JP2012104338A - Power supply circuit breaker device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To ensure that terminals which are designed to move in a diagonal direction to make and break contact with each other surely contact with each other with a prescribed force of contact, even when their relative positions are displaced from normal positions.SOLUTION: The breaker device includes a first connector housing 10; a second connector housing 20 which engages with and breaks away from the first connector housing 10; a lever 30, rotatably fitted to the second connector housing 20, which causes by rotation an engagement force and a disengagement force to act between the connector housings 10 and 20; signal terminals 16 and 40, one provided on the first connector housing 10 and the other on the lever 30, which make and break contact by rotation of the lever 30. The signal terminal on one side, 16, has its tips both folded back, has an opening 16c formed between two folded spots which is wide at an entrance and narrow at the back, and has a pair of leaf spring contactors 16a, with both sides of the opening 16c left open. The signal terminal on the other side, 40, has a tab-like contactor 40a which is inserted into the opening 16c.

Description

  The present invention relates to a power supply circuit interrupting device that connects and disconnects a power supply circuit by fitting and disconnecting between connector housings with levers.

  For example, in an electric vehicle and a hybrid vehicle, a power circuit breaker (service plug) that can cut off energization between a power supply unit and a load is mounted in order to ensure work safety in maintenance of an electric system. As this type of conventional power circuit breaker, there is one disclosed in Patent Document 1.

  As shown in FIGS. 11 and 12, the power supply circuit breaker 100 rotates to the first connector housing 101, the second connector housing 110 that fits and detaches from the first connector housing 101, and the second connector housing 110. The lever 120 is provided so as to be able to be applied and a fitting force and a detaching force are applied between the second connector housing 110 and the first connector housing 101 by rotation.

  A pair of cam pins 102 project from both side surfaces of the first connector housing 101. The first connector housing 101 is provided with one main terminal (not shown) and one signal terminal 103. One main terminal (not shown) is disposed in the connector fitting chamber. One signal terminal 103 is disposed in the external hood section 104.

  A pair of rotating shafts 111 project from both side surfaces of the second connector housing 110. The second connector housing 110 is provided with the other main terminal (not shown).

  A pair of rotation receiving grooves 121 are formed on both side surfaces of the lever 120. A pair of rotation shafts 111 of the second connector housing 110 are pivotally supported in the pair of rotation receiving grooves 121. Thereby, the lever 120 is rotatably supported by the second connector housing 110. A pair of cam grooves 122 are provided on both side surfaces of the lever 120. The cam pins 102 of the first connector housing 101 are inserted into the pair of cam grooves 122. On the side surface of the lever 120, the connector 104 in which the other signal terminal 123 is accommodated is disposed. The other signal terminal 123 is disposed in the hood portion 124.

  A main circuit switch (not shown) is constituted by both main terminals (not shown). Both signal terminals 103 and 123 constitute a signal circuit switch SW2.

  In the above configuration, the power supply conduction operation of the power circuit breaker 1 will be described. The second connector housing 110 with the lever 120 in the first operating position is inserted into a connector fitting chamber (not shown) of the first connector housing 101, and the cam pin 102 is inserted into the inlet of the cam groove 122 of the lever 120. The connector housings 101 and 110 are in a connector temporary fitting state.

  The lever 120 is rotated from the first operation position to the second operation position side. Then, the cam pin 102 moves in the cam groove 122, and a fitting force acts between the second connector housing 110 and the first connector housing 101, so that the second connector housing 110 gradually enters the connector fitting chamber of the first connector housing 101. Inserted into. When the lever 120 is rotated to the connector fitting operation position, the first connector housing 101 and the second connector housing 110 are completely fitted. The main terminals (not shown) are gradually brought into contact in the process up to the connector fitting operation position, and are brought into contact at the connector fitting operation position. Accordingly, the main circuit switch (not shown) is turned on at the connector fitting operation position.

  When the lever 120 is further rotated from the connector fitting operation position, the signal terminals 103 and 123 are gradually brought into contact with each other, and the lever 120 is brought into a contact state at the second operation position. Accordingly, the signal circuit switch SW2 is in the on state at the operation completion position of the lever 120.

  Further, the power shut-off operation of the power circuit shut-off device 1 can be performed by operating the lever 120 in the reverse direction.

  The power circuit breaker 1 does not turn on the power circuit (not shown) until both the main circuit switch (not shown) and the signal circuit switch SW2 are turned on. That is, the power supply circuit is in a conductive state only when the lever 120 is in the second operation position, and the power supply circuit is in a nonconductive state at other operation positions.

  Thereby, since the operator does not have the lever 120 in the second operation position, a situation due to a misunderstanding that the power supply circuit is in a non-conductive state is prevented.

  By the way, the signal terminals 103 and 123 of the conventional example are configured as follows. As shown in detail in FIG. 13A, the pair of signal terminals 103 on the first connector housing 101 side is a pair of plate-like tab terminals arranged with the insulating wall 105 interposed therebetween. The pair of signal terminals 123 on the lever 120 side are a pair of plate-like clip terminals arranged in the hood portion 124. The pair of signal terminals 123 are supported by the hood portion 124 at the upper end side, and can be elastically shifted to the inner surface side of the hood portion 124 at the lower end side.

  As shown in FIG. 13B, the signal terminal 123 on the lever 120 side is inserted so as to sandwich the pair of signal terminals 103 on the first connector housing 101 side from the outside. 13C, the pair of signal terminals 123 on the lever 120 side and the pair of signal terminals 103 on the first connector housing 101 side are brought into close contact with each other by the elastic deformation force of each signal terminal 123.

  Thus, by making both the signal terminals 103 and 123 both plate-shaped, it is possible to reliably contact even by contact in an oblique direction.

JP 2008-176969 A

  However, when both signal terminals 103 and 123 of the signal circuit switch SW2 are plate-like as in the conventional example, the following problem occurs. That is, if the signal terminal 103 on the first connector housing 101 side is slightly shifted due to floating from the insulating wall 105 or the like, the distal end surfaces of both the signal terminals 103 and 123 may abut against each other and plastically deform, resulting in poor contact. There is. Also, if both signal terminals 103 and 123 are in contact and the lever 120 is twisted to the left and right, the contact force between the signal terminals 103 and 123 is weakened, and in the worst case, there is a risk of non-contact. is there.

  As described above, in the conventional example, if the positions of both signal terminals 103 and 123 are slightly shifted from the normal positions, contact failure occurs or contact becomes unstable, and a desired contact state cannot be obtained. There is a fear.

  Therefore, the present invention has been made to solve the above-described problems, and in the case where both terminals are in contact / non-contact by moving in an oblique direction, the positions of both terminals are slightly changed from the normal positions. However, it is an object of the present invention to provide a power supply circuit breaker that can be reliably contacted and can secure a predetermined contact force.

  The present invention includes a first connector housing, a second connector housing that fits and detaches from the first connector housing, a rotatable connection to the second connector housing, and the rotation of the second connector housing by the rotation. A power source comprising: a lever that applies a fitting force and a detaching force between the first connector housings; and a pair of terminals that are provided on the first connector housing and the lever, and are brought into contact / non-contact by a rotation operation of the lever A circuit breaker, wherein one of the terminals is folded back at the tip side, an opening having a wide entrance side and a narrow width at the back side is formed between the folded portions, and both sides of the opening are open. It has a pair of leaf spring contacts, and the other terminal has a tab-like contact inserted into the opening.

  The tab-shaped contact is preferably one in which the punched surface has been surface processed.

  According to the present invention, since one side of the terminal is open on both sides of the opening, even if there is a contact or non-contact between the two terminals due to the movement in the oblique direction, the connection between the two terminals is ensured. Can touch. Further, if the transition position of the other terminal is within the range of the opening on the inlet side of the one terminal, the two terminals can be reliably contacted. In addition, even if the contact position of both terminals is slightly shifted from the normal position, the contact pressure due to one of the leaf spring contacts decreases, but conversely, the contact pressure due to the other leaf spring contact increases. A predetermined contact force can be secured. As described above, there is a contact between the pair of terminals that is in contact or non-contact by moving in an oblique direction, and even if the position of both terminals slightly changes from the normal position, the contact can be made reliably and a predetermined contact force can be secured. .

1 is a perspective view of a power circuit breaker according to an embodiment of the present invention in which a first connector housing and a second connector housing are in a detached state. 1 is a perspective view of a power circuit breaker according to an embodiment of the present invention, in which a lever is located at a first operation position and a first connector housing and a second connector housing are in a temporarily fitted state. FIG. 4 is a side view of the power supply circuit breaker according to the embodiment of the present invention, in which the lever is located at the first operation position and the first connector housing and the second connector housing are in a temporarily fitted state. 1 is a side view of a power circuit breaker according to an embodiment of the present invention, in which a lever is located at a connector fitting operation position and a first connector housing and a second connector housing are in a completely fitted state. FIG. 2 shows an embodiment of the present invention, (a) a cross-sectional view of a power circuit breaker in which a lever is located at a connector fitting operation position and a first connector housing and a second connector housing are in a completely fitted state; ) Is a cross-sectional view of the main part showing a state in which the signal terminal on the lever side is obliquely inserted into the signal terminal on the first connector housing side, (c) is a direction different from (b), It is principal part sectional drawing which shows the state inserted in the signal terminal by the side of a connector housing. FIG. 4 is a perspective view of the power circuit breaker according to the embodiment of the present invention, in which the lever is located at the second operation position and the first connector housing and the second connector housing are in a completely fitted state. FIG. 4 is a side view of the power circuit breaker according to the embodiment of the present invention, in which the lever is located at the second operation position and the first connector housing and the second connector housing are in a completely fitted state. FIG. 5 is a cross-sectional view of the power supply circuit breaker according to the embodiment of the present invention, in which the lever is located at the second operation position and the first connector housing and the second connector housing are in a completely fitted state. FIG. 3 is a perspective view of a pair of signal terminals on the first connector housing side according to the embodiment of the present invention. FIG. 2 is a perspective view of a pair of signal terminals on the lever side according to the embodiment of the present invention. It is a perspective view of the power circuit breaker of a prior art example. It is a partially broken perspective view of the power circuit breaker of a prior art example. Both signal terminals of a conventional example are shown, (a) is a sectional view showing a state before contact of both signal terminals, (b) is a sectional view showing a contact start state of both signal terminals, and (c) is both. It is sectional drawing which shows the contact completion state of this signal terminal.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  1 to 11 show an embodiment of the present invention. As shown in FIGS. 1 to 8, the power circuit breaker 1 is rotatable to the first connector housing 10, the second connector housing 20 that fits and detaches from the first connector housing 2, and the second connector housing 20. And a lever 30 that applies a fitting force or a detaching force between the second connector housing 20 and the first connector housing 10 by rotation.

  A pair of cam pins 11 project from both side surfaces of the first connector housing 10. The first connector housing 10 has a connector fitting chamber 10a having an open upper surface. Two internal terminal hood portions 12 are provided in the connector fitting chamber 11. One main terminal 13 is disposed in each internal terminal hood portion 12. Each main terminal 13 is a female terminal.

  The first connector housing 10 is provided with an external terminal hood portion 15 outside the connector fitting chamber 10a. The terminal hood portion 15 is open at the top. Two signal terminals 16, which are terminals on one side, are arranged in the external terminal hood portion 15. The detailed configuration of the two signal terminals 16 will be described below.

  A pair of first locked portions 17 project from the side wall of the external terminal hood portion 15. The first locked portion 17 is easily bent and deformed by the slit 15 a on the side wall of the external terminal hood portion 15.

  The second connector housing 20 includes a housing main body 21 in which the fuse 2 is accommodated, and a cover 22 attached to the upper surface of the housing main body 21. The housing main body 21 is formed to have a size and shape that can be fitted and removed from the connector fitting chamber 10 a of the first connector housing 10. Two main terminals 23 on the other side are provided at the lower portion of the housing body 21. Each main terminal 23 is a male terminal. Each main terminal 23 protrudes downward from the housing body 21. The two main terminals 23 are connected via the fuse 2. The main circuit switch SW1 is configured by the two main terminals 13 on the first connector housing 10 side and the two main terminals 23 on the second connector housing 20 side.

  A pair of rotation support shafts 24 project from both side surfaces of the housing body 21. A pair of locking projections 25 are provided on both side surfaces of the housing body 21. Each locking projection 25 is an arc-shaped projection having a low height.

  An arm-shaped second lock portion 26 protrudes from the housing main body 21. An elastic deformation space 28 for elastically deforming the second lock portion 26 is formed on the rear side of the second lock portion 26.

  The lever 30 includes a pair of arm plate portions 31, and a connection portion 32 and an operation portion 33 that connect the pair of arm plate portions 31 on the rotation tip side. A pair of rotation receiving portions 34 is provided on the pair of arm plate portions 31. The pair of rotation support shafts 24 of the second connector housing 20 are pivotally supported by the pair of rotation receiving portions 34. Thereby, the lever 30 is rotatably supported by the second connector housing 20. A pair of cam grooves 35 are formed in the pair of arm plate portions 31. The cam pins 11 of the first connector housing 10 are inserted into the pair of cam grooves 35.

  4 and 7, the cam groove 35 communicates with the entry straight portion 35a into which the cam pin 11 can enter and the entry straight portion 35a, and the distance from the center of the rotation receiving portion 34 gradually changes. A curved portion 35b that communicates with the curved portion 35b, and a circular arc portion 35c that has a constant distance from the center of the rotation receiving portion 34.

  The lever 30 rotates between the first operation position and the second operation position that has passed through the connector fitting operation position while the cam pin 11 moves in the cam groove 35. In the first operation position, the cam pin 11 is positioned on the entry straight portion 35a. At the connector fitting operation position, the cam pin 11 is positioned at the boundary position between the curved portion 35b and the arc portion 35c. In the second operation position, the cam pin 11 is located at the innermost position of the arc portion 35c.

  That is, in the rotation process of the first operation position of the lever 30 and the connector fitting operation position, the cam pin 11 moves along the curved portion 35a, and a fitting force or a detaching force acts between the first connector housing 10 and the second connector housing 20. Then, the first connector housing 10 and the second connector housing 20 move in the fitting direction or in the separating direction. When the lever 30 rotates between the connector fitting operation position and the second operation position, the cam pin 11 moves along the arc portion 35c, and no fitting force or detachment force acts between the first connector housing 10 and the second connector housing 20. The first connector housing 10 and the second connector housing 20 do not move in the fitting direction or in the separating direction.

  The pair of arm plate portions 31 are provided with position holding holes 36 at two locations. As for the lever 30, the latching protrusion 25 is latched by either one of the position holding holes 36 in the 1st operation position and the 2nd operation position. Thereby, the lever 30 is positioned by the position holding force at the first operation position and the second operation position.

  A pair of first lock portions 37 is provided on the rotation tip side of the pair of arm plate portions 31 and at a lower position. The connecting part 32 is provided with a plate-like lock release preventing part 38.

  A hood portion 39 is provided below the operation portion 33. The hood portion 39 opens downward. In the hood portion 39, two signal terminals 40 which are terminals on the other side are arranged. The detailed configuration of the two signal terminals 40 will be described below. The two signal terminals 16 on the first connector housing 10 side and the two signal terminals 40 on the lever 30 side constitute a signal circuit switch SW1.

  The operation portion 33 is provided with a second locked portion 41. The 2nd to-be-latched part 41 is an arm form extended to the connection part 32 side.

  Next, the configuration of both signal terminals 16 and 40 will be described. As shown in detail in FIG. 9, each signal terminal 16 on one side includes a pair of leaf spring contacts 16 a and a wire crimping portion 16 b integrally connected thereto. Each of the pair of leaf spring contacts 16a is folded back inwardly at the leading end side, and an opening 16c having a wide entrance side and a narrow back side is formed between the folded portions. Both sides of the opening 16c of the pair of leaf spring contacts 16a are open.

  As shown in FIG. 10, each signal terminal 40 on the other side includes a tab-like contact 40a and a support portion 40b integrally connected thereto. The support portions 40b of the pair of signal terminals 40 are connected to each other by a connecting portion 40c. The tab-shaped contact 40a has a tapered surface 40d at the tip and at the corner that contacts the signal terminal 16 first. The tab-like contact 40a has a punched surface.

  Next, a power circuit system related to the power circuit breaker 1 will be briefly described. A main circuit switch SW1 and a relay (not shown) that is turned on / off by a signal circuit switch SW2 are connected in series between a power supply unit (not shown) and a load unit (not shown). Therefore, both the main circuit switch SW1 and the signal circuit switch SW2 are turned on, and the power supply circuit is turned on. In other switch states, the power supply circuit is in an off state.

  In the above configuration, the conduction operation of the power circuit by the power circuit breaker 1 will be described. As shown in FIG. 1, the second connector housing 20 with the lever 30 as the first operation position is aligned with the connector fitting chamber 10 a of the first connector housing 10. 2 and 3, the second connector housing 20 is inserted into the connector fitting chamber 10 a of the first connector housing 10, and the cam pin 11 is inserted into the entry straight portion 35 a of the cam groove 35 of the lever 30. To do. The connector housings 10 and 20 are in a connector temporary fitting state.

  Next, the lever 30 is rotated from the first operation position to the second operation position. Then, the cam pin 11 moves in the cam groove 35 and a fitting force acts between the second connector housing 20 and the first connector housing 10, so that the second connector housing 20 enters the connector fitting chamber 10 a of the first connector housing 10. It is inserted gradually.

  When the lever 30 is rotated to the connector fitting operation position, as shown in FIGS. 4 and 5A, the second locked portion 41 is moved over the second lock portion 26, and the first connector housing 10 and the first connector housing 10 The two connector housings 20 are completely engaged. In the process from the first operation position to the connector fitting operation position, contact between both the main terminals 13 and 23 is started, and the contact is completed at the connector fitting operation position. At the connector fitting operation position of the lever 30, the main circuit switch SW1 is turned on.

  When the lever 30 is rotated from the connector fitting operation position to the second operation position, as shown in FIGS. 6 to 8, the lock release prevention portion 38 enters the elastic deformation space 28 and the first lock portion 37 is the first lock portion 37. Locked to the locked portion 17. In the rotation process from the connector fitting operation position of the lever 30 to the second operation position, the contact between both the signal terminals 16 and 40 is started, and the contact is completed at the second operation position. In the second operation position of the lever 30, the signal circuit switch SW2 is turned on. That is, the power supply circuit is non-conductive at the connector fitting operation position of the lever 30 and is not conductive until the lever 30 is at the second operation position.

  Next, the power cut-off operation by the power circuit breaker 1 will be described. As shown in FIGS. 6 to 8, when the lever 30 is in the second operation position, the lever 30 is rotated with a rotational force stronger than the locking force between the first lock portion 37 and the first locked portion 17. It rotates to the first operating position side. Then, the lock between the first lock portion 37 and the first locked portion 17 is released, and the rotation of the lever 30 is allowed. Thereby, as shown in FIG.4 and FIG.5 (a), the lever 30 is rotated to a connector complete fitting operation position. When the lever 30 is rotated to the connector complete fitting operation position, the second locked portion 41 of the lever 30 is locked to the second lock portion 26. Thus, the rotation of the lever 30 is temporarily prevented. In the process of rotation from the second operation position of the lever 30 to the connector fitting operation position, the signal terminals 16 and 40 are not gradually in contact with each other, and the lever 30 is completely non-contacted at the connector fitting operation position. Therefore, the signal circuit switch SW2 is turned off at the connector complete fitting operation position of the lever 30. The power supply circuit becomes non-conductive at the connector fitting operation position of the lever 30.

  Further, the lock release preventing portion 38 of the lever 30 comes out of the elastic deformation space 28 of the first connector housing 10 by the rotation of the lever 30 from the second operation position to the connector fitting operation position.

  Next, the second lock portion 26 is elastically deformed using the elastic deformation space 28 and the lock with the second locked portion 41 is released. Thus, the rotation of the lever 30 toward the first operation position is allowed, and the lever 30 is rotated to the first operation position. When the lever 30 is rotated from the connector fitting position to the first operation position, the cam groove 35 and the cam pin 11 cause a detachment force to act between the second connector housing 20 and the first connector housing 10 so that the second connector housing 20 The first connector housing 10 is gradually pulled out from the connector fitting chamber 10a.

  As shown in FIGS. 2 and 3, the first connector housing 10 and the second connector housing 20 are in a temporarily fitted state at the first operation position of the lever 30. The main terminals 13 and 23 are gradually not in contact with each other in the process from the connector fitting operation position to the first operation position, and are completely in a non-contact state at the first operation position. Accordingly, at the first operation position of the lever 30, the main circuit switch SW1 is turned off.

  As described above, the first connector housing 10, the second connector housing 20 that fits and detaches from the first connector housing 10, the lever 30 that is rotatably provided on the second connector housing 20, and the first connector Provided in each of the housing 10 and the lever 30 and provided with both signal terminals 16 and 40 which are brought into contact / non-contact with the rotation of the lever 30, the signal terminal 16 on one side is folded back at both ends, and both folded back An opening 16c having a wide entrance side and a narrow back side is formed between the locations, and a pair of leaf spring contacts 16a are opened on both sides of the opening 16c. It has the structure which has the tab-like contactor 40a inserted in the opening 16c.

  Since the signal terminal 16 on one side is open on both sides of the opening 16a, as shown in FIG. 5B, the signal terminals 16 and 40 are in contact or non-contact with each other by moving in an oblique direction. Even if it exists, between both the signal terminals 16 and 40 can contact reliably. Further, as shown in FIG. 5C, if the transition position of the signal terminal 40 on the other side is within the range of the opening 16c on the inlet side of the signal terminal 16 on the one side, the distance between the two signal terminals 16 and 40 is not increased. Can contact reliably. Further, even if the contact position of both signal terminals 16 and 40 is slightly shifted from the normal position, the contact pressure by one of the leaf spring contacts 16a is reduced, but conversely, the contact by the other leaf spring contact 16a. Since the pressure increases, a predetermined contact force can be secured.

  The tab-like contact 40a has a punched surface. Therefore, the punched surface of the tab-like contact 40a is smooth, and the terminal insertability is improved.

DESCRIPTION OF SYMBOLS 1 Power supply circuit interruption | blocking apparatus 10 1st connector housing 16 One side signal terminal (one side terminal)
16a leaf spring contact 16c opening 20 second connector housing 30 lever 40 signal terminal on the other side (terminal on the other side)
40a Tab contact

Claims (2)

A first connector housing;
A second connector housing that fits and detaches from the first connector housing;
A lever that is rotatably provided in the second connector housing and that exerts a fitting force and a detaching force between the second connector housing and the first connector housing by rotation;
A power circuit breaker provided with a pair of terminals provided on the first connector housing and the lever, respectively, and brought into contact / non-contact by rotation of the lever,
The terminal on one side is folded back at the tip side, a pair of leaf spring contacts are formed between the folded portions, an opening having a wide entrance side and a narrow width on the back side, and both sides of the opening being open. Have
The terminal on the other side has a tab-like contactor inserted into the opening. The power circuit breaker according to claim 1,
A power circuit breaker according to claim 1, wherein the tab-like contact has a punched surface.

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