1. Field of the Invention
The present invention relates to a polarized electromagnetic relay. The present invention also relates to a coil assembly adapted to be used in a polarized electromagnetic relay.
2. Description of the Related Art
A polar or polarized electromagnetic relay, wherein an electromagnet assembly including an electromagnet and a permanent magnet as well as a contact section including a plurality of contact members are insulated from each other and attached to a base, and wherein a force transfer member shiftable under an action of the electromagnet assembly to make the contact members of the contact section open or close is disposed between the electromagnet assembly and the contact section, has been known in the art. For example, Japanese Unexamined Patent Publication (Kokai) No. 58-181227 (JP-A-58-181227) discloses a polarized electromagnetic relay of this type, in which an electromagnet assembly is configured so that a magnetic movable element (referred to as “an armature section” in JP-A-58-181227) including a permanent magnet and a pair of yokes or iron plates, holding the permanent magnet therebetween, linearly shifts in a direction parallel with a center axis of a coil in response to the excitation of the electromagnet. Typically, the electromagnet assembly configured as described above has an advantage that outside dimensions can be effectively reduced in a redial direction of the coil of the electromagnetic relay, in comparison with a configuration in which a magnetic movable element including a permanent magnet linearly shifts in a direction orthogonal to the coil center axis in response to the excitation of an electromagnet.
In the polarized electromagnetic relay disclosed in JP-A-58-181227, two large and small U-shaped yokes are assembled together to hold, between the center areas of the yokes, a permanent magnet in a direction of magnetization of the magnet, so that at longitudinally opposite end regions of the magnetic movable element, end portions of the yokes, on which respective magnetic poles are formed by the magnet, are arranged so as to face to each other. Similarly, an iron core of the electromagnet is a U-shaped member, of which longitudinally opposite ends extend in a radial direction of the coil and protrude outward. At each longitudinal end region of the magnetic movable element, each end portion of the iron core of the electromagnet is inserted into a space between the end portions of a pair of yokes, at which mutually different magnetic poles are formed. The magnetic movable element is integrally incorporated in a force transfer member as a molded component, and when the electromagnet operates under the above described relative disposition, the force transfer member linearly shifts together with the magnetic movable elements, so as to make the contact section open or close.
Further, a polarized electromagnetic relay, wherein an electromagnet includes a bobbin, on which a conductive wire is wound to form a coil, and at least three coil terminals securely supported on the bobbin, the wire of the coil being connected to each of the coil terminals (see, e.g., Japanese Unexamined Patent Publication (Kokai) No. 2005-243367 (JP-A-2005-243367)). In this type of the polarized electromagnetic relay, the coil may constitutes two excitation circuits, each of which includes a terminal pair defined by any two coil terminals of the at least three coil terminals, and thereby an advantage is given, such that an operation mode of the relay can be quickly switched between an operating state (i.e., a make-contact closing state) and a reset state (i.e., a break-contact closing state), and in either state, the contact section can be stably kept in the contact closing state.
In the polarized electromagnetic relay disclosed in JP-A-58-181227, the pair of U-shaped yokes constituting the magnetic movable element have lengths substantially corresponding to an entire length of the U-shaped iron core of the electromagnet, so that the dimension and weight of a movable section including the force transfer member are relatively large, which may influence the response (i.e., operating time) and outside dimensions of the relay. Further, in this configuration, the U-shaped iron core of the electromagnet and the U-shaped yokes of the magnetic movable element cooperate with each other by simultaneously exerting magnetic effects at their longitudinally opposite ends, so that in order to reduce unevenness of operational characteristics, it is necessary to improve the dimensional accuracy of these components, which may increase manufacturing costs.
On the other hand, in the polarized electromagnetic relay in which the electromagnet includes at least three coil terminals as described in JP-A-2005-243367, it is required to safely and accurately perform an automatic winding process for connecting the conductive wire to each coil terminal and thereby forming the coil on the bobbin.
It is an object of the present invention to provide a polarized electromagnetic relay including an electromagnet assembly configured in such a manner that a magnetic movable element including a permanent magnet is linearly shifted due to the excitation of an electromagnet in a direction parallel with a center axis of a coil, wherein the structure and driving configuration of the magnetic movable element can be simplified, so that response (or operating time) can be improved and outside dimensions and manufacturing costs can be effectively reduced.
It is another object of the present invention to provide a polarized electromagnetic relay in which an electromagnet includes at least three coil terminals, wherein an automatic winding process for connecting a wire to each coil terminal and thereby forming a coil on a bobbin can be safely and accurately performed.
It is a further object of the present invention to provide a coil assembly adapted to be used in a polarized electromagnetic relay, wherein an automatic winding process for connecting a wire to each of at least three coil terminals and thereby forming a coil on a bobbin can be safely and accurately performed.
To accomplish the above object, the present invention provides, as one aspect thereof, a polarized electromagnetic relay comprising a base; an electromagnet assembly fitted to the base, the electromagnet assembly comprising an electromagnet, an armature driven by the electromagnets and a permanent magnet carried on the armature, a contact section fitted to the base and insulated from the electromagnet assembly; and a force transfer member disposed between the electromagnet assembly and the contact section, the force transfer member being shiftable under an action of the electromagnet assembly to make the contact section open or close; wherein the electromagnet includes a coil with a center axis, an iron core provided with a shaft portion disposed along the center axis of the coil and a head portion extending outside of the coil and radially outward from one axial end of the shaft portion, and a yoke joined to another axial end of the shaft portion of the iron core and extending outside of the coil, the yoke including a major portion extending generally parallel with the center axis, an outer peripheral region of the head portion of the iron core being opposed to and spaced from a distal end region of the major portion of the yoke; wherein the armature includes first and second electrically conductive plate elements holding the permanent magnet therebetween in a direction of magnetization of the permanent magnet and disposed to orient the direction of magnetization in parallel with the center axis of the coil, the armature being arranged linearly movably in a direction parallel with the center axis in a state where a part of the first electrically conductive plate element is inserted into a space defined between the outer peripheral region of the head portion of the iron core and the distal end region of the major portion of the yoke; and wherein the force transfer member is arranged to linearly shift in a direction parallel with the center axis to make the contact section open or close, while accompanying with a linear movement of the armature driven by the electromagnet in the direction parallel with the center axis.
The present invention also provides, as another aspect thereof, a polarized electromagnetic relay comprising a base; an electromagnet assembly fitted to the base, the electromagnet assembly comprising an electromagnet, an armature driven by the electromagnet, and a permanent magnet carried on the armature; a contact section fitted to the base and insulated from the electromagnet assembly; and a force transfer member disposed between the electromagnet assembly and the contact section, the force transfer member being shiftable under an action of the electromagnet assembly to make the contact section open or close; wherein the electromagnet includes a coil with a center axis, a bobbin on which the coil is wound, and at least three coil terminals securely supported on the bobbin, a conductive wire forming the coil being connected to each of the coil terminals; wherein the coil constitutes two excitation circuits, each excitation circuit including a terminal pair defined by any two of the at least three coil terminals; wherein each of the at least three coil terminals is provided with a tying portion to which the wire is connected and a termination portion defined away from the tying portion, the tying portion and the termination portion being disposed to protrude outside of the bobbin; wherein the bobbin is provided with a first surface defining a side from which the tying portion of one coil terminal of the terminal pair in each of the two excitation circuits protrudes, and a second surface defining another side opposite to the first surface and from which the termination portion of the one coil terminal protrudes; and wherein the conductive wire is provided with a first lead portion extending between the coil and the tying portion of the one coil terminal of the terminal pair, the first lead portion being laid along the first surface of the bobbin, and a second lead portion extending between the coil and the tying portion of another coil terminal of the terminal pair, the second lead portion being laid along the second surface of the bobbin.
The present invention also provides, as a further aspect thereof, a coil assembly used in a polarized electromagnetic relay, the coil assembly comprising a coil with a center axis; a bobbin on which the coil is wound; and at least three coil terminals securely supported on the bobbin, a conductive wire forming the coil being connected to each of the coil terminals; wherein the coil constitutes two excitation circuits, each excitation circuit including a terminal pair defined by any two of the at least three coil terminals; wherein each of the at least three coil terminals is provided with a tying portion to which the wire is connected and a termination portion defined away from the tying portion, the tying portion and the termination portion being disposed to protrude outside of the bobbin; wherein the bobbin is provided with a first surface defining a side from which the tying portion of one coil terminal of the terminal pair in each of the two excitation circuits protrudes, and a second surface defining another side opposite to the first surface and from which the termination portion of the one coil terminal protrudes; and wherein the conductive wire is provided with a first lead portion extending between the coil and the tying portion of the one coil terminal of the terminal pair, the first lead portion being laid along the first surface of the bobbin, and a second lead portion extending between the coil and the tying portion of another coil terminal of the terminal pair, the second lead portion being laid along the second surface of the bobbin.
The above and other objects, features and advantages of the present invention will become more apparent from the following description of preferred embodiments in connection with the accompanying drawings, wherein;
The embodiments of the present invention are described below in detail, with reference to the accompanying drawings. In the drawings, the same or similar components are denoted by common reference numerals.
Referring to the drawings,
As shown in
The base 12 is formed of an electrically insulative resinous molded article, and is provided with, as an integral or unitary structure, a first portion 20 on which the electromagnet assembly 14 is disposed and a second portion 22 on which the contact section 16 is disposed (
The electromagnet assembly 14 includes an electromagnet 26; an armature 28 adapted to be driven by the electromagnet 26; and a permanent magnet 30 carried on the armature 28. As shown in
The iron core 36 is a bar-shaped member made of, e.g., magnetic steel, and is provided with, as an integral or unitary structure, a cylindrical shaft portion 46 disposed along the center axis 34a of the coil 34 and accommodated in the body 40 of the bobbin 32, and a tabular head portion 48 extending outside of the coil 34 and radially outward from one axial end of the shaft portion 46 (
The yoke 38 is an L-shaped plate-like member made of, e.g., magnetic steel, and is fixedly joined to the other axial end 46a of the shaft portion 46 of the iron core 36, at a side opposite to the head portion 48, by, e.g., caulking, so as to form a magnetic path around the coil 34 (
The armature 28 includes first and second electrically conductive plate elements 54, 56 having tabular shapes identical to each other and made of, e.g., magnetic steel. The permanent magnet 30 has a rectangular parallelepiped shape, wherein N and S poles are formed on the opposite surfaces thereof involving the longest edges of parallelepiped. The first and second electrically conductive plate elements 54, 56 are disposed to be opposed to and spaced from each other, and securely hold the permanent magnet 30 therebetween in a direction of magnetization of the permanent magnet 30 (i.e., in a direction of a magnetic field created between the N and S poles as illustrated). The first and second plate elements 54, 56 are arranged to orient the magnetization direction in parallel with the center axis 34a of the coil 34 (
The armature 28 (or the first and second electrically conductive plate elements 54, 56) cooperates with the permanent magnet 30 to constitute a magnetic movable element that moves in response to the excitation of the electromagnet 26. The magnetic movable element is arranged linearly movably in a reciprocating manner in a direction parallel with the coil center axis 34a (shown by an arrow α in
As shown in
The movable contact 58 carried on the movable contact-spring member 60 is adapted to be displaced in a rocking manner at a location above the second portion 22 of the base 12 (
As shown in
While accompanying with the above-described linear movement of the armature 28 driven by the electromagnet 26 in the direction parallel with the center axis 34a, the force transfer member 18 also linearly shifts in a direction parallel with the coil center axis 34a, so as to transfer the motion of the armature 28 to the movable contact-spring member 60 of the contact section 16, and thereby to make the contact section 16 perform an opening or closing operation. In this connection, the movable contact-spring member 60 is configured to elastically bias the movable contact 58 in a direction away from the make stationary contact 62 of the first stationary contact member 64 due to own spring effect of the movable contact-spring member 60 and, in a state where no external force is applied, to urge the movable contact 58 (or the break movable contact element 58b) against the break stationary contact 66 of the second stationary contact member 68 (
Therefore, when the electromagnet 28 does not operate (or is not excited), the armature 28 is placed at a rest position where the lower half part 54a of the first electrically conductive plate element 54 is spaced away from the distal end region 52a of the major portion 52 of the yoke 38 and abuts against the outer peripheral region 48a of the head portion 48 of the iron core 36, under the spring biasing force of the movable contact-spring member 60 transferred through the force transfer member 18. In the rest position, a magnetic attractive force exerted by the permanent magnet 30 acts between the first electrically conductive plate element 54 and the head portion 48 of the iron core 36, so that the contact section 16 is securely retained at a break-contact closing position where the movable contact 58 conductively contacts the break stationary contact 66.
From the rest position, when the electromagnet 26 operates (or is excited) so as to close a make-contact pair, the armature 28 is displaced toward a first operating position where the lower half part 54a of the first electrically conductive plate element 54 abuts against the distal end region 52a of the major portion 52 of the yoke 38 and a lower half part 56a of the second electrically conductive plate element 56 abuts against the outer peripheral region 48a of the head portion 48 of the iron core 36, by synergistic magnetic-attractive force exerted by the electromagnet 26 and the permanent magnet 30 (
If the excitation of the electromagnet is stopped in the first operating position, the armature 28 is retained at the first operating position by the action of the permanent magnet 30, and thus the contact section 16 is also securely retained at the make-contact closing position. Then, if the electromagnet 26 operates (or is excited) so as to close a break-contact pair, the armature 28 is displaced toward a second operating position where the lower half part 54a of the first electrically conductive plate element 54 is spaced away from the distal end region 52a of the major portion 52 of the yoke 38 and abuts against the outer peripheral region 48a of the head portion 48 of the iron core 36, by the magnetic repulsive force between the electromagnet 26 and the permanent magnet 30. During this displacement, the force transfer member 18 also acts to transfer the spring biasing force of the movable contact-spring member 60 of the contact section 16 to the armature 28. In the second operating position, the synergistic magnetic attractive force exerted by the electromagnet 26 and the permanent magnet 30 acts between the first electrically conductive plate element 54 and the iron core head portion 48, so that the contact section 16 is stably and securely retained at the break-contact closing position where the movable contact 58 conductively contacts the break stationary contact 66.
In the polarized electromagnetic relay 10 configured as described above, the electromagnet assembly 14 is configured to allow a magnetic movable element including the armature 28 and the permanent magnet 30 to linearly shift in a direction parallel with the center axis 34a of the coil 34 in response to the actuation of the electromagnet 26, and therefore an advantage is realized by the entire outside dimensions of the relay which can be effectively reduced in a coil radial direction. In addition, the first and second electrically conductive plate elements 54, 56 constituting the armature 28 are configured to hold the permanent magnet 30 therebetween in the magnetization direction thereof and orient the magnetization direction in parallel with the coil center axis 34a, and therefore the structure of the magnetic movable element formed by the armature 28 and the permanent magnet 30 can be simplified and downsized. Furthermore, the electromagnet 26 is configured to use the yoke 38, as a member separate from the iron core 36, capable of defining a desired magnetic circuit outside the coil, so as to easily ensure a space for driving the armature, where the outer peripheral region 48a of the head portion 48 of the iron core 36 of the electromagnet 26 and the distal end region 52a of the major portion 52 of the yoke 38 are opposed to and spaced from each other, at a desired position around the coil, and therefore the flexibility of the relative arrangement of the electromagnet 26 and the armature 28 can be improved. Moreover, the armature 28 is arranged linearly movably in a direction parallel with the coil center axis 34a in a state where the part 54a of the first electrically conductive plate element 54 is inserted into the space for driving the armature, and therefore the operational accuracy of the armature 28 can be ensured mainly by optimizing the shape and dimension of the first electrically conductive plate element 54. As apparent above, according to the polarized electromagnetic relay 10, all of the shifting direction of the magnetic movable element including the armature 28 and the permanent magnet 30, the magnetization direction of the permanent magnet 30, and the moving direction of the force transfer member 18 are arranged in parallel with the coil center axis 34a, so that the structure and driving configuration of the magnetic movable element can be simplified, and therefore the response (or operating time) of the polarized electromagnetic relay 10 can be improved and the outside dimensions and manufacturing cost can be effectively reduced.
Further, in the polarized electromagnetic relay 10 configured as described above, the armature 28 is fixedly joined to the force transfer member 18 in a state where the permanent magnet 30 is held between the first and second electrically conductive plate elements 54, 56, and therefore the force transfer member 18 can efficiently and accurately transfer the linear shifting motion of the armature 28 to the contact section 16. Moreover, the force transfer member 18, having the rectangular profile where the major axis is disposed parallel with the coil center axis 34a, is provided at one longitudinal end thereof with the force application point 72 for the contact section 16 and at the other longitudinal end region (i.e., cavity 74) thereof with the armature 28 secured thereto, and therefore the magnetic movable element including the armature 28 and the permanent magnet 30 can be sufficiently spaced from the contact section 16 so as to significantly reduce electrical and magnetic effects therebetween.
In the polarized electromagnetic relay 10 according to the illustrated embodiment, as shown in
Further, as shown in
The polarized electromagnetic relay 10 further includes a casing 82 secured to the base 12 and accommodating the electromagnet assembly 14, the contact section 16 and the force transfer member 18 (
Further, the bottom wall 86 of the base 12 is provided at a side opposite to the bulge portion 86a with a recess 86c formed by a part of the cylindrical inner circumferential surface 24a of the cylindrical wall 24 (
In the polarized electromagnetic relay 10 according to the illustrated embodiment, the bobbin 32 of the electromagnet 26 is further provided with an extension 88 (
As shown in
In the polarized electromagnetic relay 10 configured as described above, when the electromagnet 26 is assembled, as shown in
While a preferred embodiment of the polarized electromagnetic relay according to the present invention has been described, the present invention is not limited to the above embodiment and other various modifications may be made.
For example,
The electromagnet 96 is configured such that the distal end region 52a of the major portion 52 of the yoke 38 is provided with an annular portion 98 surrounding, through a required gap, a magnetic movable element in which the permanent magnet 30 is held between the first and second electrically conductive plate elements 54, 56 of the armature 28. In this configuration, parts 54a, 54b (
In the electromagnet 100, the major portion 52 of the yoke 38 is disposed close to the force transfer member 18 at one lateral side of the coil 34, and the yoke further includes a secondary portion 102 disposed oppositely to the major portion 52 and close to the base 12 (
In the embodiment and its modifications described above, the distal end region 52a of the major portion 52 of the yoke 36 is provided with a sheared surface 104 resulting from forming the yoke 38 by a stamping process (
In this connection, the coil assembly 110 shown in
The coil assembly 110 includes a coil 112 with a center axis 112a; a bobbin 114 on which the coil 112 is wound; and three coil terminals 118, 120 and 122 securely supported on the bobbin 114, a conductive wire 116 forming the coil 112 being connected to each coil terminal (
The coil 112 constitutes two excitation circuits, each of which includes a terminal pair defined by any two coil terminals of the three coil terminals 118, 120, 122. In the illustrated embodiment, the three coil terminals 118, 120, 122 are generally equidistantly aligned in a direction orthogonal to the coil center axis 112a on the extension 130 of the bobbin 114. As illustrated, a coil power supply 132 is connected in a switchable manner to the first and second coil terminals 118, 120 at opposite ends in an aligning direction as well as the third coil terminal 122 at the center in the aligning direction, so that the first and third coil terminals 118, 122 constitute a terminal pair of one excitation circuit 134a and the second and third coil terminals 120, 122 constitute a terminal pair of the other excitation circuit 134b (
Each of three coil terminals 118, 120, 122 has a tying portion 118a, 120a, 122a, to which the wire 116 is connected, and a termination portion 118b, 120b, 122b defined away from the tying portion 118a, 120a, 122a, wherein the tying portion 118a, 120a, 122a and the termination portion 118b, 120b, 122b are disposed to protrude outside the bobbin 114 (
More specifically, in the illustrated embodiment, the first and second coil terminals 118, 120 are respectively provided at one ends thereof with the tying portions 118a, 120a protruding from the first surface 130a of the extension 130 of the bobbin 114 in a direction generally orthogonal to the coil center axis 112a, and at the other ends thereof with the termination portions 118b, 120b protruding from the second surface 130b of the extension 130 in a direction generally orthogonal to the coil center axis 112a. The first and second coil terminals 118, 120 are disposed on the extension 130 in such a manner that the tying portions 118a, 120a are in parallel with each other and the termination portions 118b, 120b are also in parallel with each other. On the other hand, the third coil terminal 122 is provided at one end thereof with the tying portion 122a protruding from the extension 130 of the bobbin 114 in a direction generally parallel with the coil center axis 112a, and at the other end thereof with the termination portion 122b protruding from the second surface 130b of the extension 130 in a direction generally orthogonal to the coil center axis 112a. The third coil terminal 122 is disposed on the extension 130 in such a manner that the termination portion 122b is in parallel with the termination portions 118b, 120b of the first and second coil terminals 118, 120. Due to this terminal configuration, the automatic winding process as described later and using a known winding machine can be smoothly performed.
The wire 116 of the coil 112 is provided with a pair of predetermined lengths (each referred to as a first lead portion, in this application) 116a, each of which extends between the coil 112 and the tying portion (the tying portions 118a, 120a, in the drawing) of one coil terminal (the first and second coil terminals 118, 120, in the drawing) of the terminal pair of each of two excitation circuits 134a, 134b, and a pair of predetermined lengths (each referred to as a second lead portion, in this application) 116b, each of which extends between the coil 112 and the tying portion (the tying portion 122a, in the drawing) of the other coil terminal (the third coil terminal 122, in the drawing) of the terminal pair. In the coil assembly 110, the wire 116 of the coil 112 is configured so that the first lead portions 116a are laid along the first surface (the first surface 130a of the extension 130, in the drawing) of the bobbin 114 at a side closer to the center axis 112a of the coil 112, and the second lead portions 116b are laid along the second surface (the second surface 130b of the extension 130, in the drawing) of the bobbin 114 at a side away from the coil center axis 112a (
In the coil assembly 110 configured as described above, the pair of the first lead portions 116a and the pair of the second lead portions 116b of the wire 116, extending between the individual coil terminals 118, 120, 122 and the coil 112, are laid respectively along the first and second surfaces 130a, 130b of the extension 130 of the bobbin 114 without intersecting or contacting each other, and therefore it is possible to prevent the first and second lead portions 116a, 116b from causing a wire breakage and/or a layer short due to insulation-coating deterioration, which may otherwise be caused by friction between the wires. Therefore, according to the coil assembly 110, an automatic winding process for connecting the wire 116 to each of three coil terminals 118, 120, 122 and thus forming the coil 112 on the bobbin 114 can be safely and accurately performed. Further, due to the fact that the automatic winding process can be safely and accurately performed, a polarized electromagnetic relay (e.g., the polarized electromagnetic relay 10) including an electromagnet (e.g., the electromagnet 26, 96, 100) incorporating the coil assembly 110 therein possesses excellent reliability.
In the illustrated embodiment, the extension 130 of the bobbin 114 is provided on the first surface 130a with a pair of guide grooves 136 spaced from each other and adjacent to respective areas from which the tying portions 118a, 120a of the first and second coil terminals 118, 120 protrude, and on the second surface 130b with a pair of guide grooves 138 spaced from each other and adjacent to respective areas from which the termination portions 118b, 120b of the first and second coil terminals 118, 120 protrude (
On the other hand, provided that the accuracy and reliability of the automatic winding process can be sufficiently ensured, the guide grooves 136, 138 of the bobbin 114 described above may be omitted.
In the coil assemblies 110, 110′ described above, the first to third coil terminals 118, 120, 122 are generally equidistantly aligned in the direction orthogonal to the coil center axis 112a and the center third coil terminal 122 is shared by two excitation circuits 134a, 134b, so that the coil 112 can be formed entirely by a single continuous wire 116, wherein the opposite wire ends 116c of the wire 116 are connected respectively with the first and second coil terminals 118, 120 and an intermediate point 116d of the wire 116 is connected with the third coil terminal 122 (
An example of the automatic winding process of the wire 116 in the coil assembly 110, 110′, in which the coil 112 is entirely formed by the single continuous wire 116, will be described with reference to
First, the wire end 116c of the wire 116 is tied and temporarily secured to the tying portion 118a of the first coil terminal 118. Next, the first lead portion 116a of the wire 116 adjacent or subsequent to the wire end 116c is laid along the first surface 130a (or in the guide groove 136 (
Next, another second lead portion 116b of the wire 116 adjacent or subsequent to the intermediate point 116d is laid along the second surface 130b (or in the guide groove 138 (
In the illustrated embodiment, the pair of second lead portions 116b of the wire 116 extend toward the first and second coil terminals 118, 120 in a direction away from each other when viewed from the tying portion 122a of the third coil terminal 122. However, the laying configuration is not limited to this embodiment, and the pair of second lead portions 116b may be laid to extend in a direction similar to each other between the coil 112 and the tying portion 122a of the third coil terminal 122 (in particular, in the case where the guide groove 138 is not provided). Also in this case, from the viewpoint of preventing the second lead portions 116b from being damaged, it is important to lay the pair of second lead portions 116b so as not to contact each other.
In the coil assembly 110, 110′, instead of forming the entire coil 112 by the single continuous wire 116, the coil 112 may be formed by respectively using conductive wires different from each other for the two excitation circuits 134a, 134b (
The bobbin 114 of the coil assembly 140 is further provided with a flat annular center collar 142 extending radially outward at the axial center of the body 124. The center collar 142 is disposed in parallel with the first and second collars 126, 128, and thereby a first region 114A supporting the wire 116 constituting one excitation circuit 134a (
In the coil assembly 140 configured as described above, a coil part 112A for one excitation circuit 134a and a coil part 112B for the other excitation circuit 134b can be formed respectively in the first region 114A and the second region 114B that are axially divided by the center collar 142 on the body 124 of the bobbin 114, so that the coil parts 112A, 112B can have mutually identical inner and outer diameters. Therefore, in the coil assembly 140, even when the entire coil 112 is formed by the single continuous wire 116, the winding efficiency for the coil parts 112A, 112B can be easily equalized. In this connection, in order to improve the accuracy and reliability of the automatic winding process of the wire 116 by a winding machine, the center collar 142 may be provided with a pair, of guide slits 144 that, can receive the first and second lead portions 116a, 116b of the wire 116 adjacent to the coil part 112B. It should be noted that, in
In the coil assembly 110, 110′, 140 configured as described above, the tying portion 122a of the third coil terminal 122 disposed at the center of three coil terminals 118, 120, 122 is formed in advance to protrude in a direction generally parallel with the coil center axis 112a from the extension 130 of the bobbin 114, and therefore in the case where, for example, the electromagnet 26, 96, 100 shown in
The coil assembly according to the present invention is not limited to the configuration having three coil terminals, and may be applied to a configuration having two terminal pairs independent from each other (i.e., four coil terminals in total) for respective two excitation circuits. Further, the coil assembly according to the present invention is not limitedly applied to the polarized electromagnetic relay 10 in which the characteristic armature 28 shown in
Thus, the present invention is a coil assembly for a polarized electromagnetic relay, including a coil with a center axis; a bobbin on which the coil is wound; and at least three coil terminals securely supported on the bobbin, a conductive wire (wires) forming the coil being connected to each of the coil terminals, wherein the coil constitutes two excitation circuits, each of which includes a terminal pair defined by any two of at least three coil terminals, characterized in that the wire is provided with a first lead portion extending between the coil and one coil terminal of the terminal pair and laid along one surface of the bobbin at a side close to the center axis of the coil, and a second lead portion extending between the coil and the other coil terminal of each terminal pair and laid along the other surface of the bobbin at a side away from the center axis.
Further, the present invention is a polarized electromagnetic relay including a base; an electromagnet assembly fitted to the base; a contact section fitted to the base and insulated from the electromagnet assembly; and a force transfer member disposed between the electromagnet assembly and the contact section and shiftable under an action of the electromagnet assembly to make the contact section open or close, wherein the electromagnet assembly includes an electromagnet, an armature driven by the electromagnet, and a permanent magnet carried on the armature, characterized in that the electromagnet includes a coil with a center axis; a bobbin on which the coil is wound; and at least three coil terminals securely supported on the bobbin, a conductive wire (wires) forming the coil being connected to each of the coil terminals; wherein the coil constitutes two excitation circuits, each of which includes a terminal pair defined by any two of at least three coil terminals; and wherein the wire is provided with a first lead portion extending between the coil and one coil terminal of the terminal pair and laid along one surface of the bobbin at a side close to the center axis of the coil, and a second lead portion extending between the coil and the other coil terminal of each terminal pair and laid along the other surface of the bobbin at a side away from the center axis.
While the invention has been described with reference to specific preferred embodiments, it will be understood by those skilled in the art that various changes and modifications may be made thereto without departing from the scope of the following claims.
Number | Date | Country | Kind |
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2007-021535 | Jan 2007 | JP | national |
2007-255377 | Sep 2007 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
3271707 | Koehler | Sep 1966 | A |
4122420 | Brown | Oct 1978 | A |
4621246 | Nagamoto et al. | Nov 1986 | A |
4740771 | Motoyama et al. | Apr 1988 | A |
5291166 | Chikira | Mar 1994 | A |
5389905 | Shibata et al. | Feb 1995 | A |
6046660 | Gruner | Apr 2000 | A |
6046661 | Reger et al. | Apr 2000 | A |
6320485 | Gruner | Nov 2001 | B1 |
6359537 | Ichikawa et al. | Mar 2002 | B1 |
6426689 | Nakagawa et al. | Jul 2002 | B1 |
Number | Date | Country |
---|---|---|
0 257 607 | Mar 1988 | EP |
2 616 959 | Dec 1988 | FR |
57-30232 | Feb 1982 | JP |
58-181227 | Oct 1983 | JP |
61-78106 | Apr 1986 | JP |
1-243333 | Sep 1989 | JP |
5-81991 | Apr 1993 | JP |
2005-183554 | Jul 2005 | JP |
2005-243367 | Sep 2005 | JP |
2006-210123 | Aug 2006 | JP |
Number | Date | Country | |
---|---|---|---|
20080180197 A1 | Jul 2008 | US |