of the armature unit 6 in response to the excitation/non-excitation of the electromagnet 5 can be performed with higher accuracy by the permanent magnet 9 and the auxiliary yoke Y1. Further, for example, as compared with a case where two sets of the permanent magnet 9 and the auxiliary yoke Y1 are provided and the two sets are arranged in bilateral symmetry with respect to the rotation axis A1, swing of the armature unit 6 can be performed with higher accuracy with the number of parts decreased.
The pair of press parts 80 are provided integrally with the left and right end parts of the first holding block 81. Each press part 80 is part that applies a pressing force to the certain surface 250 of the movable spring 25 to move the movable contact 26. Hereinafter, the press part 80 protruding rightward from the right end part of the first holding block 81 may be referred to as a first press part 80A. The press part 80 protruding leftward from the left end part of the first holding block 81 may be referred to as a second press part 80B.
Each press part 80 is formed in an elongated rectangular parallelepiped shape. As shown in
On the other hand, as shown in
Each press part 80 includes a second insertion piece 804 with a rectangular plate shape at a position spaced apart from the first holding block 81 by a predetermined distance. The second insertion piece 804 is placed to have a thickness direction extending in the left and right directions.
As shown in
Not to prevent contact between the first to third protrusions 801 to 803 and the movable spring 25, a protrusion amount of the L-shaped protrusion 805 is smaller than a protrusion amount of each of these protrusions. Part of the L-shaped protrusion 805 along the front edge is positioned to substantially face to the step part 254 of the movable spring 25. The L-shaped protrusion 805 cooperates with the step part 254 to shield the movable contact 26 from an abrasion powder which may be produced due to operation of the press part 80, thereby suppressing spread of the abrasion powder.
In the armature unit 6 configured as described above, each press part 80 applies a pressing force to a certain surface 250 of a corresponding movable spring 25, thereby moving the movable contact 26 to the open position. In addition, each press part 80 eliminates the pressing force to the certain surface 250 of the corresponding movable spring 25, thereby moving the movable contact 26 to the closed position. In particular, since the armature unit 6 is of the seesaw type, when one of the first press part 80A and the second press part 80B moves toward the certain surface 250 of the corresponding movable spring 25, the other moves away from the certain surface 250 of the corresponding movable spring 25.
Here, in the present embodiment, the auxiliary yoke Y1 is placed to allow the second surface Y12 to face the yoke 52 in a range of at least part of a movable range of the armature 7 moving in response to excitation/non-excitation. The movable range is, for example, defined as a range allowing the armature 7 to rotate (swing) between a position in which the left end of the armature 7 is lifted as shown in
The second surface Y12 of the auxiliary yoke Y1 faces the yoke 52 while the electromagnet 5 is not excited. More specifically, when the left end of the armature 7 is raised to the upper position as shown in
(2.4) Housing
The housing 4 is made of an electrically insulating material such as a synthetic resin material. As shown in
As shown in
Specifically, as shown in
The first accommodation part 401 is positioned at a right end of the certain surface 40 of the base 4B. The second accommodation part 402 is positioned at a left end of the certain surface 40 of the base 4B. The third accommodation part 403 is positioned between the first accommodation part 401 and the second accommodation part 402 on the certain surface 40 of the base 4B. In the third accommodation part 403, the armature unit 6 of the electromagnetic device 3X and the electromagnet 5 of the electromagnetic device 3X are accommodated to be arranged so that the armature unit 6 is on a front side and the electromagnet 5 is on a rear side.
Therefore, the first contact unit 2A accommodated in the first accommodation part 401 and the electromagnet 5 accommodated in the third accommodation part 403 are arranged on a plane intersecting with the upward and downward directions on the certain surface 40 side of the base 4B (here, the certain surface 40). Similarly, the second contact unit 2B accommodated in the second accommodation part 402 and the electromagnet 5 accommodated in the third accommodation part 403 are arranged on a plane intersecting with the upward and downward directions on the certain surface 40 side of the base 4B (here, the certain surface 40). Therefore, the electromagnetic relay 1X can be downsized (in particular, decreased in height).
Further, the electromagnet 5 accommodated in the third accommodation part 403 is positioned between the first contact unit 2A and the second contact unit 2B. Therefore, the electromagnetic relay 1X is further downsized (in particular, decreased in height).
In particular, as shown in
Between the first accommodation part 401 and the third accommodation part 403, a first partition 41 having a substantially rectangular plate shape protrudes upright from the certain surface 40 of the base 4B. Between the second accommodation part 402 and the third accommodation part 403, a second partition 42 having a substantially rectangular plate shape is provided upright from certain surface 40 of the base 4B. The first partition 41 and the second partition 42 are arranged so that their thickness directions extend along the left and right directions. As shown in
In the third accommodation part 403, a third partition 43 having a substantially rectangular plate shape for separating the electromagnet 5 and the armature unit 6 from each other protrudes upright from the certain surface 40 of the base 4B. The third partition 43 is placed so that its thickness direction extends along the forward and rearward directions. As shown in
As shown in
As shown in
The third accommodation part 403 includes lead-out openings (not shown) at both left and right ends slightly in front of the third partition 43. The lead-out opening allow the second terminal pieces 532 of the pair of coil terminals 53 of the electromagnet 5 to be inserted thereinto and to be led out therefrom to the outside of the housing 4.
As shown in
Further, in the present embodiment, similarly to Embodiment 1, the movable contact 26 is placed between the base 4B and the fixed contact 21 in an arrangement direction in which the base 4B and the electromagnet 5 are arranged (the upward and rearward directions in
(3) Explanation of Operation of Embodiment 2
Hereinafter, the operation of the electromagnetic relay 1X according to the present embodiment will be described by referring to
First, a magnetic path formed while the electromagnet 5 is in the non-excited state will be described. A magnetic flux generated from the N pole of the permanent magnet 9 passes through the armature 7 and falls from the right end of the armature 7 to the right protruded part 520 of the yoke 52 (see a magnetic path indicated by a dotted arrow B1 in
As a result, the auxiliary yoke Y1 is attracted to the left protruded part 520 (see a magnetic path indicated by a solid arrow B3 in
In the first inclined state, as shown in
When, for example, a switch (not shown) connected in series to the coil 50 is switched from an off state to an on state in a condition where the electromagnet 5 is in the non-excited state, a voltage is applied between the pair of coil terminals 53, and a coil current flows through the coil 50. Then, the electromagnet 5 is excited, and as shown in
In the second inclined state, the second area 72 of the armature 7 is located closer to (the left protruded part 520 of) the opposite yoke 52 than in the first inclined state, but is not in contact with the protruded part 520. This is because the separator 85 of the holder 8 prevents contact between the second area 72 and the protruded part 520 (see
Now, comparison between
As described above, the present embodiment includes the auxiliary yoke Y1 and therefore can reduce the leakage of the magnetic flux at the other magnetic pole (the S pole in
The permanent magnet 9 is smaller in size than the permanent magnet 9X in the comparative example of
In addition, the permanent magnet 9 and the auxiliary yoke Y1 are located at positions deviated from the rotation axis A1. Therefore, the rotation of the armature 7 in accordance with excitation/non-excitation can be performed with higher accuracy by the permanent magnet 9 and the auxiliary yoke Y1, and the leakage of magnetic flux can be reduced.
(4) Variations of Embodiment 2
Other variations of the above embodiment are listed below. The variations described below can be applied in combination in an appropriate manner. In the following, the above embodiment is also referred to as a “basic example”.
(4.1) Variation 1
In the armature unit 6 of the basic example, the holder 8 is configured to hold the permanent magnet 9 and the auxiliary yoke Y1 by press-fitting from below. However, the configuration of the holder 8 is not limited to the configuration of holding by press-fitting. For example,
The second holding block 82A is formed in a rectangular parallelepiped box shape so as to cover not only the permanent magnet 9 and front, rear, left and right surfaces of the auxiliary yoke Y1 but also a lower surface of the auxiliary yoke Y1. The second holding block 82A includes at its individual four corners window holes 821 exposing the permanent magnet 9 and the auxiliary yoke Y1. The second holding block 82A includes a circular window hole 822 in its lower surface. The window hole 821 is positioned in a position to allow a boundary surface where the permanent magnet 9 and the auxiliary yoke Y1 are in contact with each other, to be visible from the side. The window hole 821 allows visual inspection of appearances of the permanent magnet 9 and the auxiliary yoke Y1, for example, in manufacture (or usage) of the armature unit 6 or the electromagnetic device 3X.
According to this configuration, the permanent magnet 9, the auxiliary yoke Y1, and the holder 8 are formed as an integrally molded product, and therefore the workability of assembling operation of the armature unit 6 is excellent.
The holder 8 of the present variation further includes L-shaped protrusions 805A and 805B having different structures from the L-shaped protrusion 805 for suppressing spread of the abrasion powder, of the holder 8 of the basic example. The L-shaped protrusions 805A and 805B of the present variation are configured to have different protrusion amounts from the lower surface of the press part 80 depending on their parts.
Specifically, the L-shaped protrusion 805A formed on the first press part 80A on the right side has three parts. That is, the right L-shaped protrusion 805A includes a first wall W1 facing the first protrusion 801 in the forward and rearward directions, a second wall W2 facing the second protrusion 802 in the forward and rearward directions, and a third wall W3 corresponding to a right end wall. The protrusion amount of the first wall W1 is slightly smaller than the protrusion amount of the first protrusion 801, for example. On the other hand, the protrusion amounts of the second wall W2 and the third wall W3 are substantially equal to each other, and both are larger than the protrusion amount of the first wall W1. As an example, dimensions in the upward and downward directions of the second wall W2 and the third wall W3 are about three times as large as a dimension in the upward and downward directions of the first wall W1.
On the other hand, the L-shaped protrusion 805B formed on the second press part 80B on the left side includes a fourth wall W4 facing the third projection 803 in the forward and rearward directions, and a fifth wall W5 corresponding to a left end wall. The protrusion amount of the fourth wall W4 is substantially equal to the protrusion amount of the first wall W1, for example. The protrusion amount of the fifth wall W5 is substantially equal to the protrusion amount of each of the second wall W2 and the third wall W3.
In short, the right L-shaped protrusion 805A of this variation includes a recess formed by the first to third walls W1 to W3, and the left L-shaped protrusion 805B includes a recess formed by the fourth wall W4 and the fifth wall W5. The L-shaped protrusions 805A and 805B can more efficiently suppress spread of the abrasion powder produced by the operation of the press part 80 while avoiding contact by the movable spring 25 due to these recesses.
(4.2) Variation 2
In the basic example, the configuration of the electromagnetic relay 1X alone has been described. A plurality of electromagnetic relays 1X may be applied. For example, as shown in
When a plurality of electromagnetic relays 1X are arranged close to each other, a magnetic force of the permanent magnet 9 of each electromagnetic relay 1X may have a considerable effect on the other adjacent electromagnetic relays 1X, in contrast to a case where the electromagnetic relay 1X is used alone. This is considered to be caused by the leakage of the magnetic flux from the permanent magnet 9. In the electromagnetic relay 1B located in the center of the side-by-side arrangement relay system 100B, it is likely to be particularly affected by leakage flux. Specifically, there is a possibility that the attraction force between the permanent magnet 9 and the yoke 52 is reduced and swing of the armature 7 is not properly performed.
On the other hand, as described in the basic example, by providing the respective electromagnetic relays 1X with the auxiliary yokes Y1, it is possible to reduce the leakage magnetic flux. As a result, it is possible to suppress the reduction of the attractive force when the adjacent arrangement as shown in
(4.3) Other Variations
In the basic example, as shown in
In the basic example, the auxiliary yoke Y1 has substantially the same shape and substantially the same size as the permanent magnet 9, but is not particularly limited. For example, a dimensional relationship may be defined so that the thickness of the auxiliary yoke Y1 is different from the thickness of the permanent magnet 9. For example, the auxiliary yoke Y1 may have a doughnut shape having a through hole at its center. Further, a dimensional relationship is defined so that the areas of individual upper and lower end surfaces of the auxiliary yoke Y1 are different from the areas of individual upper and lower end surfaces of the permanent magnet 9. However, considering the efficiently reduction of the leakage magnetic flux and the reduction of the height of the entire electromagnetic device 3X, it is desirable that the auxiliary yoke Y1 has the structure of the basic example.
In the basic example, the permanent magnet 9 is placed to cover the entire area of the first surface Y11 of the auxiliary yoke Y1, but may cover only an area of part of the first surface Y11. However, in consideration of efficiently reducing the leakage magnetic flux, the basic example is desirable.
In the basic example, the second surface Y12 of the auxiliary yoke Y1 is configured to be positioned outside the range facing the yoke 52 while the electromagnet 5 is excited. However, an area of at least part of the second surface Y12 of the auxiliary yoke Y1 may face the yoke 52 not only when the electromagnet 5 is not excited but also when the electromagnet 5 is excited. However, in this case, there is a possibility that the armature 7 is hardly separated from the yoke 52 due to residual magnetization when the excitation is switched to the non-excitation. Therefore the configuration of the basic example is desirable.
In the basic example, the step part 254 for suppressing spread of the abrasion powder in each movable spring 25 has a structure recessed downward with respect to the third part 251C. However, for example, the step part 254 may have a structure protruded upward with respect to the third part 251C.
In the basic example, the first press part 80A includes two protrusions which are the first protrusion 801 and the second protrusion 802, and is configured to make contact with the movable spring 25 with these protrusions. However, the first press part 80A is not limited to this configuration, but may include a single protrusion like the second press part 80B and be configured to make contact with the movable spring 25 with the protrusion.
In the basic example, the armature unit 6 is supported on the base 4B to be allowed to swing, by fitting the axle 813 of the holder 8 into the bearing holes 430 and 440 of the base 4B, but may no be limited to this configuration. The holder 8 may be provided with bearing holes, and the base 4B may be provided with an axle to be fitted into the bearing holes of the holder 8.
As described above, an electromagnetic relay (1) according to a first aspect includes: at least one contact unit (2); an electromagnet (5); an armature unit (6); and a base (4B). The at least one contact unit (2) includes a fixed contact (21) and a movable spring (25) including a movable contact (26). The electromagnet (5) includes a coil (50) and is excited by a coil current flowing through the coil (50). The armature unit (6) is movable in accordance with excitation of the electromagnet (5) to allow the movable contact (26) to move between a closed position in contact with the fixed contact (21) and an open position away from the fixed contact (21). The base (4B) holds the contact unit (2) and the electromagnet (5) on a certain surface (40) side. The movable contact (26) is placed between the base (4B) and the fixed contact (21) in an arrangement direction in which the base (4B) and the electromagnet (5) are arranged. The armature unit (6) includes a press part (80) which causes movement of the movable contact (26) by applying a pressing force to a certain surface (250) facing the fixed contact (21), of the movable spring (25). According to the first aspect, the movable contact (26) is placed between the base (4B) and the fixed contact (21) in the arrangement direction (the upward and downward directions) in which the base (4B) and the electromagnet (5) are arranged. Therefore, the movable contact (26), the fixed contact (21), the electromagnet (5) and the armature unit (6) can be attached to the base (4B) in this order from above the base (4B) along the upward and downward directions, for example. Therefore, it is possible to provide the electromagnetic relay (1) excellent in workability of assembling operation.
Preferably in an electromagnetic relay (1) according to a second aspect would be realized in combination with the first aspect, the contact unit (2) and the electromagnet (5) are arranged in a plane crossing the arrangement direction (the upward and downward directions) on the certain surface (40) side of the base (4B). According to the second aspect, it is possible to provide the electromagnetic relay (1) excellent in workability of assembling operation while being downsized (in particular, decreased in height).
Preferably in an electromagnetic relay (1) according to a third aspect would be realized in combination with the first or second aspect, the press part (80) causes movement of the movable contact (26) to the open position by applying the pressing force to the certain surface (250) of the movable spring (25). According to the third aspect, even if welding occurs between the movable contact (26) and the fixed contact (21), they can be separated from each other by the pressing force causing movement to the open position. Therefore, as compared with a configuration in which the movable contact (26) is moved to the closed position by applying a pressing force thereto, reliability between the contacts can be enhanced.
Preferably in an electromagnetic relay (1) according to a fourth aspect would be realized in combination with the third aspect, the press part (80) causes movement of the movable contact (26) to the closed position by reducing or eliminating the pressing force to the certain surface (250) of the movable spring (25). According to the fourth aspect, it is possible to maintain the closed state between the contacts even if the movable contact (26) and/or the fixed contact (21) are worn due to aging, for example. Therefore, the reliability between the contacts can be enhanced. That is, for example, even in a configuration in which the movable contact is moved to the closed position by applying a pressing force, the closed state between the contacts can be maintained even when they are worn as long as depth of wear is smaller than a predetermined amount, for example, corresponding to a distance of OT (Over Travel). However, a gap may be developed between the contacts when depth of wear exceeds the predetermined amount. However, the movable contact is moved to the closed position by eliminating or reducing the pressing force, the closed state between the contacts can be maintained by the elastic restoring force of the movable spring (25) even if depth of wear exceeds the predetermined amount.
Preferably in an electromagnetic relay (1) according to a fifth aspect would be realized in combination with any one of the first to fourth aspects, the contact unit (2) is placed close to either one of opposite ends of the coil (50) in an axial direction (A2) of the coil (50). According to the fifth aspect, as compared with a case where the contact unit (2) and the coil (50) are arranged along a direction perpendicular to the axial direction (A2), for example, the stroke of the armature unit (6) can be increased with downsizing (in particular decreasing in height) achieved.
Preferably in an electromagnetic relay (1) according to a sixth aspect would be realized in combination with any one of the first to fifth aspects, the armature unit (6) moves the movable contact (26) by swinging about a rotation axis (A1) relative to the base (4B) in accordance with excitation of the electromagnet (5). According to the sixth aspect, it is possible to increase the stroke of the armature unit (6) while realizing downsizing (in particular, decreasing in height).
Preferably an electromagnetic relay (1) according to a seventh aspect would be realized in combination with any one of the first to sixth aspects further includes a plurality of the contact units (2) including two contact units (2) which are a first contact unit (2A) and a second contact unit (2B). Preferably, the armature unit (6) includes two of the press parts (80) which are a first press part (80A) and a second press part (80B). The first press part (80A) causes movement of the movable contact (26) of the first contact unit (2A) by applying the pressing force to the certain surface (250) of the movable spring (25) of the first contact unit (2A). The second press part (80B) causes movement of the movable contact (26) of the second contact unit (2B) by applying the pressing force to the certain surface (250) of the movable spring (25) of the second contact unit (2B). When one of the first press part (80A) and the second press part (80B) moves toward the certain surface (250) of a corresponding movable spring (25), the other of the first press part (80A) and the second press part (80B) moves away from the certain surface (250) of a corresponding movable spring (25). According to the seventh aspect, one of the first contact unit (2A) and the second contact unit (2B) can serve as a normally open contact which closes a contact when the electromagnet (5) is excited, and the other can serve as a normally closed contact which closes a contact when the electromagnet (5) is not excited. Therefore, the electromagnetic relay (1) can be applied as a safety relay capable of detecting occurrence of an abnormality such as contact welding.
Preferably an electromagnetic relay (1) according to an eighth aspect would be realized in combination with any one of the first to seventh aspects further includes a plurality of the contact units (2). Preferably, the electromagnet (5) is placed among the plurality of contact units (2). According to the eighth aspect, it is possible to realize further downsizing (in particular, decreasing in height).
Preferably in an electromagnetic relay (1) according to a ninth aspect would be realized in combination with the eighth aspect, at least two contact units (2) of the plurality of contact units (2) are arranged with the electromagnet (5) in-between. Preferably, the two contact units (2) include a contact unit (2A) which is on one side of the electromagnet (5) in an arrangement direction of the two contact units (2) and includes a normally open contact, and a contact unit (2B) which is on the other side of the electromagnet (5) in the arrangement direction of the two contact units (2) and includes a normally closed contact. According to the ninth aspect, the electromagnetic relay (1) can be applied as a safety relay capable of detecting occurrence of an abnormality such as contact welding.
Configurations according to the second to ninth aspects are not necessary for the electromagnetic relay (1) and thus may be omitted appropriately.
Also as described above, an electromagnetic device (3) according to a tenth aspect includes: an electromagnet (5); and an armature unit (6). The electromagnet (5) includes a coil (50) and a yoke (52) provided to protrude from the coil (50). The armature unit (6) includes an armature (7) at least part of which has an area facing the yoke (52), and a holder (8) holding the armature (7). The armature (7) moves in a direction in which the area moves toward the yoke (52) or in a direction in which the area moves away from the yoke (52), when the electromagnet (5) is excited. The holder (8) includes a separator (85) which has electrically insulating properties and separates at least part of the area of the armature (7) facing the yoke (52) from the yoke (52) when the area moves toward the yoke (52). According to the tenth aspect, the magnetic gap can be provided with the configuration simplified.
Preferably in an electromagnetic device (3) according to an eleventh aspect would be realized in combination with the tenth aspect, the armature unit (6) further includes a permanent magnet (9). Preferably the holder (8) holds the armature (7) and the permanent magnet (9) integrally. According to the eleventh aspect, movement of the armature unit (6) in response to the excitation of the electromagnet (5) can be performed with higher accuracy by the permanent magnet (9). Further, the holder (8) holds both of the armature (7) and the permanent magnet (9) and therefore the configuration can be simplified.
Preferably in an electromagnetic device (3) according to a twelfth aspect would be realized in combination with the eleventh aspect, the armature unit (6) swings about a rotation axis (A1) relative to the electromagnet (5) in accordance with excitation of the electromagnet (5). Preferably the permanent magnet (9) is placed in a position deviated away from the rotation axis (A1). According to the twelfth aspect, swing of the armature unit (6) in response to the excitation of the electromagnet (5) can be performed with higher accuracy by the permanent magnet (9).
Preferably in an electromagnetic device (3) according to a thirteenth aspect would be realized in combination with any one of the tenth to twelfth aspects, the separator (85) is placed to separate only part of the area of the armature (7) from the yoke (52). According to the thirteenth aspect, manufacture of the armature unit (6) can be made easier than that of a configuration separating the entire area from the yoke (52), for example.
Preferably in an electromagnetic device (3) according to a fourteenth aspect would be realized in combination with any one of the tenth to thirteenth aspects, the separator (85) is placed to be in contact with at least part of the yoke (52) facing the area of the armature (7).
According to the fourteenth aspect, it is possible to provide the magnetic gap with the configuration more simplified.
Preferably in an electromagnetic device (3) according to a fifteenth aspect would be realized in combination with any one of the tenth to fourteenth aspects, the armature unit (6) swings about a rotation axis (A1) relative to the electromagnet (5) in accordance with excitation of the electromagnet (5). Preferably the separator (85) is placed to separate an outer end of opposite ends of the area of the armature (7) in a radial direction of the rotation axis (A1) from the yoke (52). According to the fifteenth aspect, the magnetic gap can be made with higher accuracy than a configuration separating an inner end of opposite ends of the area of the armature (7) from the yoke (52), for example. Therefore, separation of the armature (7) from the yoke (52) can be made easier.
Preferably in an electromagnetic device (3) according to a sixteenth aspect would be realized in combination with any one of the tenth to fifteenth aspects, the armature unit (6) swings about a rotation axis (A1) relative to the electromagnet (5) in accordance with excitation of the electromagnet (5). Preferably the armature (7) includes a plurality of the areas facing the yoke (52) including two areas which are a first area (71) and a second area (72). Preferably the first area (71) and the second area (72) are provided to opposite tops of the armature unit (6) extending in opposite directions (left and right directions) moving away from the rotation axis (A1), respectively. Preferably a first interval (D1) between the first area (71) and the yoke (52) when the first area (71) is in a closest position to the yoke (52) and a second interval (D2) between the second area (72) and the yoke (52) when the second area (72) is in a closest position to the yoke (52) are different from each other. According to the sixteenth aspect, control of operation (swing) of the armature (7) can be facilitated.
Preferably in an electromagnetic device (3) according to a seventeenth aspect would be realized in combination with the sixteenth aspect, the separator (85) is placed to separate either one of the first area (71) and the second area (72) of the armature (7) from the yoke (52). According to the seventeenth aspect, manufacture of the armature unit (6) can be made easier than that of a configuration separating both the first area (71) and the second area (72), for example.
Preferably in an electromagnetic device (3) according to an eighteenth aspect would be realized in combination with any one of the tenth to seventeenth aspects, the electromagnet (5) further includes a coil terminal (53). Preferably the coil terminal (53) is held by a coil bobbin (51) of the coil (50) and is connected to the coil (50). Preferably the coil terminal (53) is provided on an opposite side of the yoke (52) from the armature (7) and extends in a direction away from the armature (7). According to the eighteenth aspect, it is possible to downsize the electromagnetic device (3).
An electromagnetic relay (1) according to a nineteenth aspect includes: the electromagnetic device (3) according to any one of the tenth to eighteenth aspects; and a contact unit (2). The contact unit (2) includes a fixed contact (21), and a movable contact (26) movable in accordance with movement of the armature unit (6) between a closed position in contact with the fixed contact (21) and an open position away from the fixed contact (21). According to the nineteenth aspect, it is possible to provide the electromagnetic relay (1) including the electromagnetic device (3) which can be provided with the magnetic gap with the configuration simplified.
Configurations according to the eleventh to eighteenth aspects are not necessary for the electromagnetic device (3) and thus may be omitted appropriately.
Also as described above, an electromagnetic device (3X) according to a twentieth aspect includes: an electromagnet (5); an armature (7); a permanent magnet (9); and an auxiliary yoke (Y1). The electromagnet (5) includes a coil (50) and a yoke (52). The permanent magnet (9) includes poles one of which (one of an S pole and an N pole) faces the armature (7). The auxiliary yoke (Y1) includes a first surface (Y11) and a second surface (Y12). The first surface (Y11) faces the other of the poles (the other of the S pole and the N pole) of the permanent magnet (9) and crosses a magnetic pole direction of the permanent magnet (9). The second surface (Y12) faces the yoke (52). The armature (7) moves toward or away from the yoke (52) when the electromagnet (5) is excited. The second surface (Y12) of the auxiliary yoke (Y1) faces the yoke (52) in a range of at least part of a movable range of the armature (7) moving in response to the excitation. According to the twentieth aspect, it is possible to reduce the leakage flux at the other of the poles of the permanent magnet (9).
Preferably in an electromagnetic device (3X) according to a twenty-first aspect would be realized in combination with the twentieth aspect, the yoke (52) includes a protruded part (520) protruding from one end in an axial direction (A2) of the coil (50) in a direction crossing the axial direction (A2). Preferably the second surface (Y12) of the auxiliary yoke (Y1) faces the protruded part (520) in the range of the at least part. According to the twenty-first aspect, a flow of a magnetic flux between the protruded part (520) and the second surface (Y12) of the auxiliary yoke (Y1) becomes dominant, and therefore it is possible to further reduce the leakage of the magnetic flux.
Preferably in an electromagnetic device (3X) according to a twenty-second aspect would be realized in combination with the twentieth or twenty-first aspect, the armature (7) rotates about a rotation axis (A1) relative to the electromagnet (5) within the movable range in accordance with the excitation. Preferably the permanent magnet (9) is in a position deviated from the rotation axis (A1). According to the twenty-second aspect, rotation (swing) of the armature (7) in response to the excitation of the electromagnet (5) can be performed with higher accuracy through the permanent magnet (9) and the auxiliary yoke (Y1).
Preferably in an electromagnetic device (3X) according to a twenty-third aspect would be realized in combination with the twenty-second aspect, the auxiliary yoke (Y1) is in a position deviated from the rotation axis (A1). According to the twenty-third aspect, rotation (swing) of the armature (7) in response to the excitation of the electromagnet (5) can be performed with higher accuracy through the permanent magnet (9) and the auxiliary yoke (Y1) with the leakage flux reduced.
Preferably an electromagnetic device (3X) according to a twenty-fourth aspect would be realized in combination with any one of the twentieth to twenty-third aspects further includes a holder (8). The holder (8) holds the armature (7), the permanent magnet (9), and the auxiliary yoke (Y1) integrally. According to the twenty-fourth aspect, the permanent magnet (9) and the auxiliary yoke (Y1) can be rotated (swung) integrally with the armature (7) with displacements thereof suppressed.
Preferably in an electromagnetic device (3X) according to a twenty-fifth aspect would be realized in combination with any one of the twentieth to twenty-fourth aspects, the permanent magnet (9) is placed to cover the first surface (Y11) of the auxiliary yoke (Y1). According to the twenty-fifth aspect, it is possible to further efficiently reduce the leakage of the magnetic flux at the other magnetic pole of the permanent magnet (9).
Preferably in an electromagnetic device (3X) according to a twenty-sixth aspect would be realized in combination with any one of the twentieth to twenty-fifth aspects, the second surface (Y12) of the auxiliary yoke (Y1) faces the yoke (52) at least when the electromagnet (5) is not excited. According to the twenty-sixth aspect, it is possible to reduce the leakage of the magnetic flux during non-excitation.
Preferably in an electromagnetic device (3X) according to a twenty-seventh aspect would be realized in combination with any one of the twentieth to twenty-sixth aspects, the second surface (Y12) of the auxiliary yoke (Y1) is outside a range facing the yoke (52) when the electromagnet (5) is in the excitation. According to the twenty-seventh aspect, it is possible to reduce a possibility that the armature (7) is hardly separated from the yoke (52) when the excitation is switched to the non-excitation.
An electromagnetic relay (1X) according to a twenty-eighth aspect includes: the electromagnetic device (3X) according to any one of the twentieth to twenty-seventh aspects; and a contact unit (2). The contact unit (2) includes a fixed contact (21), and a movable contact (26) movable in accordance with movement of the armature (7) between a closed position in contact with the fixed contact (21) and an open position away from the fixed contact (21). According to the twenty-eighth aspect, it is possible to provide the electromagnetic relay (1X) including the electromagnetic device (3X) capable of reducing the leakage flux.
Configurations according to the twenty-first to twenty-seventh aspects are not necessary for the electromagnetic device (3X) and thus may be omitted appropriately.
Number | Date | Country | Kind |
---|---|---|---|
2017-212215 | Nov 2017 | JP | national |
2017-212216 | Nov 2017 | JP | national |
2018-093255 | May 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2018/039682 | 10/25/2018 | WO | 00 |