The present invention relates to a relay.
A relay moves one of contacts toward the other contact to open or close the contacts. For example, a relay disclosed in Patent Document 1 drives a pressing member by using magnetic force of a coil generated when voltage is applied to the coil. The pressing member thus presses a contact piece and moves a movable contact attached to the contact piece to bring the movable contact into contact with a fixed contact.
Patent Document 1: Japanese Patent No. 5741679
The pressing member moves the movable contact by pressing and bending the contact piece. Accordingly, when the contact piece has high rigidity, force for driving the pressing member needs to increase. This may cause a problem that power consumption required by the coil rises. Particularly in case of adoption of such an actuator which moves the pressing member from an off-position to an on-position via an overshoot position located beyond the on-position, further force is required to move the pressing member to the overshoot position when the contact piece has high rigidity. In this case, power consumption by the coil further rises.
Moreover, when a terminal to which the fixed contact is attached has high rigidity similarly to the contact piece, a large bend of the terminal becomes difficult to achieve. In this case, a load applied to the contact piece at the time of movement of the pressing member to the overshoot position increases. The heavy load thus applied may decrease stability of an action of the contact piece.
An object of the present invention is to provide a relay which reduces a rise of energy consumed by an actuator and achieves a stable action of a contact piece even when the actuator is of such a type which moves a pressing member via an overshoot position.
A relay according to an aspect of the present invention includes a first contact, a terminal, a second contact, a contact piece, a pressing member, and an actuator. The first contact is attached to the terminal. The second contact is disposed at a position facing the first contact. The second contact is attached to the contact piece. The pressing member is configured to move to an off-position and an on-position. When the pressing member is located at the off-position, the first contact and the second contact come into a non-contact state. When the pressing member is located at the on-position, the first contact and the second contact come into a contact state by press of the pressing member against the contact piece. The actuator moves the pressing member from the off-position to the on-position via an overshoot position located beyond the on-position. The contact piece includes a body, and a low rigidity portion having rigidity lower than rigidity of the body. The pressing member presses the low rigidity portion.
In relay according to the aspect, the low rigidity portion is bendable with small force by press of the pressing member against the low rigidity portion. Accordingly, a rise of energy consumption by the actuator can be reduced. Moreover, even when the terminal has high rigidity, a load applied to the contact piece by movement of the pressing member to the overshoot position can be reduced by a bend of the low rigidity portion. Accordingly, a stable operation of the contact piece can be obtained.
The low rigidity portion may have a thickness smaller than a thickness of the body. In this case, the reduction of the thickness of the low rigidity portion can decrease rigidity of the low rigidity portion.
The contact piece may include a plurality of leaf springs laminated on each other. The low rigidity portion may include the leaf springs fewer in number than the leaf springs included in the body. In this case, the reduction of the number of the leaf springs constituting the low rigidity portion can decrease rigidity of the low rigidity portion.
The low rigidity portion may be located on a leading end side of the contact piece with respect to the second contact. In this case, a large bend of the low rigidity portion is achievable with small force.
The low rigidity portion may have a width smaller than a width of the body. In this case, the reduction of the width of the low rigidity portion can decrease rigidity of the low rigidity portion.
The contact piece may include a slit formed between the low rigidity portion and the body. In this case, the presence of the slit can decrease rigidity of the low rigidity portion.
The low rigidity portion may include a first low rigidity portion and a second low rigidity portion. The first low rigidity portion and the second low rigidity portion may be extended in a lengthwise direction of the contact piece from the body, and disposed away from each other in a widthwise direction of the contact piece. In this case, a load applied to the contact piece can decrease by bends of the first low rigidity portion and the second low rigidity portion.
The body may include a contact attaching portion to which the second contact is attached. The contact attaching portion may be disposed between the first low rigidity portion and the second low rigidity portion. The contact piece may include a first slit and a second slit. The first slit may be formed between the first low rigidity portion and the contact attaching portion, and extended in the lengthwise direction of the contact piece. The second slit may be formed between the second low rigidity portion and the contact attaching portion, and extended in the lengthwise direction of the contact piece. In this case, the presence of the first slit and the second slit can decrease each rigidity of the first low rigidity portion and the second low rigidity portion.
Each of the first slit and the second slit may reach a position on a proximal end side of the contact piece with respect to the second contact. In this case, each rigidity of the first low rigidity portion and the second rigidity portion can further decrease.
The low rigidity portion may further include a junction that joins the first low rigidity portion and the second low rigidity portion. This configuration reduces a twist between the first low rigidity portion and the second low rigidity portion, thereby reducing deviation of a pressing position.
The pressing member may press the junction. Alternatively, the pressing member may press the first low rigidity portion and the second low rigidity portion.
The pressing position formed in the low rigidity portion and pressed by the pressing member may be located on a leading end side of the contact piece with respect to the second contact. In this case, a large bend of the low rigidity portion is achievable with small force.
The actuator may further include a retaining member that latches the pressing member to retain the pressing member at the on-position. In this case, the pressing member can be stably retained at the on-position without being affected by impact or magnetic force from the outside, compared to the case where the pressing member is retained at the on-position by magnetic force.
According to the present invention, a relay can reduce a rise of energy consumed by an actuator and achieve a stable action of a contact piece even when the actuator is of such a type which moves a pressing member via an overshoot position.
A relay according to an embodiment is hereinafter described with reference to the drawings.
The base 2 houses the fixed contact terminal 3, the movable contact terminal 4, the contact piece 5, the pressing member 6, and the actuator 7. The base 2 has an opened face. The opening of the base 2 is covered by a not-shown cover.
The fixed contact terminal 3 is made of a conductive material such as copper. A first contact 8 is attached to one end of the fixed contact terminal 3.
The other end of the fixed contact terminal 3 projects from the base 2 toward the outside. A first support groove 11 is formed inside the base 2. The fixed contact terminal 3 is fitted into the first support groove 11 to be supported on the base 2.
The movable contact terminal 4 is made of a conductive material such as copper. As illustrated in
The contact piece 5 is made of a conductive material such as copper. The contact piece 5 is disposed at a position facing the fixed contact terminal 3. A leading end portion 14 of the contact piece 5 is pressed by the pressing member 6. A proximal end portion 15 of the contact piece 5 is attached to the support 12 of the movable contact terminal 4. The contact piece 5 is supported on the support 12. A second contact 9 is attached to the contact piece 5. The second contact 9 is disposed at a position facing the first contact 8. The second contact 9 is located between the leading end portion 14 and the support 12.
The contact piece 5 includes a curved portion 16. The curved portion 16 is located between the second contact 9 and the support 12. The second contact 9 is located between the leading end portion 14 and the curved portion 16. The curved portion 16 has a shape expanded in a direction away from the fixed contact terminal 3. The curved portion 16 may have a shape expanded in a direction toward the fixed contact terminal 3. The contact piece 5 includes a plurality of leaf springs 5a and 5b. The contact piece 5 is constituted by a lamination of the plurality of leaf springs 5a and 5b.
The second contact 9 is provided to be movable relative to the first contact 8. More specifically, the contact piece 5 is pressed by the pressing member 6 to thereby elastically deform and bend toward the fixed contact terminal 3. The second contact 9 thus moves toward the first contact 8. When the press against the contact piece 5 by the pressing member 6 is released, the contact piece 5 returns in a direction away from the fixed contact terminal 3 by elastic force of the contact piece 5. The second contact 9 thus moves away from the first contact 8. Alternatively, the contact piece 5 may be pulled by the pressing member 6 to move the second contact 9 away from the first contact 8.
The low rigidity portion 72 projects from the body 71 toward the leading end side. The low rigidity portion 72 is located on a leading end side of the contact piece 5 with respect to the second contact 9. The low rigidity portion 72 includes the leading end portion 14 described above. The pressing member 6 therefore presses the low rigidity portion 72. A pressing position formed in the low rigidity portion 72 and pressed by the pressing member 6 is located on the leading end side of the contact piece 5 with respect to the second contact 9.
The low rigidity portion 72 is constituted by the leaf spring 5a fewer in number than the leaf springs 5a and 5b constituting the body 71. Accordingly, the low rigidity portion 72 has a thickness smaller than a thickness of the body 71. Moreover, the low rigidity portion 72 has a width W1 smaller than a width W2 of the body 71. The low rigidity portion 72 therefore exhibits rigidity lower than rigidity of the body 71. Accordingly, when the same pressing force is applied, a displacement amount of the low rigidity portion 72 is larger than a displacement amount of the body 71. In other words, pressing force required by the low rigidity portion 72 is smaller than pressing force required by the body 71 for producing an equivalent displacement amount.
According to the embodiment, the body 71 is constituted by the two leaf springs 5a and 5b, while the low rigidity portion 72 is constituted by the one leaf spring 5a. However, the body 71 may be constituted by more than the two leaf springs 5a and 5b. The low rigidity portion 72 may be constituted by more than the one leaf spring 5a.
As illustrated in
The second pressing member 38 includes a first movable portion 21 and a second movable portion 22. The first movable portion 21 and the second movable portion 22 are separate portions. The first movable portion 21 includes the pivot 17. The second movable portion 22 includes the contact portion 18, and extends from the first movable portion 21 toward the contact piece 5. The first movable portion 21 includes a first part 23 and a second part 24.
The first movable portion 21 has a shape bent at a position between the first part 23 and the second part 24. More specifically, the first part 23 obliquely extends from the pivot 17 toward the contact piece 5. The second part 24 is disposed between the contact piece 5 and the actuator 7.
The second movable portion 22 extends from a leading end of the first movable portion 21 toward the leading end portion 14 of the contact piece 5. The second movable portion 22 is connected to the leading end of the first movable portion 21. More specifically, as illustrated in
The second movable portion 22 includes a recess 26. The leading end portion 14 of the contact piece 5 is disposed inside the recess 26. The contact portion 18 described above is a part of an edge of the recess 26. The leading end portion 14 of the contact piece 5 has a shape bent toward the contact portion 18. When the first movable portion 21 rotates around the pivot 17 in a direction of approaching the contact piece 5, the second movable portion 22 is pressed by the leading end of the first movable portion 21. Accordingly, the second movable portion 22 linearly moves in such a direction that the contact portion 18 approaches the contact piece 5.
The actuator 7 moves the first pressing member 33 in the axial direction. The actuator 7 includes a coil 31 and a retaining mechanism 32. The coil 31 includes a bobbin 34, a winding 35, a coil case 36, and an iron core 37. The winding 35 is wound around the bobbin 34. The winding 35 is connected to a not-shown coil terminal. When voltage is applied to the coil 31 via the coil terminal, the coil 31 generates magnetic force which moves the iron core 37 disposed inside the coil 31 in an axial direction of the actuator 7.
The retaining mechanism 32 and the first pressing member 33 are disposed within a housing 39. The retaining mechanism 32 transmits an action of the iron core 37 to the first pressing member 33 to move the first pressing member 33 to an on-position illustrated in
The first pressing member 33 moves in the axial direction to press the second pressing member 38. A pressing position P1 at which the first pressing member 33 presses the second pressing member 38 is located between the pivot 17 and the contact portion 18. The pressing position P1 is located on a side where the second contact 9 is disposed with respect to the curved portion 16. The pressing position P1 is located on a side where the curved portion 16 is disposed with respect to the second contact 9.
When the first pressing member 33 is located at the off-position illustrated in
Next, a configuration of the retaining mechanism 32 is described in detail.
The cover 41 is attached to a leading end of the retaining member 42. A through hole 44 is formed inside the cover 41 and the retaining member 42. The first pressing member 33, the pusher 43, and the iron core 37 described above are disposed to be movable in the axial direction within the through hole 44.
The latching portion 56 has a plurality of latching projections 58. The plurality of latching projections 58 are disposed with a space left between each other in the circumferential direction of the latching portion 56. The plurality of latching projections 58 are movable along the release grooves 46 described above.
A plurality of inclined surfaces 59 are provided at an end of the latching portion 56. The plurality of inclined surfaces 59 are disposed in the circumferential direction of the latching portion 56.
As illustrated in
Next, an operation of the actuator 7 is described.
In the following description, an “off-direction” refers to a direction from the on-position Pon to the off-position Poff. The “off-direction” corresponds to the right direction in
In (A) of
At this time, the inclined surfaces 53 of the pusher 43 press the inclined surfaces 59 of the latching portion 56 as illustrated in
In the state that the latching projections 58 are located beyond the retaining projections 45, the first pressing member 33 reaches the overshoot position Pov after further movement in the on-direction from the on-position Pon as illustrated in (B) of
When voltage applied to the actuator 7 stops, the first pressing member 33 moves in the off-direction by the elastic force of the contact piece 5. Accordingly, the latching projections 58 move in the off-direction and contact the latching inclined surfaces 47 as illustrated in
In this state, the first pressing member 33 is located at the on-position Pon illustrated in (C) of
Each of the latching projections 58 moving to a position facing the guide groove 49 has a larger outside diameter than the inside diameter of the guide groove 49. Thus, each of the latching projections 58 does not enter the guide groove 49, but stops by latching of the retaining projection 45. This latching regulates the movement of the latching projection 58 in the off-direction.
When voltage is subsequently applied to the actuator 7 in the state that the first pressing member 33 is located at the on-position Pon as illustrated in (C) of
When the latching projections 58 reach positions above the steps 50 of the retaining member 42, the latching portion 56 rotates around the axis in the same manner as described above. As a result, the latching projections 58 move to positions facing the releasing inclined surfaces 48 (arrows A6) as illustrated in
When voltage applied to the actuator 7 then stops, the first pressing member 33 moves in the off-direction by the elastic force of the contact piece 5. The inclined surfaces 53 of the latching projections 58 therefore slide along the releasing inclined surfaces 48, and move to positions facing the release grooves 46 as illustrated in
As described above, the actuator 7 moves the first pressing member 33 from the off-position Poff to the on-position Pon via the overshoot position Pov. The actuator 7 also moves the first pressing member 33 from the on-position Pon to the off-position Poff via the overshoot position Pov. Retention and release of the first pressing member 33 by using the retaining member 42 are switchable by passage of the first pressing member 33 through the overshoot position Pov.
The relay 1 according to the embodiment has the following characteristics.
The low rigidity portion 72 is bendable with small force by press of the pressing member 6 against the low rigidity portion 72. Accordingly, a rise of energy consumed by the actuator 7 can be reduced. Moreover, the thickness of the body 71 is made larger than the thickness of the low rigidity portion 72. Accordingly, conductivity of the contact piece 5 can be increased, which can reduce an excessive temperature rise during conduction.
According to the embodiment, the thickness of the fixed contact terminal 3 is larger than the thickness of the body 71. Accordingly, the fixed contact terminal 3 has rigidity higher than rigidity of the body 71. However, even in the state of high rigidity of the fixed contact terminal 3, a load applied to the contact piece 5 by movement of the first pressing member 33 to the overshoot position Pov is reducible by a bend of the low rigidity portion 72. Accordingly, a stable operation of the contact piece 5 is realizable.
The first pressing member 33 is retained at the on-position Pon by latching of the latching portion 56 by the retaining member 42. In other words, the first pressing member 33 is retained at the on-position Pon not by magnetic force but in a mechanical manner. Accordingly, the relay 1 can be maintained in the set state even at a stop of voltage applied to the coil 31. Moreover, when voltage is applied to the coil 31 to cancel the set state, the pusher 43 rotates and retains the first pressing member 33 at the off-position Poff. Accordingly, the relay 1 can be maintained in the reset state even at a stop of voltage applied to the coil 31.
In the relay 1 according to the embodiment, the state of the relay 1 switches between the set state and the reset state for every input of a pulse signal to the actuator 7. If no signal is input, the state of the relay 1 is maintained without change in the state. In this case, the state of the relay 1 can be maintained without the need of continuous application of voltage to the actuator 7. Accordingly, power consumption of the relay 1 can be reduced. Moreover, control by the pulse signal as adopted herein can simplify the configuration of a control circuit included in the actuator 7.
Because the relay 1 is maintained in the set state by the latching between the retaining member 42 and the latching portion 56, impact resistance can be improved as compared to the case that the relay 1 is maintained in the set state by electromagnetic force generated by the coil 31. Furthermore, the set state can be continued without being affected by magnetism from the outside.
Next, the contact piece 5 according to a second embodiment is described.
The first low rigidity portion 72a and the second low rigidity portion 72b are extended in the lengthwise direction of the contact piece 5 from the body 71, and disposed away from each other in the widthwise direction of the contact piece 5. The first low rigidity portion 72a includes a first hole 74. The second low rigidity portion 72b includes a second hole 75. Positions of the first hole 74 and the second hole 75 in the lengthwise direction of the contact piece 5 are located on a leading end side with respect to the second contact 9.
The first low rigidity portion 72a has a thickness smaller than the thickness of the body 71. The second low rigidity portion 72b has a thickness smaller than the thickness of the body 71. The first low rigidity portion 72a is constituted by the leaf spring 5a fewer in number than the leaf springs 5a and 5b constituting the body 71. The second low rigidity portion 72b is constituted by the leaf spring 5a fewer in number than the leaf springs 5a and 5b constituting the body 71. According to the embodiment, each of the low rigidity portion 72a and the second low rigidity portion 72b is constituted by the one leaf spring, while the body 71 is constituted by the two leaf springs 5a and 5b. However, each of the first low rigidity portion 72a and the second low rigidity portion 72b may be constituted by more than one leaf spring. The body 71 may be constituted by more than the two leaf springs 5a and 5b.
The contact piece 5 includes a first slit 76 and a second slit 77. The first slit 76 is formed between the first low rigidity portion 72a and the contact attaching portion 73, and extended in the lengthwise direction of the contact piece 5. The second slit 77 is formed between the second low rigidity portion 72b and the contact attaching portion 73, and extended in the lengthwise direction of the contact piece 5. The first slit 76 and the second slit 77 reach the proximal end side of the contact piece 5 with respect to the second contact 9.
As apparent from above, each of the first low rigidity portion 72a and the second low rigidity portion 72b of the contact piece 5 according to the second embodiment has a reduced thickness, and includes the slit 76 or 77. Accordingly, each of the first low rigidity portion 72a and the second low rigidity portion 72b has rigidity lower than rigidity of the body 71.
In the contact piece 5 according to the second embodiment described above, the first low rigidity portion 72a and the second low rigidity portion 72b are similarly bendable with small force by press of the pressing member 6 against the first low rigidity portion 72a and the second low rigidity portion 72b. Accordingly, a rise of energy consumed by the actuator 7 can be reduced. Moreover, a load applied to the contact piece 5 by movement of the first pressing member 33 to the overshoot position Pov is reducible by bends of the first low rigidity portion 72a and the second low rigidity portion 72b. Accordingly, a stable operation of the contact piece 5 is realizable.
The present invention is not limited to the embodiment described herein as a specific embodiment of the present invention. Various modifications may be made without departing from the scope of the subject matters of the invention.
The configuration of the relay 1 may be modified. For example, not a single but two or more contacts may be provided to constitute each of the first contact 8 and the second contact 9. The configuration of the contact piece 5 may be modified from the configuration described above in the embodiment.
The shape of the pressing member 6 may be modified from the shape described above in the embodiments. For example, the first movable portion 21 and the second movable portion 22 may be integrated into one piece. Alternatively, the second pressing member 38 may be eliminated. In this case, the contact piece 5 may be pressed directly by the first pressing member 33.
The configuration of the actuator 7 may be modified from the configuration described above in the embodiment. Similarly, the configuration of the retaining mechanism 32 may be modified.
The shape of the contact piece 5 may be modified from the shape described above in the embodiments.
The junction 72c thus provided reduces a twist between the first low rigidity portion 72a and the second low rigidity portion 72b. Accordingly, reduction of deviation of the pressing position is achievable. The pressing member 6 of the contact piece 5 according to the first modified example may press the first low rigidity portion 72a and the second low rigidity portion 72b. Alternatively, the pressing member 6 may press the junction 72c.
According to the present invention, a relay can reduce a rise of energy consumed by an actuator and achieve a stable action of a contact piece even when the actuator is of such a type which moves a pressing member via an overshoot position.
8 first contact
3 fixed contact terminal
9 second contact
5 contact piece
6 pressing member
7 actuator
71 body
72 low rigidity portion
5
a,
5
b leaf spring
72
a first low rigidity portion
72
b second low rigidity portion
73 contact attaching portion
76 first slit
77 second slit
72
c junction
42 retaining member
Number | Date | Country | Kind |
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2015-242409 | Dec 2015 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2016/083974 | 11/16/2016 | WO | 00 |