JP2017174615A - Switch - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a switch that makes it easy to transfer heat to a thermally-actuated element.SOLUTION: A contact part 200 is provided in a cable run 110 including a first terminal 5 and a second terminal 10. A drive device 2 opens/closes the contact part 200. A shut-off mechanism 20 has a movable body 21 that is freely moved to an ON-position and an OFF-position. The shut-off mechanism 20 causes a drive device 2 to open the contact part 200 when the movable body 21 moves from the ON-position to the OFF-position. A thermally-actuated element 7 is formed in a plate shape, and moves the movable body 21 from the ON-position to the OFF-position by bending with heat transferred from the first terminal 5. A housing 6 accommodates the first terminal 5, the second terminal 10, the contact part 200, the drive part 2, the shut-off mechanism 20, and the thermally-actuated element 7. A heat conductor 8 is made of a material higher in heat conductivity than the thermally-actuated element 7, is accommodated in the housing 6, and transfers heat, transferred from the first terminal 5, to the thermally-actuated element 7.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a switch, and more particularly to a switch that interrupts an electric circuit when a terminal generates heat exceeding a predetermined temperature.

  2. Description of the Related Art Conventionally, a circuit breaker (switch) including a driving unit that opens and closes a stator piece and a movable piece connected to a terminal and a bimetal (thermally responsive element) is known (see, for example, Patent Document 1). ). The drive means has a movable frame in the longitudinal direction of the instrument frame, a tripping frame, and a snap mechanism at the center upper part of the instrument frame. In the circuit breaker described in Patent Document 1, the base end of the bimetal is fixed in the vicinity of the connection position between the stator piece and the terminal. The bimetal displaces the tip portion with temperature deformation and rotates the tripping frame in the direction in which the contact opens. The circuit breaker opens the contact by the temperature deformation of the bimetal.

Japanese Patent Laying-Open No. 2015-28906

  When heat exceeding the specified temperature occurs near the connection point between the stator piece and the terminal, heat is easily transferred to the base end of the bimetal (thermally responsive element), but heat is transmitted to the part far from the base end of the bimetal. There was a possibility that it was difficult to convey.

  This invention is made | formed in view of the said subject, and it aims at providing the switch which made it easy to transmit heat | fever to a thermally responsive element.

  The switch according to the present invention includes a first terminal and a second terminal, a contact portion, a driving device, a shut-off mechanism, a thermally responsive element, a container, and a heat conductor. The contact portion is provided in an electric circuit including the first terminal and the second terminal. The drive device opens and closes the contact portion. The blocking mechanism has a movable body that is movable between an on position and an off position. The blocking mechanism causes the driving device to open the contact portion when the movable body moves from the on position to the off position. The thermally responsive element is formed in a plate shape and is deformed by heat transmitted from the first terminal to move the movable body from the on position to the off position. The container houses the first terminal, the second terminal, the contact portion, the driving device, the shut-off mechanism, and the thermally responsive element. The thermal conductor is made of a material having a higher thermal conductivity than the thermal responsive element, and is housed in the container and transmits heat transmitted from the first terminal to the thermal responsive element.

  It is possible to provide a switch that facilitates transferring heat to the thermally responsive element.

It is a disassembled perspective view of the switch concerning an embodiment. FIG. 2A is a front view of the switch according to the embodiment. FIG. 2B is a plan view of the switch according to the embodiment. FIG. 2C is a left side view of the switch according to the embodiment. FIG. 2D is a right side view of the switch according to the embodiment. It is sectional drawing of the principal part of the switch concerning an embodiment. It is another sectional drawing of the principal part of the switch concerning an embodiment. It is sectional drawing of the principal part of the switch concerning the modification 1 of embodiment. It is sectional drawing of the principal part of the switch concerning the modification 2 of embodiment.

  Each figure demonstrated in the following embodiment and the modifications 1 and 2 is a typical figure, and the ratio of the size and thickness of each component in FIGS. 1 to 6 does not necessarily reflect the actual dimensional ratio. Not necessarily.

  The switch 1 of this embodiment is a switch that opens and closes an electric circuit through which a direct current flows. The switch 1 can be used, for example, for an application that turns on (turns on) or turns off (cuts off) the current of at least one DC circuit.

(Embodiment)
As shown in FIGS. 1 to 4, the switch 1 according to the present embodiment includes a first terminal 5 and a second terminal 10, a contact part 200, a driving device 2, a shut-off mechanism 20, and a heat responsive element 7. The heat conductor 8 and the container 6 are provided. The contact part 200 is provided in the electric circuit 110 including the first terminal 5 and the second terminal 10. The driving device 2 opens and closes the contact part 200. The blocking mechanism 20 has a movable body 21 that is movable between an on position and an off position. The blocking mechanism 20 causes the driving device 2 to open the contact portion 200 when the movable body 21 moves from the on position to the off position. The thermally responsive element 7 is formed in a plate shape and is deformed by heat transmitted from the first terminal 5 to move the movable body 21 from the on position to the off position. The container 6 houses the first terminal 5, the second terminal 10, the contact part 200, the driving device 2, the shut-off mechanism 20, and the thermally responsive element 7. The heat conductor 8 is made of a material having a higher thermal conductivity than that of the heat responsive element 7, is housed in the container 6, and transfers heat transferred from the first terminal 5 to the heat responsive element 7.

  It is preferable that the switch 1 of the present embodiment further includes the release unit 3 and the permanent magnet 202.

  The contact part 200 includes a fixed contact 26 and a movable contact 25. The fixed contact 26 is provided on the conductive plate 101 of the second terminal 10. The movable contact 25 is provided at an end opposite to the end on the first terminal 5 side of the conductive plate 27 and faces the fixed contact 26.

  The electric circuit 110 includes a first terminal 5, a second terminal 10, a conductive plate 101 connected to the second terminal 10, a conductive plate 27 connected to the first terminal 5, and a contact part 200. It is out.

  The container body 6 is formed of a resin material having electrical insulation. The container 6 is formed in a box shape, and has two first terminals 5, two second terminals 10, two contact portions 200, a driving device 2, a shut-off mechanism 20, and two The release unit 3, the permanent magnet 202, the two thermally responsive elements 7, and the two thermal conductors 8 are accommodated.

  In the following description, the directions of arrows indicating x, y, and z shown in FIGS. 1 to 4 are defined as an x direction, a y direction, and a z direction, respectively. For example, the y direction is a direction from the release unit 3 toward the first terminal 5. The x direction and the z direction are directions orthogonal to each other on a plane orthogonal to the y direction.

  Two insertion holes 62 (see FIG. 2C) through which the conductive portion 91 of the electric wire 9 connected to the first terminal 5 passes, and two insertions through the external electric wire connected to the second terminal 10, etc. A hole 652 (see FIG. 2D) is provided. The two insertion holes 62 are arranged in the x direction. Similarly, two insertion holes 652, two first terminals 5, two second terminals 10, two contact portions 200, two thermal responsive elements 7, two release portions 3, two Each of the insertion holes 62 is aligned in the x direction. One insertion hole 62, one insertion hole 652, one second terminal 10, one contact part 200, one thermal actuator 7, one first terminal 5, and one release part 3 And the one insertion hole 62 is located in a line along the y direction. Therefore, the two electric paths 110 along the y direction are arranged in the x direction.

  Two insulating walls 201 are provided on the body 65 of the vessel body 6. The two insulating walls 201 are provided between two adjacent contact portions 200 among a plurality (two) of contact portions 200. The insulating wall 201 suppresses a short circuit between the adjacent contact portions 200.

  The container 6 includes a body 65 and a cover 64. The body 65 is made of an electrically insulating material (synthetic resin). The outer peripheral shape of the body 65 in plan view is a rectangular shape. The first terminal 5, the second terminal 10, and the driving device 2 are fixed to the body 65 by screws or the like. The cover 64 is made of an electrically insulating material (synthetic resin). The outer peripheral shape of the cover 64 in plan view is a rectangular shape. The cover 64 and the body 65 support the shaft 32 of the release portion 3.

  As shown in FIG. 2B, a first opening 61 (opening) and a second opening 66 are provided on the surface of the cover 64 that intersects the z direction. Each of the first opening 61 and the second opening 66 penetrates the cover 64 in the z direction. The first opening 61 exposes the lever 31 of the release unit 3. The second opening 66 exposes the lever 22 of the driving device 2. The conductive portion 91 of the electric wire 9 is inserted into the insertion hole 62. The 1st opening part 61 and the 2nd opening part 66 are formed so that a longitudinal direction may become a rectangular-shaped hole in alignment with ay direction.

  The second terminal 10 is a pillar terminal, for example. The second terminal 10 includes a conductive plate 101, a movable plate 102, a screw 103, and a terminal frame 104. The conductive plate 101, the movable plate 102, the screw 103, and the terminal frame 104 are made of conductive members. The terminal frame 104 is formed in a cylindrical shape whose axis is the y direction. A screw hole into which the screw 103 is screwed is provided in a surface intersecting the z direction of the terminal frame 104. Inside the terminal frame 104, the conductive plate 101, the movable plate 102, and the screw 103 are arranged so as to overlap in the z direction in this order. For example, the second terminal 10 and the conductor of the electric wire are connected by screwing the screw 103 in a state where the conductor of the electric wire is inserted between the conductive plate 101 and the movable plate 102.

  The interruption mechanism 20 is a mechanism (so-called tripping mechanism) for the drive device 2 to change the contact portion 200 from the closed state to the open state. The blocking mechanism 20 includes a movable body 21 and a screw 214. The movable body 21 is made of an electrically insulating material (synthetic resin). The movable body 21 rotates around the shaft pin supported by the support portion 23 of the drive device 2. The movable body 21 moves between an on position and an off position. The “on position” of the movable body 21 is the position of the movable body 21 in a state where the driving device 2 closes the contact portion 200. The “off position” of the movable body 21 is the position of the movable body 21 that causes the driving device 2 to open the contact portion 200 from the closed state. That is, the drive device 2 opens the contact portion 200 when the movable body 21 is changed from the on position to the off position. Note that the “movement of the movable body 21” includes that the position of a part of the movable body 21 is changed by the rotation of the movable body 21. The movable body 21 rotates from the on position to the off position when receiving a force of a predetermined magnitude or more from the thermal actuator 7 in the direction of rotating to the off position in the on position. The driving device 2 opens the contact portion 200 when the movable body 21 rotates from the on position to the off position.

  In the movable body 21, a screw 214 is provided at a portion opposite to the portion supported by the support portion 23 so as to penetrate the movable body 21 in the y direction side.

  The drive device 2 includes a lever 22, a support portion 23, a pressing member 24, and two conductive plates 27. The support part 23 supports the lever 22, the pressing member 24, and the movable body 21. The two conductive plates 27 are arranged in the x direction. Each of the two contact portions 200 is arranged in the x direction. The lever 22 and the pressing member 24 are made of an electrically insulating material (synthetic resin). The support part 23 is made of, for example, a metal material. The support part 23 is screwed to the body 65 of the vessel body 6. The support part 23 supports two shaft pins. The support portion 23 supports the movable body 21 with a shaft pin that is passed through a shaft hole 231 formed in the support portion 23. Further, the support portion 23 supports the lever 22 by an axial pin different from the axial pin that is passed through the axial hole 231. The movable body 21 and the lever 22 are interlocked. The pressing member 24 is movable along the z direction in conjunction with the rotation of the lever 22.

  The conductive plate 27 is made of a conductive member. The conductive plate 27 is formed in a long plate shape, and is formed to a thickness that bends along the z direction and the y direction. The longitudinal direction of the conductive plate 27 is along the y direction. A hole 28 for passing a screw 63 in the thickness direction of the conductive plate 27 is provided at one end of the conductive plate 27 in the y direction. A movable contact 25 is provided at the other end of the conductive plate 27 opposite to the y direction.

  Two first terminals 5 are disposed on the y direction side of the movable body 21. Each first terminal 5 includes a retaining portion 51, a pressing portion 52, and a terminal plate 50.

  The terminal board 50 is made of a conductive material. The terminal plate 50 includes a connection plate 53, a conductive plate 55, a side plate 56, and a regulation plate 54. The connection plate 53 is disposed on the z direction side with respect to the axis of the insertion hole 62. The connection plate 53 has a plane that intersects the z direction. The connection plate 53 is disposed on the z direction side with respect to the axis of the insertion hole 62. The conductive plate 55 is formed in a long plate shape. The conductive plate 55 has a plane that intersects the z direction. An end of the conductive plate 55 on the opposite side to the y direction is provided with a hole 59 that penetrates the conductive plate 55 in the thickness direction. The end of the conductive plate 55 on the side opposite to the y direction is electrically connected to the conductive plate 27 of the driving device 2. A side plate 56 is provided at the end of the conductive plate 55 on the y direction side. The side plate 56 has a plane that intersects the x direction, and protrudes in the direction opposite to the z direction from the end of the connection plate 53 on the x direction side (and the direction opposite to the x direction). A restriction plate 54 is provided at the end of the side plate 56 opposite to the y direction. The restriction plate 54 has a plane that intersects the axis of the insertion hole 62 of the container 6.

  A lock spring 57 is disposed in a space surrounded by the connection plate 53, the conductive plate 55, the side plate 56, and the restriction plate 54 in the terminal plate 50.

  The lock spring 57 is formed by bending one end and the other end in the longitudinal direction of the strip-shaped conductive plate. In the lock spring 57, the retaining portion 51 is configured by one end in the longitudinal direction of the conductive plate, and the pressing portion 52 that presses the conductive portion 91 of the electric wire 9 is configured by the other end in the longitudinal direction of the conductive plate. The lock spring 57 includes a support portion 58 that supports the pressing portion 52 and the retaining portion 51 by an intermediate portion in the longitudinal direction of the conductive plate. The pressing part 52 is formed in an S shape. The retaining portion 51 is formed in a J shape. The pressing portion 52 presses the conductive portion 91 of the electric wire 9 against the connection plate 53 of the terminal plate 50 by its elastic force. Further, the retaining portion 51 prevents the conductive portion 91 from coming off by the elastic force of the leading end of the retaining portion 51 being caught by the conductive portion 91 of the electric wire 9.

  The heat-responsive element 7 is an element that starts to deform when heat is applied to the heat-responsive element 7 and exceeds a predetermined temperature, and the amount of deformation increases as the temperature rises. The thermoresponsive element 7 is made of bimetal as an example. As an example, the bimetal includes a first plate-like member made of a Ni—Fe alloy and a second plate-like member made of a Cu—Ni—Mn alloy having a higher coefficient of thermal expansion than the first plate member. A first plate-like member is arranged on the first surface 73 on the y-direction side of the thermal response element 7, and a second plate-like member is arranged on the second surface 74 on the opposite side of the y direction of the thermal response element 7. . Therefore, the second plate-like member on the second surface 74 side of the thermally responsive element 7 has a higher coefficient of thermal expansion than the first plate-like member on the first surface 73 side.

  The thermoresponsive element 7 is formed in a long plate shape. The thermal response element 7 has a short direction along the x direction. The thermally responsive element 7 includes a fixed portion 71 and a deformable portion 72. The fixing portion 71 is a shorter portion of the portions where the thermoresponsive element 7 is bent in an L shape. The deformation part 72 is a longer part among the parts where the thermoresponsive element 7 is bent in an L shape. The fixing portion 71 is provided with a hole 75 and is fixed to the body 65 of the container body 6 with a screw 63 passed through the hole 75. When the temperature of the deforming portion 72 rises above a predetermined temperature, the deforming portion 72 deforms so that the end 721 of the deforming portion 72 moves in the y direction. When the deforming portion 72 is deformed due to a temperature rise, the deforming portion 72 bends so as to be convex in the direction opposite to the y direction.

  When the temperature rises due to heat transmitted from the first terminal 5, the heat conductor 8, and the conductive plate 27, the deforming portion 72 is deformed so as to move the end portion 721 in the y direction. The heat transmitted from the first terminal 5, the heat conductor 8, and the conductive plate 27 is generated by, for example, a current flowing through the electric circuit 110 including the first terminal 5 and the second terminal 10. Therefore, when an overcurrent flows or the contact resistances of the first terminal 5, the second terminal 10, and the contact part 200 increase, the amount of heat increases. When the deformation portion 72 continues to be deformed, the end portion 721 of the deformation portion 72 pushes the screw 214 of the movable body 21 in the y direction, whereby the movable body 21 moves from the on position to the off position (see FIG. 4). When the movable body 21 rotates to the off position, the drive device 2 opens the contact portion 200.

  The deforming portion 72 returns to its original shape as the temperature of the deforming portion 72 decreases and approaches a predetermined temperature.

  The thermal conductor 8 is made of a material having a higher thermal conductivity than that of the thermally responsive element 7. The heat conductor 8 is made of beryllium copper, for example. The heat conductor 8 is formed in a long plate shape. The short direction of the heat conductor 8 is along the x direction. The heat conductor 8 has a first end 81, a second end 82, and a pressing portion 83. The first end 81 is provided with a hole 86 (see FIG. 3). The first end 81 is fixed to the body 65 of the container body 6 by a screw 63 in a state of being sandwiched between the fixing portion 71 of the thermally responsive element 7 and the conductive plate 27.

  The pressing portion 83 is a portion between the first end 81 and the second end 82. The pressing portion 83 presses the second end 82 against the second surface 74 of the thermally responsive element 7. The pressing portion 83 of the heat conductor 8 includes a spring portion 831 and a support portion 832. The spring portion 831 is a portion of the pressing portion 83 on the first end 81 side. The spring portion 831 is bent in a direction in which the deformable portion 72 of the thermally responsive element 7 is bent by heat.

  The support portion 832 protrudes from the spring portion 831 toward the second surface 74 of the thermally responsive element 7. The support portion 832 receives a force in a direction approaching the thermally responsive element 7 from the spring portion 831 of the heat conductor 8. The support portion 832 presses the second end 82 against the second surface 74 of the thermally responsive element 7.

  The second end 82 is an end portion of the heat conductor 8 opposite to the first end 81. The second end 82 is in contact with the second surface 74 of the thermally responsive element 7. The second end 82 of the heat conductor 8 is provided to transmit the heat transmitted from the first end 81 to the distal end portion of the deformable portion 72.

  The spring portion 831 and the second end are resistant to bending in a state where the first end 81 is fixed to the body 65 of the container body 6 and on the side opposite to the direction in which the deformed portion 72 of the thermally responsive element 7 is bent by heat. And is elastically deformed. The spring portion 831 presses the second end 82 against the second surface 74 of the thermally responsive element 7 by the restoring force of the elastically deformed deflection.

  A gap 80 is provided between the second surface 74 of the thermally responsive element 7 and the spring portion 831. The gap 80 is provided so that the deformable portion 72 does not come into contact with the spring portion 831 of the pressing portion 83 when the deformable portion 72 of the thermoresponsive element 7 is deformed by heat and becomes convex in the direction opposite to the y direction. ing.

  The spring portion 831 is elastically deformed according to the degree of bending of the deformation portion 72 even if the deformation portion 72 of the heat response element 7 is deformed by heat, and the second end 82 is formed on the second surface 74 of the heat response element 7. You can keep pushing. The second end is deformed along the second surface 74 of the thermally responsive element 7 by the elastically deformed bending restoring force, and is in surface contact with the second surface 74 of the thermally responsive element 7. The second end 82 is elastically deformed according to the degree of bending of the deformation portion 72 and continues to be in surface contact with the second surface 74 of the heat response element 7 even when the deformation portion 72 of the heat response element 7 is deformed by heat. be able to. For this reason, even if the degree of bending of the deforming portion 72 increases, the contact area with the deforming portion 72 hardly changes. Accordingly, the second end 82 of the heat conductor 8 can continue to transmit heat to the tip portion of the deformable portion 72 even when the deformable portion 72 of the thermoresponsive element 7 continues to be deformed by heat. As a result, the temperature of the thermally responsive element 7 is likely to be uniform, and the amount of displacement (degree of deformation) of the thermally responsive element 7 with respect to the heat transmitted to the thermally responsive element 7 is easily stabilized. In other words, the thermal conductor 8 makes it easy to ensure the amount of deformation of the thermal response element 7 due to the temperature rise of the thermal response element 7.

  The conductive plate 27, the heat conductor 8, the thermal actuator 7 and the conductive plate 55 of the terminal plate 50 are stacked in this order along the x direction. The conductive plate 55 and the conductive plate 27 are electrically connected. The conductive plate 27, the heat conductor 8, the thermally responsive element 7, and the connection plate 53 are thermally coupled. The heat of the conductive plate 55 is transmitted to the thermally responsive element 7 and the heat conductor 8. The conductive plate 27, the heat conductor 8, the thermally responsive element 7, and the conductive plate 55 of the terminal plate 50 are fixed to the body 65 of the container body 6 by screws 63. The screw 63 includes a hole 59 in the conductive plate 55 of the terminal plate 50, a hole 75 in the fixing portion 71 of the heat responsive element 7, a hole 86 in the first end 81 of the heat responsive element 7, and a hole 28 in the conductive plate 27. Through the body 65 of the vessel 6.

  As described above, the switch 1 according to the present embodiment includes the first terminal 5 and the second terminal 10, the contact portion 200, the driving device 2, the shut-off mechanism 20, the thermal responsive element 7, and the thermal conductor. 8 and the body 6. The contact part 200 is provided in the electric circuit 110 including the first terminal 5 and the second terminal 10. The driving device 2 opens and closes the contact part 200. The blocking mechanism 20 has a movable body 21 that is movable between an on position and an off position. The blocking mechanism 20 causes the driving device 2 to open the contact portion 200 when the movable body 21 moves from the on position to the off position. The thermally responsive element 7 is formed in a plate shape and is deformed by heat transmitted from the first terminal 5 to move the movable body 21 from the on position to the off position. The container 6 houses the first terminal 5, the second terminal 10, the contact part 200, the driving device 2, the shut-off mechanism 20, and the thermally responsive element 7. The heat conductor 8 is made of a material having a higher thermal conductivity than that of the heat responsive element 7, is housed in the container 6, and transfers heat transferred from the first terminal 5 to the heat responsive element 7.

  According to the above configuration, the heat conductor 8 is made of a material having a higher thermal conductivity than that of the heat responsive element 7, so that heat transferred from the first terminal 5 can be easily transferred to the heat responsive element 7. As a result, the thermally responsive element 7 can easily secure the amount of displacement due to the heat transmitted from the first terminal 5. In other words, it is possible to realize the switch 1 that facilitates transferring heat to the thermally responsive element 7.

  It is preferable that the heat conductor 8 of the switch 1 has a portion (second end 82) that is not fixed to the heat responsive element 7 and is in contact with the heat responsive element 7. Thereby, when the thermally responsive element 7 is deformed by heat, the heat conductor 8 can be made difficult to prevent deformation of the thermally responsive element 7. For example, assuming that there is a braided wire fixed to the thermally responsive element 7, the rigidity of the braided wire may prevent deformation of the thermally responsive element 7 when the braided wire transfers heat to the thermally responsive element 7. Since the heat conductor 8 in the switch 1 according to the present embodiment is not fixed to the heat responsive element 7, it is difficult to prevent deformation of the heat responsive element 7.

  The thermally responsive element 7 in the switch 1 of the present embodiment includes a first plate-like member (member of the first surface 73) and a second plate-like member (second surface) having a higher coefficient of thermal expansion than the first plate-like member. 74 members). The heat conductor 8 is in contact with the second plate-like member (the member of the second surface 74) of the thermally responsive element 7. Thereby, the thermally responsive element 7 is easily deformed by the heat transmitted from the heat conductor 8.

  The heat-responsive element 7 in the switch 1 according to the present embodiment preferably has a fixed portion 71 fixed to the container body 6 and a deformed portion 72 that bends with heat transmitted from the first terminal 5. The heat conductor 8 includes a second end 82 that is in contact with the deformable portion 72, a first end 81 that is closer to the first terminal 5 than the second end 82, a pressing portion 83 that presses the second end 82 against the deformable portion 72, It is preferable to have. According to the above configuration, even if the deforming portion 72 is bent by heat, the pressing portion 83 can press the second end 82 against the deforming portion 72. Therefore, even when the deforming portion 72 is bent by heat, the second end 82 can contact the deformation portion 72 and continue to transmit heat to the deformation portion 72.

  The pressing portion 83 in the switch 1 of the present embodiment is provided between the first end 81 and the second end 82 of the heat conductor 8, and is between the pressing portion 83 and the deforming portion 72 of the thermal response element 7. A gap 80 is preferably provided. According to the above configuration, since the gap 80 is provided between the pressing portion 83 and the deformation portion 72 of the thermal response element 7, even if the deformation portion 72 of the thermal response element 7 is deformed by heat, the deformation portion 72. Is less likely to come into contact with the pressing portion 83 of the heat conductor 8, and the deformable portion 72 is less likely to interfere with the pressing portion 83. Therefore, the operation of pressing the second end 82 against the deforming portion 72 by the pressing portion 83 of the heat conductor 8 is not easily prevented by the deforming portion 72. As a result, even when the deforming portion 72 of the thermoresponsive element 7 is deformed, the second end 82 can continue to contact the deforming portion 72, so that the second end 82 can continue to transmit heat to the deforming portion 72. it can.

  Each of the second end 82 of the heat conductor 8 and the pressing portion 83 in the switch 1 according to the present embodiment is bent in a direction in which the deformable portion 72 of the thermally responsive element 7 is bent by heat. It is preferable that the second end 82 is in contact with the deforming portion 72 of the thermally responsive element 7 in a state in which the deforming portion 72 is elastically deformed against bending on the side opposite to the direction in which the deforming portion 72 is bent by heat. Thereby, even when the deforming portion 72 of the thermoresponsive element 7 is deformed, the area where the second end 82 is in contact with the deforming portion 72 is hardly changed, so that the deforming portion 72 of the thermoresponsive element 7 is deformed. However, the second end 82 can continue to transfer heat to the deformed portion 72.

  Hereinafter, the operation of the driving device 2, the permanent magnet 202, and the release unit 3 will be described.

  The lever 22 of the drive device 2 is movable in the y direction side and the direction opposite to the y direction. When the lever 22 is rotated in the direction opposite to the y direction by the operator's operation while the movable body 21 is in the on position, the pressing member 24 moves in the direction opposite to the z direction. When the pressing member 24 moves in the direction opposite to the z direction, the pressing member 24 presses the conductive plate 27 to bend in the direction opposite to the z direction, thereby pressing the movable contact 25 against the fixed contact 26. Therefore, the driving device 2 connects the movable contact 25 and the fixed contact 26 and closes the contact portion 200.

  When the lever 22 is rotated in the y direction by the operator's operation while the movable body 21 is in the on position, the movable body 21 rotates to the off position in conjunction with the rotation of the lever 22. When the movable body 21 rotates to the off position, the pressing member 24 moves to the z direction side. When the conductive plate 27 returns to its original shape by the restoring force from the bent state, the movable contact 25 is separated from the fixed contact 26. Therefore, the driving device 2 opens the contact part 200 and interrupts the electric circuit 110 between the first terminal 5 and the second terminal 10.

  The permanent magnet 202 is provided to extinguish an arc between the fixed contact 26 and the movable contact 25.

  The release unit 3 is disposed on the z direction side of the first terminal 5. The release part 3 includes a main body 30, a lever 31, a shaft 32, a pressing part 34, and a protruding part 35. The release part 3 is made of an electrically insulating material (synthetic resin). The lever 31 protrudes from the z-direction side portion of the main body 30 toward the z-direction side. The lever 31 protrudes from the first opening 61 of the cover 64 in the container 6 to the z direction side. The shaft 32 protrudes from the surface of the main body 30 on the x direction side and the opposite surface. The shaft 32 is supported by the vessel body 6.

  The pressing portion 34 is provided on the main body 30 on the y direction side with respect to the shaft 32. The pressing part 34 protrudes in the direction opposite to the z direction. When the lever 31 is rotated in the y direction by the operator's operation, the main body 30 is rotated, and the pressing portion 34 is moved in the direction opposite to the z direction. When the pressing portion 34 moves in the direction opposite to the z direction, the pressing portion 51 contacts the end of the retaining portion 51 of the first terminal 5 on the x direction side (and the direction opposite to the x direction), and causes the retaining portion 51 to be in the z direction. Move to the opposite side.

  The protruding portion 35 is provided on the main body 30 on the side opposite to the y direction from the shaft 32. The protruding portion 35 has a portion protruding from the main body 30 in the direction opposite to the z direction. The protruding portion 35 is disposed between the connection plate 53 of the terminal plate 50 and the restriction plate 54. When the lever 31 rotates in the direction opposite to the y direction, the protruding portion 35 moves to a position that protrudes in the direction opposite to the z direction from the plane in the direction opposite to the z direction in the connection plate 53. In the state where the protruding portion 35 protrudes in the direction opposite to the z direction from the plane opposite to the z direction in the connection plate 53 of the terminal plate 50, the conductive portion 91 of the electric wire 9 inserted from the insertion hole 62 is provided. Touch.

  By the way, each of the 1st terminal 5 and the 2nd terminal 10 is not limited to a quick connection terminal and a pillar terminal, The terminal which a crimp terminal etc. can connect may be sufficient. Each of the 1st terminal 5 and the 2nd terminal 10 may be electrically connected with connection conductors, such as a crimp terminal provided in the tip of the core wire of an insulation covering electric wire, for example.

  The thermally responsive element 7 may be composed of an appropriate member that deforms due to temperature rise, such as trimetal using three different metal materials.

  The switch 1 is not limited to the application of turning on (turning on) or turning off (cutting off) the current of the DC circuit, but may be used for the purpose of turning on (turning on) or turning off (cutting off) the current of the AC circuit.

  The switch 1 has two second terminals 10, two contact portions 200, a thermally responsive element 7, a heat conductor 8, a first terminal 5, a release portion 3, and two insertion holes 62. However, the present invention is not limited to this, and it is only necessary to have at least one of each.

  At least one thermal response element 7 among the plurality (two) of thermal response elements 7 can move the movable body 21 to the off position. Thereby, since the drive device 2 can interrupt | block all the two (two) electric circuits 110, when heat generate | occur | produces in the at least 1 electric circuit 110, it can improve safety | security.

  The release unit 3 and the movable body 21 of the blocking mechanism 20 are not limited to rotating, and may be configured to be movable by sliding, for example, along the y direction. In short, the lever 31 of the release part 3, the pressing part 34 of the release part 3, the release part 3 protruding part 35, and the movable body 21 of the blocking mechanism 20 may be configured to be movable.

  The first end 81 of the heat conductor 8 is fixed to the conductive plate 27 so as to overlap the conductive plate 27. The heat conductor 8 is formed by punching in a state where the heat conductor 8 overlaps the conductive plate 27 and then bending the second end 82 and the pressing portion 83 of the heat conductor 8. The hole 85 penetrating the second end 82 in the thickness direction is a hole formed when a hole for attaching the movable contact 25 to the conductive plate 27 is provided in the conductive plate 27. In addition, when forming the heat conductor 8 and the conductive plate 27 separately, the hole 85 may not be provided in the second end 82 of the heat conductor 8.

  Between the second end 82 of the heat conductor 8 and the deformed portion 72 of the heat-responsive element 7, grease (for example, silicone grease) that can easily transfer heat may be applied.

  The conductive plate 27, the thermal conductor 8, the thermal actuator 7 and the conductive plate 55 are not limited to being stacked in this order along the x direction, and the conductive plate 27, the thermal conductor 8, The responding element 7 and the conductive plate 55 may be stacked in any order in which they are thermally coupled.

  In addition, the container 6 is not limited to being comprised with the body 65 and the cover 64 which are divided in az direction. The container body may be configured by, for example, a pair of side cases separated in the x direction and an intermediate case provided between the pair of side cases.

  The permanent magnet 202 can be omitted. Moreover, when the 1st terminal 5 and the 2nd terminal 10 do not contain a quick connection terminal, the cancellation | release part 3 is omissible.

(Modification 1)
Modification 1 of the switch 1 will be described with reference to FIG. The switch of the modification 1 differs in the structure of the heat conductor 8a from the structure of the switch 1 of embodiment. In the switch according to the first modification, the second end 82 of the heat conductor 8a and the pressing portion 83a are in contact with the second surface 74 of the heat responsive element 7 in a state where the heat responsive element 7 is not deformed. A portion between the hole 86a and the pressing portion 83a at the first end 81a of the heat conductor 8a is in contact with the fixing portion 71 of the thermal actuator 7. In addition, about the structure similar to the switch 1 of embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted. Further, the definitions in the x, y, and z directions shown in FIG. 5 are the same as those in the switch 1 of the embodiment.

  Since the second end 82 of the heat conductor 8a and the pressing portion 83a are in contact with the second surface 74 of the heat responsive element 7 in a state where the heat responsive element 7 is not deformed, the heat responsive element 7 starts to be deformed. By the time, the heat of the heat conductor 8a is easily transmitted to the heat-responsive element 7. Each of the pressing portion 83a and the second end 82 of the heat conductor 8a is bent in a direction approaching the second surface 74 of the thermal response element 7, and is bent in a direction away from the second surface 74 due to elastic deformation. ing. Therefore, each of the pressing portion 83a and the second end 82 of the heat conductor 8a is in contact with the second surface 74 of the thermal response element 7 in a bent state. The pressing portion 83a of the heat conductor 8a presses the second end 82 against the second surface 74 of the heat responsive element 7 by a bending restoring force. Even if the deforming portion 72 of the heat responsive element 7 is bent by heat, the second end 82 contacts the second surface 74 of the heat responsive element 7 and deforms along the second surface 74. Even if the deformed portion 72 of the thermoresponsive element 7 is bent by heat, the second end 82 of the heat conductor 8a can continue to transmit heat to the deformed portion 72.

(Modification 2)
Modification 2 of the switch 1 will be described with reference to FIG. In the switch according to the second modification, the heat conductor 8b is different from the switch 1 according to the embodiment in that the heat conductor 8b has an extension 87. In addition, about the structure similar to the switch 1 of embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted. Further, the definitions in the x, y, and z directions shown in FIG. 6 are the same as those in the switch 1 of the embodiment.

  The extension part 87 is formed in a long plate shape. The longitudinal direction of the extension part 87 is along the y direction. The extension portion 87 is provided at the end of the first end 81 opposite to the end where the pressing portion 83 is provided. The extension 87 is formed integrally with the first end 81, for example. The extension 87 is bent along the surface of the first terminal 5 opposite to the z direction of the conductive plate 55. The extension 87 is in surface contact with the surface of the first terminal 5 opposite to the z direction of the conductive plate 55. Therefore, the heat conductor 8 b in the switch 1 according to the second modification is in contact with the first terminal 5. The heat conductor 8 b is in contact with the first terminal 5, thereby making it easy to transfer the heat of the first terminal 5 to the thermally responsive element 7.

  In addition to the conductive plate 55, the heat conductor 8b may be in surface contact with, for example, the connection plate 53, the regulation plate 54, the side plate 56, and the like. Moreover, the heat conductor 8b may have the site | part which carries out a line contact and a point contact other than the 1st terminal 5 and a surface contact.

DESCRIPTION OF SYMBOLS 1 Switch 10 Second terminal 110 Electric path 2 Driving device 20 Breaking mechanism 21 Movable body 200 Contact portion 3 Release portion 5 First terminal 6 Body 7 Thermoresponsive element 71 Fixing portion 72 Deformation portion 73 First surface 74 Second surface 8 , 8a, 8b Heat conductor 80 Clearance 81 First end 82 Second end 83 Pressing portion

Claims (7)

A first terminal and a second terminal;
A contact portion provided in an electric circuit including the first terminal and the second terminal;
A driving device for opening and closing the contact part;
A blocking mechanism that has a movable body that is movable between an on position and an off position, and that causes the drive device to open the contact portion when the movable body moves from the on position to the off position;
A thermally responsive element that is formed in a plate shape and is deformed by heat transmitted from the first terminal to move the movable body from the on position to the off position;
A container housing the first terminal, the second terminal, the contact portion, the driving device, the shut-off mechanism, and the thermally responsive element;
A heat conductor made of a material having a higher thermal conductivity than the thermally responsive element, housed in the container, and transferring heat transferred from the first terminal to the thermally responsive element;
A switch characterized by comprising. The switch according to claim 1, wherein the thermal conductor has a portion that is not fixed to the thermal responsive element and is in contact with the thermal responsive element. The thermally responsive element includes a first plate member and a second plate member having a larger coefficient of thermal expansion than the first plate member,
The switch according to claim 1, wherein the thermal conductor is in contact with the second plate-like member of the thermal response element. The thermally responsive element has a fixed portion fixed to the container body, and a deformable portion that bends by heat transmitted from the first terminal,
The thermal conductor has a second end in contact with the deforming portion, a first end closer to the first terminal than the second end, and a pressing portion that presses the second end against the deforming portion. The switch according to any one of claims 1 to 3. The pressing portion is provided between the first end and the second end of the heat conductor,
The switch according to claim 4, wherein a gap is provided between the pressing portion and the deformation portion of the thermally responsive element. Each of the second end of the heat conductor and the pressing portion is bent in a direction in which the deforming portion of the thermoresponsive element is bent by heat,
The second end is in contact with the deforming portion of the thermally responsive element in an elastically deformed state against bending on a side opposite to a direction in which the deforming portion is bent by heat. The switch according to 5. The switch according to any one of claims 1 to 6, wherein the thermal conductor is in contact with the first terminal.

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