JP7044819B2 - Power circuit breaker - Google Patents

Description

The present invention relates to a power supply circuit cutoff device.

For example, vehicles such as electric vehicles and hybrid vehicles are provided with a power supply circuit cutoff device called a service plug that cuts off the power supply between the power supply and the load in order to ensure work safety in maintenance of the electric system. Be done.
This type of power circuit cutoff device includes a first housing and a second housing that is attached to and detached from the first housing, for example, a female terminal provided in the first housing and a male terminal provided in the second housing. Some power switches are configured from the above (see, for example, Patent Document 1).

In this power supply circuit cutoff device, the male terminal is inserted and removed from the female terminal by attaching and detaching the second housing to and from the first housing, and the power switch is turned on and off.

Japanese Unexamined Patent Publication No. 2012-243559

By the way, in the above power supply circuit cutoff device, every time the second housing is attached / detached to / from the first housing, the male terminal is inserted / removed from the female terminal and the contact portions slide with each other. Therefore, if the operation of attaching / detaching the second housing to / from the first housing is repeated, the surface of the contact portion where the female terminal and the male terminal slide with each other may be scraped. Further, the plating applied to the surfaces of the terminals may be scraped off to expose the base portion, and the exposed portion may be oxidized to increase the electric resistance and reduce the reliability.

Further, the power supply circuit cutoff device has a structure in which terminals are brought into contact with each other by moving the second housing in the vertical direction with respect to the first housing to fit and detach. Therefore, the second housing needs a moving stroke in the vertical direction, and the height dimension of the power supply circuit cutoff device becomes large.

The present invention has been made in view of the above-mentioned circumstances, and an object thereof is to maintain high connection reliability between terminals electrically connected to each other, and to be compact and low while keeping costs down. The purpose of the present invention is to provide a power supply circuit cutoff device capable of making a backlash.

The above object of the present invention is achieved by the following configuration.
(1) A pair of housings, a switch portion provided in the housing, and an operating member for turning on / off the switch portions, and the switch portions are arranged along the bottom surface of the housing. Along the arrangement direction of the pair of terminals and the conductive member that is elastically urged and contacted with the terminal in the direction in which the contact portion contacts the pair of terminals to conduct the pair of terminals. It has an insulating moving member made of an insulating material provided so as to be movable, and the insulating moving member is interposed between the contact portion between the terminal and the conductive member by the operation of the operating member, and the switch portion is provided. Is moved between the cutoff position in which the switch is turned off and the energized position in which the switch portion is turned on by being displaced from the contact portion, and in the energized state in which the insulating moving member is arranged in the energized position, the above-mentioned The circuit of the switch unit is energized by turning it on together with the switch unit and turning it off in the temporary cutoff state in which the switch unit is maintained in the on state while the insulating moving member is displaced to the cutoff position. Equipped with a sub-switch unit that shuts off
A power supply circuit cutoff device characterized by that.

According to the power supply circuit cutoff device having the configuration of (1) above, the insulating moving member is moved by the operating member, so that the insulating moving member is inserted and removed between the contact portion between the terminal in contact with each other and the conductive member, and the switch portion. Is turned on and off. The insulating moving member inserted and removed between the contact portion between the terminal and the conductive member is made of an insulating material such as synthetic resin having a hardness lower than that of the terminal or the conductive member. Therefore, damage to the terminal and the conductive member when the insulating moving member is inserted and removed between the contact portion between the terminal and the conductive member can be suppressed as much as possible. As a result, as compared with the case where contacts such as terminals made of a conductive metal material slide with each other, it is possible to suppress scraping of the surface of the terminal and the conductive member, and it is possible to suppress the generation of scraped metal powder. In particular, when the surfaces of the terminal and the conductive member are plated, it is possible to suppress problems such as peeling of the plating, oxidation of the exposed base, and an increase in electrical resistance. Therefore, it is possible to suppress deterioration of the switch portion that turns the circuit on and off and maintain high reliability.
Further, the power supply circuit cutoff device of this configuration has a structure in which the switch portion is turned on and off by moving the insulating moving member along the arrangement direction of the terminals arranged along the bottom surface of the housing. Therefore, the power supply circuit cutoff device of the present configuration is a power supply circuit cutoff device having a conventional structure in which the first housing and the second housing move relative to each other in the vertical direction to fit and detach from each other and the switch portion is turned on and off. Compared to the above, it can be made smaller and shorter.
Further, according to the power supply circuit cutoff device having the configuration of (1) above, when the insulating moving member is in the temporary cutoff state while being displaced from the energization position to the cutoff position, the sub switch portion is turned off and the circuit is energized. The shut-off switch section is maintained in the on state. Therefore, by delaying the timing at which the switch unit is turned off with respect to the sub-switch unit, it is possible to suppress the generation of arcs, sparks, and the like due to the residual current of the circuit.

(2) The power supply circuit cutoff device according to (1) above, wherein the switch portion is housed in a storage space partitioned by the housing and covered with a periphery.

According to the power supply circuit cutoff device having the configuration of (2) above, the switch unit is housed in a house space formed by a housing and covered with a periphery. Therefore, it is possible to ensure safety by suppressing contact by the user with terminals and conductive members that are energized portions. As a result, the power supply circuit cutoff device of this configuration has a tactile prevention structure for the energized portion, as compared with the conventional structure in which the second housing is fitted and detached from the first housing and the switch portion is turned on and off. Can be eliminated, and cost reduction and miniaturization can be achieved by simplifying the structure.

( 3 ) The power supply circuit cutoff according to (1) or (2) above, wherein the terminal and the conduction member are covered with each other's contact surfaces by the insulating moving member arranged at the cutoff position. Device.

According to the power supply circuit cutoff device having the above configuration ( 3 ), the contact surface at the contact portion between the terminal and the conductive member is covered by the insulating moving member in the cutoff state. Therefore, as compared with the conventional structure in which the terminal and the conductive member are relatively moved to be brought into contact with each other, it is possible to eliminate the exposure of the contact surface of the contact portion in the cutoff state and suppress the formation and corrosion of the oxide film on the contact surface. This makes it possible to improve the reliability of the switch unit.

( 4 ) The operating member has a lever rotatably mounted on the housing, and the insulating moving member is moved by the rotational power of the lever (1) to ( 3 ). ) Is described in any one of the power supply circuit breakers.

According to the power supply circuit cutoff device having the above configuration ( 4 ), the insulating moving member can be easily moved with a light operating force by rotating the lever. This makes it possible to provide a power supply circuit cutoff device having better operability.

( 5 ) The above-mentioned ( 4 ), wherein a lever disengagement prevention mechanism is provided between the lever and the housing so that the lever can be detached from the housing only at the shutoff operation position. Power circuit breaker.

According to the power supply circuit cutoff device having the above configuration ( 5 ), a lever detachment prevention mechanism is provided for the housing so that the lever can be detached only at the cutoff operation position. Therefore, the lever rotated between the shutoff operation position and the energization operation position with respect to the housing can be attached to and detached from the housing. Therefore, in the cutoff operation position, only the lever can be detached from the housing, and the terminal and the conductive member remain covered by the housing. Therefore, unlike the first housing in the conventional power supply circuit cutoff device, there is no need for a tactile prevention structure for the female terminal of the first housing that is exposed when the second housing is detached. Further, the lever does not inadvertently come off during a rotation operation other than the shutoff operation position.

( 6 ) The lever disengagement prevention mechanism is provided on either one of the lever and the housing and a guide protrusion provided on the other of the lever and the housing, and engages with the guide protrusion. The power supply circuit cutoff device according to ( 5 ) above, wherein the housing is provided with a guide groove that allows the lever to be detached only at a cutoff operation position.

According to the power supply circuit cutoff device having the above configuration ( 6 ), the lever and the housing are provided with a guide protrusion and a guide groove matching the movement locus of the guide protrusion (lever attachment / detachment locus and rotation locus). , The lever disengagement prevention mechanism can be configured.

According to the present invention, there is provided a power supply circuit cutoff device capable of maintaining high connection reliability between terminals electrically connected to each other, and also being able to reduce the size and height while suppressing the cost. can.

The present invention has been briefly described above. Further, the details of the present invention will be further clarified by reading through the embodiments described below (hereinafter referred to as "embodiments") with reference to the accompanying drawings. ..

It is a figure which shows the power supply circuit cutoff device which concerns on 1st Embodiment of this invention, (a) is the perspective view in the cutoff state, (b) is the perspective view in the energized state. It is a perspective view of the power circuit cutoff device in the cutoff state shown in FIG. 1 (a) in the state where the lever is removed from the housing. It is an exploded perspective view of the power supply circuit cutoff device which concerns on this 1st Embodiment. FIG. 2 is a cross-sectional view taken along the line AA in FIG. It is sectional drawing of BB in (a) of FIG. It is a figure which shows the cut-off state of the power supply circuit cut-off device which concerns on this 1st Embodiment, (a) is a side view, (b) is a sectional view along the longitudinal direction. It is a figure which shows the energization state of the power supply circuit cutoff device which concerns on this 1st Embodiment, (a) is a side view, (b) is a sectional view along a longitudinal direction. It is a figure which shows the temporary cut-off state of the power supply circuit cut-off device which concerns on this 1st Embodiment, (a) is a side view, (b) is a sectional view along the longitudinal direction. It is a figure which shows the power supply circuit cutoff device which concerns on 2nd Embodiment of this invention, (a) is the perspective view in the cut-off state, (b) is the perspective view in the energized state. 9 is a perspective view of the power supply circuit cutoff device in the cutoff state shown in FIG. 9A in a state where the lever is removed from the housing. It is a side view which shows the cut-off state of the power supply circuit cut-off device which concerns on this 2nd Embodiment. (A) and (b) are side views showing the energized state and the temporary cutoff state of the power supply circuit cutoff device according to the second embodiment.

Hereinafter, examples of embodiments according to the present invention will be described with reference to the drawings.
1A and 1B are views showing a power supply circuit cutoff device 1 according to the first embodiment of the present invention, FIG. 1A is a perspective view in a cutoff state, and FIG. 1B is a perspective view in an energized state. Is. FIG. 2 is a perspective view showing a state in which the lever 80 is removed from the housing 10 in the power supply circuit cutoff device 1 in the cutoff state.

As shown in FIGS. 1 (a) and 1 (b) and FIG. 2, the power supply circuit cutoff device 1 according to the first embodiment includes a housing 10 and a lever (operating member) 80. The lever 80 is rotatable with respect to the housing 10. The lever 80 is rotated with respect to the housing 10 between the shutoff operation position (position (a) in FIG. 1) and the energization operation position (position (b) in FIG. 1). Further, the lever 80 is detachable from the housing 10 in a state of being arranged at the shutoff operation position.

The power supply circuit cutoff device 1 of the first embodiment cuts off the energization between the power supply unit and the load in order to ensure work safety in maintenance of the electric system in a vehicle such as an electric vehicle or a hybrid vehicle. , A so-called service plug. Specifically, when the lever 80 is arranged at the energization operation position with respect to the housing 10, the power supply unit and the load can be energized, and the lever 80 is arranged at the cutoff operation position with respect to the housing 10. , The power supply between the power supply and the load is cut off. Then, the lever 80 arranged at the shutoff operation position is removed from the housing 10, so that the cutoff state between the power supply unit and the load is maintained.

FIG. 3 is an exploded perspective view of the power supply circuit cutoff device 1 according to the first embodiment. FIG. 4 is a cross-sectional view taken along the line AA in FIG. FIG. 5 is a cross-sectional view taken along the line BB in FIG. 1A.

As shown in FIGS. 3 to 5, the housing 10 includes a case 11 and a cover 60. The case 11 and the cover 60 are molded from a synthetic resin material having electrical insulation. The case 11 has a flange portion 12 that projects to the outer periphery. A bolt insertion hole 12a is formed in the flange portion 12. The housing 10 is attached to the power supply device or the like by screwing the bolt (not shown) inserted through the bolt insertion hole 12a into the bolt hole of the case of the power supply device or the like.

The case 11 has a storage cylinder portion 13 whose upper side is open. The accommodating cylinder portion 13 is formed in the shape of a rectangular cylinder having a rectangular shape in a plan view. The accommodating cylinder portion 13 has a pair of side plate portions 14 and a pair of end plate portions 15. A support shaft 16 is provided so as to project from the side plate portion 14 constituting the accommodation cylinder portion 13. Further, a notch 17 is formed in the side plate portion 14. The notch 17 is formed in an L shape having an insertion portion 18 formed along the vertical direction and a slide portion 19 formed along the horizontal direction from the lower end of the insertion portion 18. Further, a pair of main lock claws 21 projecting laterally are formed near one end of the side plate portion 14 in the accommodating cylinder portion 13. Further, a pair of sublock claws 22 are formed on the upper edge of the end plate portion 15 on one end side of the accommodating cylinder portion 13. Further, the side plate portion 14 constituting the accommodating cylinder portion 13 is formed with locking claws 23 at positions near the four corners of the accommodating cylinder portion 13 on the inner surface side thereof.

A terminal block 25 erected from the flange portion 12 is formed on one end side of the case 11, and the terminal block 25 is provided with a pair of sub-terminals 26. A signal line 3 is connected to these sub-terminals 26, and the sub-terminals 26 are inserted and mounted on the terminal block 25 from the lower side of the case 11.

A pair of terminals 30, an insulating plate (insulating moving member) 40, and a conductive plate (conducting member) 50 are assembled to the accommodating cylinder portion 13 of the case 11 and covered with a cover 60.

The terminals 30 are formed in a substantially L-shape in a plan view, and two terminals 30 are incorporated in the accommodating cylinder portion 13. The terminal 30 is made of a bus bar made of a conductive metal material such as copper or a copper alloy, and these terminals 30 are surface-treated, for example, by tin plating.

The terminal 30 has an electric wire connecting portion 32, and a power supply line 2 extending from a power supply device or the like is connected to the electric wire connecting portion 32. Further, each terminal 30 has a terminal piece (contact portion) 33 extending in a direction orthogonal to the electric wire connecting portion 32. The terminal piece 33 is connected to the electric wire connecting portion 32 via the connecting portion 34, and is arranged above the electric wire connecting portion 32. These terminals 30 are fixed to the bottom of the accommodating cylinder portion 13 by fastening fasteners 35 such as nuts to bolts (not shown) inserted into the holes 4a of the connection terminal 4 at the end of the power line 2. Will be done. Then, by fixing these terminals 30 to the bottom of the accommodating cylinder portion 13, the terminal pieces 33 are arranged at intervals along the bottom surface 10a of the accommodating cylinder portion 13.

The insulating plate 40 is an insulating moving member formed of a synthetic resin material (insulating material) having electrical insulation. The insulating plate 40 is formed in a rectangular plate shape in a plan view, and engaging pins 41 are projected on both sides thereof. The insulating plate 40 is assembled inside the accommodating cylinder portion 13 while passing the engaging pin 41 through the insertion portion 18 of the notch 17 of the accommodating cylinder portion 13. By assembling the insulating plate 40 to the accommodating cylinder portion 13, the end portion of the engaging pin 41 of the insulating plate 40 is projected from the outer surface of the side plate portion 14 of the accommodating cylinder portion 13.

Further, when the insulating plate 40 is assembled inside the accommodating cylinder portion 13, the engaging pin 41 can move along the slide portion 19 of the notch 17. As a result, the insulating plate 40 can be slidable within the movable range of the engaging pin 41 in the sliding portion 19. Specifically, the insulating plate 40 can be slidable in a direction toward one end side of the case 11 and a direction toward the other end side of the case 11 in a state of being incorporated inside the accommodating cylinder portion 13. The direction toward one end side of the case 11 is the cutoff direction SA, and the direction toward the other end side of the case 11 is the energization direction SB (see FIG. 4). The position where the insulating plate 40 is slid in the cutoff direction SA and arranged on one end side of the case 11 is the cutoff position, and the position where the insulating plate 40 is slid in the energization direction SB and arranged on the other end side of the case 11 is the energization position. Has been done.

The insulating plate 40 is formed with a window portion 42 penetrating the front and back in the center thereof. In the insulating plate 40, one end side and the other end side of the window portion 42 sandwiching the window portion 42 are each a shielding portion 43. A guide surface 44 is formed on each of the edges of the shielding portion 43 on the SA side in the blocking direction. These guide surfaces 44 are inclined surfaces that incline upward toward the SB side in the energization direction.

Further, the insulating plate 40 is formed with two guide walls 45 along the sliding direction on the upper surface thereof. These guide walls 45 are formed in the vicinity of both side portions sandwiching the window portion 42.

The conduction plate 50 is a conduction member formed in a rectangular plate shape in a plan view. The conduction plate 50 is made of a bus bar made of a conductive metal material such as copper or a copper alloy, and is subjected to surface treatment such as tin plating. The conduction plate 50 has contact pieces (contact portions) 51 that are curved downward and project at both ends thereof. These contact pieces 51 have a protruding dimension larger than the thickness of the insulating plate 40.

The conduction plate 50 has a width dimension smaller than the distance between the guide walls 45 of the insulating plates 40, and is arranged between the guide walls 45 from the upper side of the insulating plates 40.
Further, the conduction plate 50 is formed with a holding hole 52 at the center thereof. A fixing bolt 71 is inserted through the holding hole 52 from the lower side.

The cover 60 is formed in a box shape with the lower side open. The cover 60 has a top plate portion 61, a pair of side plate portions 62, and a pair of end face plate portions 63. The cover 60 has an outer shape slightly smaller than the inner shape of the accommodating cylinder portion 13 of the case 11 in a plan view thereof, and is fitted and assembled from the upper side with respect to the accommodating cylinder portion 13.

A lock arm 65 is formed in the vicinity of both ends of the side plate portion 62 of the cover 60, and by assembling the cover 60 into the accommodating cylinder portion 13, the lock arm 65 is locked to the locking claw 23. As a result, the cover 60 assembled in the accommodating cylinder portion 13 is maintained in a state in which the lock arm 65 is locked by the locking claw 23 and is assembled in the accommodating cylinder portion 13. Further, the side plate portion 62 of the cover 60 is formed with a sealing projection 66 near one end. When the cover 60 is assembled in the accommodating cylinder portion 13, the sealing protrusion 66 is fitted into the insertion portion 18 of the notch 17 formed in the accommodating cylinder portion 13 to seal the cover 60. As a result, the engaging pin 41 of the insulating plate 40 inserted into the notch 17 from the insertion portion 18 is prevented from coming off from the notch 17.

Further, the cover 60 has a nut fixing portion 67 and an annular holding wall 68 formed with a gap around the nut fixing portion 67 on the inner surface side of the upper surface plate portion 61. A nut 72 is insert-molded in the nut fixing portion 67.

A compression coil spring 74 is inserted into the gap between the nut fixing portion 67 and the annular holding wall 68 to be accommodated and held in the cover 60. Further, a fixing bolt 71 inserted from below into the holding hole 52 of the conduction plate 50 is screwed into and fastened to the nut 72 fixed to the nut fixing portion 67. As a result, the conduction plate 50 is displaceably held in a direction approaching the cover 60 against the elastic urging force of the compression coil spring 74.

When the cover 60 is assembled to the accommodating cylinder portion 13 of the case 11, the head 71a of the fixing bolt 71 fastened to the nut 72 of the nut fixing portion 67 of the cover 60 enters the window portion 42 of the insulating plate 40. .. Then, in this state, the head 71a of the fixing bolt 71 is arranged so that the head seat surface is flush with or slightly lower than the upper surface of the shielding portion 43 of the insulating plate 40 (see FIG. 4).

In a state where the lever 80 is arranged at the cutoff operation position with respect to the housing 10 and is detachable, the insulating plate 40 is arranged at the cutoff position (see (a) in FIG. 1). In this state, the shielding portion 43 of the insulating plate 40 is interposed between the contact portions of the terminal piece 33 of the terminal 30 and the contact piece 51 of the conduction plate 50, respectively, and the pair of terminals 30 are de-energized, and each terminal is de-energized. The power lines 2 connected to the 30 are not connected to each other. Then, at the cutoff operation position, only the lever 80 can be detached from the housing 10, and the terminal 30 and the conduction plate 50 remain covered by the housing 10.

Then, when the insulating plate 40 arranged at the cutoff position is slid to the current-carrying position SB by the rotation operation of the lever 80 and is placed at the current-carrying position, each shielding portion 43 of the insulating plate 40 becomes a terminal piece of the terminal 30. It is extracted from the contact portion between the contact portion 33 and the contact piece 51 of the conduction plate 50. As a result, the contact piece 51 of the conduction plate 50 elastically urged in the direction of contact with the pair of terminals 30 by the compression coil spring 74 comes into contact with the terminal piece 33 of the terminal 30. As a result, the pair of terminals 30 are energized via the conduction plate 50, and the power supply lines 2 connected to the terminals 30 are electrically connected to each other.

Further, when the insulating plate 40 arranged in the energized position is slid and moved in the cutoff direction SA by the rotation operation of the lever 80 and is placed in the cutoff position, each shielding portion 43 of the insulating plate 40 becomes a terminal of the terminal 30. It penetrates between the contact portions between the piece 33 and the contact piece 51 of the conduction plate 50 and intervenes. As a result, the pair of terminals 30 are in a non-energized state, and the power supply lines 2 connected to the respective terminals 30 are electrically disconnected. At this time, the conduction plate 50 can be displaced in the direction approaching the cover 60 against the elastic urging force of the compression coil spring 74 in the direction approaching the terminal 30, and the insulating plate 40 can slide and move smoothly. ..

The lever 80 attached to and detached from the housing 10 is formed from a synthetic resin material, and is a substantially U-shaped lever having a pair of arm portions 81 and a connecting portion 82. One end of the arm portion 81 is connected by a connecting portion 82. The arm portion 81 has a bearing hole 84, and a support shaft 16 formed in the case 11 of the housing 10 is inserted into the bearing hole 84 through a notch groove and engaged with the bearing hole 84. As a result, the lever 80 is mounted on the housing 10 and is rotatable about the axis of the support shaft 16.

A locking piece 16a extending upward from the accommodating cylinder portion 13 intersecting the axis is formed at the tip of the support shaft 16. Further, a locking recess 84a is recessed in the opening edge of the bearing hole 84 on the outer surface of the arm portion 81. The locking piece 16a of the support shaft 16 inserted into the bearing hole 84 engages with the locking recess 84a in a state where the lever 80 is not arranged at the detachable blocking operation position with respect to the housing 10. It is in a state where the portion 81 is prevented from coming off.

Further, a cam groove 85 is formed on the inner surface side of the pair of arm portions 81 of the lever 80. By mounting the lever 80 on the housing 10, the cam groove 85 is engaged with the engaging pin 41 which is assembled to the accommodating cylinder portion 13 and is movable within the range of the slide portion 19 of the notch 17.

The lever 80 is engaged with the cam groove 85 by being rotated between the shutoff operation position (see (a) in FIG. 1) and the energization operation position (see (b) in FIG. 1). The matching pin 41 is moved within the range of the slide portion 19. As a result, the insulating plate 40 is slid and moved in the accommodating cylinder portion 13.

As shown in FIG. 4, the arm portion 81 of the lever 80 is formed with a main lock step portion 86 in the vicinity of the connecting portion 82. The main lock claw 21 formed on the accommodating cylinder portion 13 of the case 11 engages with these main lock step portions 86. The main lock portion MR is configured from the main lock claw 21 and the main lock step portion 86 (see (a) in FIG. 1). In this main lock portion MR, the main lock claw 21 engages with the main lock step portion 86 in a state where the lever 80 is arranged at the energization operation position to lock the lever 80 with respect to the housing 10, and the lever 80 rotates. To regulate. Then, in the power supply circuit cutoff device 1, the state in which the lever 80 is arranged at the energization operation position and locked by the main lock portion MR is set as the energization state (see (b) in FIG. 1). Further, in the power supply circuit cutoff device 1, the state in which the lever 80 is arranged at the cutoff operation position is regarded as the cutoff state (see (a) in FIG. 1).

The connecting portion 82 of the lever 80 is formed with a sublock arm 92 having two sublock protrusions 91. Further, the sublock release portion 93 is formed on the subblock arm 92.

The subblock protrusion 91 of the subblock arm 92 can be locked to the subblock claw 22 formed in the accommodating cylinder portion 13 of the case 11. Then, the sublock portion SR is configured from the subblock claw 22 and the subblock protrusion 91 (see FIG. 4). In this sub-block SR, the sub-block protrusion 91 locks the sub-block claw 22 while the lever 80 is rotating from the energization operation position to the cutoff operation position, and restricts the rotation of the lever 80. The position where the lever 80 is locked by the sublock portion SR during the rotation from the energization operation position to the cutoff operation position is set as the temporary cutoff operation position. Then, in the power supply circuit cutoff device 1, the state in which the lever 80 is locked at the temporary cutoff operation position is set as the temporary cutoff state. In this temporary shutoff state, the sublock protrusion 91 is released from the sublock claw 22 by elastically deforming the subblock arm 92 by pressing the subblock release portion 93. As a result, the lever 80 locked at the temporary shutoff operation position can be rotated toward the shutoff operation position again.

Further, a terminal holding portion 95 is formed in the connecting portion 82 of the lever 80, and the short terminal 96 is held in the terminal holding portion 95. The short terminal 96 has a pair of tab portions 97. The pair of tab portions 97 of the short terminal 96 can be connected to the pair of sub terminals 26 of the housing 10, respectively. When the pair of tab portions 97 of the short terminal 96 are connected to the pair of sub terminals 26, the signal lines 3 connected to the pair of sub terminals 26 are electrically connected to each other via the short terminal 96. ..

In the power supply circuit cutoff device 1, the main switch portion (switch portion) MSw is composed of the terminal piece 33 of the terminal 30, the shielding portion 43 of the insulating plate 40, and the contact piece 51 of the conduction plate 50, and the sub terminal 26. The sub switch portion SSw is configured from the short terminal 96 (see FIGS. 4 and 5). The main switch portion MSw is housed in a housing space S of a housing 10 including a space surrounded by a case 11 and a cover 60.

In the power supply device or the like provided with the power supply circuit cutoff device 1 of the first embodiment, the main switch unit MSw is turned on and the pair of power supply lines 2 are electrically connected to each other to form a power supply circuit. A signal circuit is formed by turning on the sub switch unit SSw and electrically connecting the pair of signal lines 3 to each other. In a power supply device or the like provided with the power supply circuit cutoff device 1, even if the main switch unit MSw is turned on and the power supply circuit is formed, unless the sub switch unit SSw is turned on and the signal circuit is formed. It is configured so that the power supply circuit is not energized. That is, the power supply circuit can be energized only when both the main switch section MSw and the sub switch section SSw are turned on.

Next, the operation of the power supply circuit cutoff device 1 will be described.
6A and 6B are views showing a cutoff state of the power supply circuit cutoff device 1 according to the first embodiment, FIG. 6A is a side view, and FIG. 6B is a cross-sectional view taken along the longitudinal direction. be. 7A and 7B are views showing an energized state of the power supply circuit cutoff device 1 according to the first embodiment, FIG. 7A is a side view, and FIG. 7B is a cross-sectional view taken along the longitudinal direction. be. 8A and 8B are views showing a temporary cutoff state of the power supply circuit cutoff device according to the first embodiment, FIG. 8A is a side view, and FIG. 8B is a cross-sectional view taken along the longitudinal direction. be.

(Energization operation)
First, as shown in FIGS. 6A and 6B, the lever 80 is attached to the housing 10 in the cutoff state in which the insulating plate 40 is arranged at the cutoff position. Specifically, the notch groove communicating with the bearing hole 84 of the arm portion 81 of the lever 80 is engaged with the support shaft 16 of the case 11 from above and arranged at the cutoff operation position. Then, the engaging pin 41 enters the cam groove 85 of the arm portion 81 of the lever 80.

Next, as shown in FIGS. 7A and 7B, the lever 80 is rotated toward the energization operation position. Then, the engaging pin 41 that has entered the cam groove 85 is displaced along the slide portion 19 of the notch 17, so that the insulating plate 40 arranged at the cutoff position is slid and moved in the energization direction SB. As a result, the insulating plate 40 is placed in the energized position and is in an energized state. Specifically, the shielding portion 43 of the insulating plate 40 is pulled out from between the contact portions between the terminal piece 33 of the terminal 30 and the contact piece 51 of the conduction plate 50, and the contact piece 51 comes into contact with the terminal piece 33. That is, the main switch portion MSw is turned on, the pair of terminals 30 are electrically connected to each other via the conduction plate 50, and the power supply lines 2 connected to each terminal 30 are electrically connected to each other. Further, the tab portion 97 of the short terminal 96 is connected to the sub terminal 26. That is, the sub switch unit SSw is turned on, and the signal lines 3 connected to the sub terminal 26 are electrically connected to each other via the short terminal 96.

Further, by changing from the shutoff state to the energized state, in the main lock portion MR, the main lock step portion 86 of the lever 80 is locked to the main lock claw 21 of the case 11. As a result, the lever 80 is locked in a state of being arranged at the energization operation position, and the rotation of the lever 80 is restricted. As described above, in the energized state, the main lock portion MR regulates the rotation of the lever 80, so that the energized state is maintained.

(Blocking operation)
The lever 80 arranged at the energization operation position (see FIGS. 7A and 7B) is grasped and pulled up. Then, the main lock step portion 86 of the lever 80 is disengaged from the main lock claw 21 of the case 11, the lock of the lever 80 by the main lock portion MR that maintains the energized state is released, and the lever 80 becomes rotatable.

The rotatable lever 80 is rotated toward the shutoff operation position. As shown in FIG. 8, when the rotating lever 80 reaches the temporary shutoff operation position, the sublock protrusion 91 constituting the sublock portion SR locks the sublock claw 22 of the case 11. The lever 80 is locked at the temporary shutoff operation position to restrict rotation. As a result, the housing 10 is temporarily shut off.

When the temporary cutoff state is set, the tab portion 97 of the short terminal 96 is pulled out from each sub terminal 26. That is, the sub switch unit SSw is turned off, and the electrical connection between the signal lines 3 is released.

In the temporary cutoff state, the contact piece 51 of the conduction plate 50 is in a state of continuous contact with the terminal piece 33 of the terminal 30, and the pair of terminals 30 are electrically connected to each other. That is, the main switch unit MSw is continuously turned on, and the electrical connection state between the power supply lines 2 connected to the terminal 30 is continued.

From this temporary cutoff state, the sublock release unit 93 of the sublock unit SR is pressed to release the lock by the sublock unit SR. Then, the rotatable lever 80 is rotated again toward the shutoff operation position. Then, as the lever 80 rotates, the engaging pin 41 in the cam groove 85 is displaced along the slide portion 19 of the notch 17, and the insulating plate 40 arranged at the energized position is slid and moved in the cutoff direction SA. Ru. As a result, the insulating plate 40 is placed in the cutoff position (see (a) and (b) in FIG. 6).

In this way, when the insulating plate 40 is slid from the temporary cutoff state to the cutoff position and becomes the cutoff state, the shielding portion 43 of the insulating plate 40 is between the contact portion between the terminal piece 33 of the terminal 30 and the contact piece 51 of the conduction plate 50. The contact piece 51 enters, is pushed up by the guide surface 44 of the shielding portion 43, and is separated from the terminal piece 33 of the terminal 30. Then, a shielding portion 43 of the insulating plate 40 is interposed between the contact portions of the contact piece 51 and the terminal piece 33, the continuity between the pair of terminals 30 is released, the main switch portion MSw is turned off, and the pair of power supplies is turned off. The electrical connection between the wires 2 is released.

As described above, according to the power supply circuit cutoff device 1 of the first embodiment, the main switch portion MSw is in the energized state in which the lever 80 is arranged at the energized operation position in the main lock portion MR (FIG. 7A, FIG. The state shown in (b)) and the temporary shutoff state (states shown in FIGS. 8A and 8) in which the lever 80 is arranged at the temporary shutoff operation position in the sublock unit SR are turned on. Then, the main switch unit MSw is turned off in the cutoff state (the state shown in FIGS. 6A and 6) in which the lever 80 is arranged at the cutoff operation position.
Further, the sub-switch portion SSw is turned on in the energized state (the state shown in FIGS. 7A and 7) in which the lever 80 is arranged at the energized operation position in the main lock portion MR. Then, in the sub-switch unit SSw, the lever 80 is placed in the temporary cutoff operation position in the sub-block unit SR (the state shown in FIGS. 8A and 8) and the lever 80 is in the cutoff operation position. It is turned off in the arranged cutoff state (the state shown in (a) and (b) of FIG. 6).

Therefore, after the sub-switch unit SSw is turned off and the electrical connection state between the pair of signal lines 3 is released, the lock by the sub-switch unit SR is not released, or the main switch unit MSw is turned off and the pair is released. The electrical connection between the power lines 2 cannot be released. As a result, it is possible to suppress the generation of arcs, sparks, etc. due to the residual current generated by the disconnection of the power supply lines 2 immediately after the disconnection of the pair of signal lines 3.

As described above, according to the power supply circuit cutoff device 1 according to the first embodiment, the insulating plate 40 is slidably moved by the lever 80, so that the terminal pieces 33 and the conduction plate 50 of the terminals 30 that are in contact with each other are slid. The shielding portion 43 of the insulating plate 40 is inserted and removed between the contact portions with the contact portion 51 of the main switch portion MSw, and the main switch portion MSw is operated on and off. The insulating plate 40 into which the shielding portion 43 is inserted / removed between the contact portion between the terminal piece 33 of the terminal 30 and the contact piece 51 of the conductive plate 50 is a synthetic resin material having a hardness lower than that of the terminal 30 or the conductive plate 50. Consists of. Therefore, damage to the terminal 30 and the conduction plate 50 when the insulating plate 40 is inserted and removed between the contact portions between the terminal piece 33 and the contact piece 51 can be suppressed as much as possible. As a result, it is possible to suppress surface scraping of the terminal piece 33 of the terminal 30 and the contact piece 51 of the conduction plate 50 as compared with the case where contacts such as terminals made of a conductive metal material slide with each other, and the scraped metal can be suppressed. The generation of powder can be suppressed. In particular, when the surfaces of the terminal 30 and the conduction plate 50 are plated, problems such as peeling of the plating and oxidation of the exposed substrate and an increase in electrical resistance can be suppressed. Therefore, it is possible to suppress deterioration of the main switch portion MSw that turns the circuit on and off and maintain high reliability.

Further, in the power supply circuit cutoff device 1 of the first embodiment, the insulating plate 40 is slid and moved along the arrangement direction of the terminal pieces 33 of the terminals 30 arranged along the bottom surface 10a of the housing 10. It is a structure that turns MSw on and off. Therefore, in the power supply circuit cutoff device 1 of the present configuration, the power supply circuit cutoff of the conventional structure in which the switch portion is turned on and off by fitting and detaching from each other by the relative movement of the first housing and the second housing in the vertical direction. It can be made smaller and shorter than the device.

Further, according to the power supply circuit cutoff device 1 of the first embodiment, the main switch portion MSw is housed in the housed space S which is partitioned by the housing 10 and covered with the surroundings. Therefore, the user's contact with the terminal 30 and the conduction plate 50, which are energized portions, is suppressed, and safety can be ensured. As a result, the power supply circuit cutoff device 1 of the first embodiment has the same with respect to the energized portion as compared with the conventional structure in which the second housing is fitted and detached from the first housing and the switch portion is turned on and off. The tactile prevention structure can be eliminated, and the cost can be reduced and the size can be reduced by simplifying the structure.

Further, according to the power supply circuit cutoff device 1 of the first embodiment, when the insulating plate 40 is in the temporary cutoff state while being displaced from the energization position to the cutoff position, the sub switch portion SSw is turned off and the circuit is energized. The main switch unit MSw, which has been cut off, is maintained in the ON state. Therefore, by delaying the timing at which the main switch portion MSw is turned off with respect to the sub switch portion SSw, it is possible to suppress the generation of arcs, sparks, and the like due to the residual current of the circuit.

Further, according to the power supply circuit cutoff device 1 according to the first embodiment, the contact surface between the terminal piece 33 of the terminal 30 and the contact piece 51 of the conduction plate 50 is covered by the shield portion 43 of the insulating plate 40 in the cutoff state. Will be. Therefore, as compared with the conventional structure in which the terminal 30 and the conduction plate 50 are relatively moved and separated from each other, the contact surface of the contact portion in the cutoff state is not exposed, and the formation and corrosion of the oxide film on the contact surface can be suppressed. As a result, the reliability of the main switch unit MSw can be improved.

Further, according to the power supply circuit cutoff device 1 according to the first embodiment, the insulating plate 40 can be easily slid and moved with a light operating force by rotating the lever 80. Thereby, it is possible to provide the power supply circuit cutoff device 1 having more excellent operability.

9A and 9B are views showing the power supply circuit cutoff device 1A according to the second embodiment of the present invention, in which FIG. 9A is a perspective view in a cutoff state, and FIG. 9B is a perspective view in an energized state. FIG. 10 is a perspective view of the power supply circuit cutoff device 1A in the cutoff state shown in FIG. 9A in a state where the lever 80A is removed from the housing 10. FIG. 11 is a side view showing a cutoff state of the power supply circuit cutoff device 1A according to the second embodiment. 12A and 12B are side views showing an energized state and a temporary cutoff state of the power supply circuit cutoff device 1A according to the second embodiment.
The components of the power supply circuit cutoff device 1A which are substantially the same as the components of the power supply circuit cutoff device 1 according to the first embodiment are designated by the same reference numerals, and detailed description thereof will be omitted.

As shown in FIGS. 9 and 10, the power supply circuit cutoff device 1A according to the second embodiment includes a housing 10A and a lever (operating member) 80A.
The housing 10A includes a case 11A and a cover 60. A support shaft 16 is projected from the pair of side plate portions 14 constituting the accommodating cylinder portion 13 of the case 11A, and a notch 17 is formed. Further, a guide groove 20 is formed on the outer surface side of the pair of side plate portions 14. The guide groove 20 is formed in a substantially J-shape having an insertion groove 20a formed along the vertical direction and an arc groove 20b extending in an arc shape along the horizontal direction from the lower end of the insertion groove 20a.

The lever 80A attached to and detached from the housing 10A is formed from a synthetic resin material, and is a substantially U-shaped lever having a pair of arm portions 81 and a connecting portion 82. The arm portion 81 has a bearing hole 84, and a support shaft 16 formed in the case 11A of the housing 10A is inserted into the bearing hole 84 through a notch groove and engaged with the bearing hole 84. As a result, the lever 80A is mounted on the housing 10A and is rotatable about the axis of the support shaft 16.

A cam groove 85A is formed in the pair of arm portions 81 of the lever 80A according to the second embodiment. By mounting the lever 80A on the housing 10A, the cam groove 85A is engaged with the engaging pin 41 which is assembled to the accommodating cylinder portion 13 and is movable within the range of the slide portion 19 of the notch 17.

The lever 80A is rotated between the shutoff operation position (see (a) in FIG. 9) and the energization operation position (see (b) in FIG. 9) to rotate the lever 80A with the lever 80 of the first embodiment. Similarly, the engaging pin 41 engaged with the cam groove 85A is moved within the range of the slide portion 19. As a result, the insulating plate 40 is slid and moved in the accommodating cylinder portion 13. Further, as shown in FIG. 10, the lever 80A is detachable from the housing 10A in a state of being arranged at the shutoff operation position.

Further, between the lever 80A and the housing 10A in the power supply circuit cutoff device 1A according to the second embodiment, a lever disconnection prevention mechanism is provided so that the lever 80A can be detached from the housing 10A only at the cutoff operation position. ing.
The lever disengagement prevention mechanism of the second embodiment is provided in the guide protrusion 87 provided on the lever 80A and the housing 10A, and by engaging with the guide protrusion 87, the lever 80A is cut off from the housing 10A only at the shutoff operation position. It is provided with a guide groove 20 that can be detached by.

As shown in FIG. 10, a guide protrusion 87 is formed on the inner surface side of the pair of arm portions 81 of the lever 80A. The guide protrusion 87 engages with the guide groove 20 formed in the pair of side plate portions 14 in the case 11A of the housing 10A.

That is, in the insertion groove 20a of the guide groove 20, when the lever 80A is attached to and detached from the housing 10A, the support shaft 16 formed in the case 11A is inserted from the notch groove of the arm portion 81 and engaged with the bearing hole 84. It is a linear groove parallel to the vertical movement locus (lever attachment / detachment locus) of the lever 80A.
Further, the arc groove 20b of the guide groove 20 has an arc-shaped movement locus (rotation) of the guide protrusion 87 projecting from the arm portion 81 when the lever 80A is rotated around the axis of the support shaft 16. It is an arc-shaped groove that fits the locus).

Therefore, as shown in FIG. 11, when the lever 80A is arranged at the cutoff operation position, the guide protrusion 87 of the lever 80A is a guide groove 20 parallel to the notch groove communicating with the bearing hole 84 of the arm portion 81. It is located in the insertion groove 20a, and the lever 80A can be moved along the notch groove of the arm portion 81 in the vertical direction. Therefore, the lever 80A can be attached to and detached from the housing 10A.

Then, as shown in FIG. 12A, when the lever 80A is arranged at the energization operation position, the guide protrusion 87 of the lever 80A is located in the arc groove 20b of the guide groove 20, and the arm portion 81. The movement of the lever 80A along the notch groove in the detaching direction is restricted. Therefore, the lever 80A cannot be detached from the housing 10A, and the lever 80A is prevented from being inadvertently dropped. Further, as shown in FIG. 12B, the guide protrusion 87 of the lever 80A is located in the arc groove 20b of the guide groove 20 even when the lever 80A is arranged at the temporary cutoff operation position. Therefore, the lever 80A is restricted from moving in the detaching direction along the notch groove of the arm portion 81 and cannot be attached to or detached from the housing 10A, so that the lever 80A is prevented from being inadvertently dropped.

Further, in the power supply circuit cutoff device 1A according to the second embodiment, the state in which the lever 80A is arranged at the energization operation position and locked by the main lock portion MR is regarded as the energization state (see (b) in FIG. 9). .. Further, in the power supply circuit cutoff device 1A, the state in which the lever 80A is arranged at the cutoff operation position is regarded as the cutoff state (see (a) in FIG. 9). That is, the operation of the power supply circuit cutoff device 1A according to the second embodiment is the same as the operation of the power supply circuit cutoff device 1 according to the first embodiment. Therefore, the power supply circuit cutoff device 1A according to the second embodiment maintains high connection reliability between terminals electrically connected to each other, similarly to the power supply circuit cutoff device 1 according to the first embodiment. Moreover, it is possible to reduce the size and height while keeping costs down.

Further, the power supply circuit cutoff device 1A according to the second embodiment is provided with a lever detachment prevention mechanism that allows the lever 80A to be detached from the housing 10A only at the cutoff operation position. Therefore, the lever 80A that is rotated between the shutoff operation position and the energization operation position with respect to the housing 10A can be attached to and detached from the housing 10A. Therefore, at the cutoff operation position, only the lever 80A can be separated from the housing 10A, and the terminal 30 and the conduction plate 50 remain covered by the housing 10A. Therefore, unlike the first housing in the conventional power supply circuit cutoff device, there is no need for a tactile prevention structure for the female terminal of the first housing that is exposed when the second housing is detached. Further, the lever 80A does not inadvertently disengage during a rotation operation other than the shutoff operation position.

Further, according to the power supply circuit cutoff device 1A according to the second embodiment, the guide protrusion 87 and the guide groove 20 that matches the movement locus of the guide protrusion 87 (the attachment / detachment locus and the rotation locus of the lever 80A) are provided with the lever 80A and the guide groove 20. With a simple structure provided in the housing 10A, a lever detachment prevention mechanism can be configured.

The present invention is not limited to the above-described embodiment, and can be appropriately modified, improved, and the like. In addition, the material, shape, size, number, arrangement location, etc. of each component in the above-described embodiment are arbitrary as long as the present invention can be achieved, and are not limited.

For example, in the power supply circuit cutoff devices 1 and 1A of the above-described embodiment, substantially U-shaped levers 80 and 80A that are rotated with respect to the housing 10 are provided as operating members. However, if the mechanism is such that the insulating moving member (insulating plate 40) can be moved along the arrangement direction of the pair of terminals, the configurations of the operating member and the insulating moving member may be various forms based on the gist of the present invention. Of course, it can be taken.

In the power supply circuit cutoff devices 1 and 1A of the above embodiment, the compression coil spring 74 is provided as an elastic member that urges the conduction plate 50, which is a conduction member, toward the terminal 30 side and presses the contact piece 51 against the terminal piece 33. However, the power supply circuit cutoff device of the present invention is not limited to the structure provided with the compression coil spring 74. For example, if the bending stroke of the contact piece 51 can be sufficiently secured, the contact piece 51 may be pressed against the terminal piece 33 by the elastic force of the conduction plate 50 itself, and a separate elastic member may be omitted.
Further, in case the power supply circuit cutoff devices 1 and 1A become inoperable due to damage of the levers 80 and 80A, the insulating plate 40 springs to the cutoff direction SA in which the main switch portion MSw is turned off. It may be urged by an elastic member such as.

Further, in the power supply circuit cutoff device 1A of the second embodiment, the lever disengagement prevention mechanism is configured by the guide protrusion 87 provided on the lever 80A and the guide groove 20 provided on the housing 10A. However, the lever disengagement prevention mechanism of the present invention is not limited to this, and the guide protrusion provided on either one of the lever and the housing and the guide groove provided on the other of the lever and the housing are the lever and the housing. It suffices if it is provided between.

Here, the features of the above-described embodiment of the power supply circuit cutoff device according to the present invention are briefly summarized and listed below in [1] to [7], respectively.
[1] Housing (10, 10A) and
A switch unit (main switch unit MSw) provided in the housing (10, 10A) and
An operating member (lever 80, 80A) that turns the switch unit (main switch unit MSw) on and off, and
Equipped with
The switch unit (main switch unit MSw) is
A pair of terminals (terminals 30) arranged along the bottom surface (10a) of the housing (10, 10A),
A conductive member that is elastically urged and brought into contact with the pair of terminals (30) in the direction in which the contact portions (terminal piece 33, contact piece 51) come into contact with each other to conduct the pair of terminals (30) with each other. (Conduction plate 50) and
An insulating moving member (insulating plate 40) made of an insulating material provided so as to be movable along the arrangement direction of the pair of terminals (30).
Have,
The insulating moving member (insulating plate 40) is interposed between the contact portion between the terminal (30) and the conductive member (conducting plate 50) by the operation of the operating member (lever 80, 80A) and the switch portion. It is characterized in that it is moved between a cutoff position in which (main switch section MSw) is turned off and an energized position in which the switch section (main switch section MSw) is turned on by being separated from the contact section. Power circuit cutoff device (1,1A).
[2] The switch portion (main switch portion MSw) is housed in a storage space (S) partitioned by the housing (10, 10A) and covered with the surroundings [1]. ]. The power supply circuit cutoff device (1,1A).
[3] In the energized state in which the insulating moving member (insulating plate 40) is arranged at the energizing position, the switch portion (main switch portion MSw) is turned on together with the insulating moving member (insulating plate 40). In the temporary cutoff state in which the switch section (main switch section MSw) is maintained in the on state while being displaced to the cutoff position, the power supply to the circuit of the switch section (main switch section MSw) is cut off by turning it off. The power supply circuit cutoff device (1, 1A) according to the above [1] or [2], which comprises a sub-switch unit (SSw).
[4] The terminal (30) and the conduction member (conduction plate 50) are characterized in that their contact surfaces are covered with the insulation moving member (insulation plate 40) arranged at the cutoff position. The power supply circuit cutoff device (1, 1A) according to any one of [1] to [3].
[5] The operating member has a lever (80, 80A) rotatably mounted on the housing (10, 10A).
The power supply circuit cutoff device according to any one of the above [1] to [4], wherein the insulating moving member (insulating plate 40) is moved by the rotational power of the lever (80, 80A). (1,1A).
[6] A lever detachment prevention mechanism is provided between the lever (80A) and the housing (10A) so that the lever (80A) can be detached from the housing (10A) only at the shutoff operation position. The power supply circuit cutoff device (1A) according to the above [5].
[7] The lever disengagement prevention mechanism is
A guide protrusion (87) provided on either one of the lever (80A) and the housing (10A), and
The lever (80A) is provided on either one of the lever (80A) and the housing (10A), and by engaging with the guide protrusion (87), the lever (80A) can be disconnected from the housing (10A) only at the shutoff operation position. A guide groove (20) that allows detachment and
The power supply circuit cutoff device (1A) according to the above [6].

1 ... Power supply circuit cutoff device 10 ... Housing 10a ... Bottom surface 30 ... Terminal 40 ... Insulation plate (insulation moving member)
50 ... Conduction plate (conduction member)
80 ... Lever (operation member)
MSw ... Main switch section (switch section)
S ... Containment space SSw ... Sub switch section

Claims (6)

With the housing
The switch unit provided in the housing and
An operating member that turns the switch on and off, and
Equipped with
The switch part is
A pair of terminals arranged along the bottom of the housing,
A conductive member that is elastically urged and brought into contact with the pair of terminals in the direction in which the contact portions come into contact with each other to conduct the pair of terminals.
An insulating moving member made of an insulating material provided so as to be movable along the arrangement direction of the pair of terminals, and an insulating moving member.
Have,
The insulating moving member has a cutoff position that is interposed between the contact portion between the terminal and the conduction member to turn off the switch portion by the operation of the operation member, and the switch portion is separated from the contact portion. Moved to and from the energized position to turn on
In the energized state in which the insulating moving member is arranged at the energized position, the switch portion is turned on together with the switch portion, and the switch portion is maintained in the on state while the insulating moving member is displaced to the cutoff position. It is provided with a sub-switch unit that shuts off the energization of the circuit of the switch unit by turning it off in the state.
A power supply circuit cutoff device characterized by that. The power supply circuit cutoff device according to claim 1, wherein the switch portion is housed in a storage space partitioned by the housing and covered with a periphery. The power supply circuit cutoff device according to claim 1 or 2, wherein the terminal and the conductive member are covered with a contact surface with each other by the insulating moving member arranged at the cutoff position . With the housing
The switch unit provided in the housing and
An operating member that turns the switch on and off, and
Equipped with
The switch part is
A pair of terminals arranged along the bottom of the housing,
A conductive member that is elastically urged and brought into contact with the pair of terminals in the direction in which the contact portions come into contact with each other to conduct the pair of terminals.
An insulating moving member made of an insulating material provided so as to be movable along the arrangement direction of the pair of terminals, and an insulating moving member.
Have,
The insulating moving member has a cutoff position that is interposed between the contact portion between the terminal and the conduction member to turn off the switch portion by the operation of the operation member, and the switch portion is separated from the contact portion. Moved to and from the energized position to turn on
The operating member has a lever that is rotatably mounted on the housing.
A power supply circuit cutoff device, characterized in that the insulating moving member is moved by the rotational power of the lever . The power supply circuit breaking device according to claim 4 , wherein a lever disengagement prevention mechanism is provided between the lever and the housing so that the lever can be detached from the housing only at a breaking operation position. .. The lever disengagement prevention mechanism is
A guide protrusion provided on either the lever or the housing,
A guide groove provided on either one of the lever and the housing, which can be disengaged from the housing only at the shutoff operation position by engaging with the guide protrusion.
5. The power supply circuit cutoff device according to claim 5.

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