JP6953192B2 - Bus bar module resin case, bus bar module, and power supply - Google Patents

Description

The present invention relates to a resin case of a bus bar module constituting a power supply device used in a hybrid vehicle, an electric vehicle, or the like, a bus bar module including the resin case, and a power supply device including the bus bar module.

For example, various vehicles such as an electric vehicle that travels by using an electric motor and a hybrid vehicle that travels by using an engine and an electric motor in combination are equipped with a power supply device as a power source of the electric motor. In this type of power supply device, a plurality of batteries having a positive electrode (hereinafter referred to as "positive electrode") at one end and a negative electrode (hereinafter referred to as "negative electrode") at the other end are alternately adjacent to each other. It has a battery assembly that is linearly arranged to fit. The battery assembly is provided with a bus module as shown in Patent Document 1 so as to be superposed on the surface on which the electrodes are provided.

The bus bar module includes a plurality of bus bars, a plurality of voltage detection terminals, a plurality of voltage detection lines, and a resin case. The plurality of buses electrically connect the positive electrode and the negative electrode of the adjacent batteries of the battery assembly so that the plurality of batteries are connected in series. The voltage detection line is electrically connected to the electrode of the battery via the voltage detection terminal superimposed on the bus bar.

The resin case is provided with a bus bar accommodating portion for accommodating the bus bar and the voltage detection terminal, and an electric wire accommodating portion for accommodating the voltage detection line. Further, the resin case is provided with a wire accommodating portion cover that closes the upper surface opening of the electric wire accommodating portion so as to be rotatable by a hinge after the wiring of the voltage detection line is completed. Then, after the bus bar and the voltage detection terminal housed in the bus bar accommodating portion are fastened to the electrodes of the battery with bolts, nuts, or the like, the cover is put on. That is, the upper surface opening of the bus bar accommodating portion is covered with a bass bar accommodating portion cover provided separately from the resin case.

As described above, in many cases, the electric wire accommodating portion cover is conventionally connected to the resin case with a hinge, but the bass bar accommodating portion cover is often prepared separately from the resin case. In the case of a separate body, the cost tends to increase as the number of parts increases.

On the other hand, Patent Document 2 shows an example in which a cover covering a bus bar accommodating portion is integrally connected to a main body portion of a resin case with a hinge. Therefore, like the electric wire accommodating portion cover, it is conceivable that the bass bar accommodating portion cover is integrally connected to the main body portion of the resin case via a hinge.

Japanese Unexamined Patent Publication No. 2014-233159 Japanese Unexamined Patent Publication No. 2015-149185

However, even if the number of parts can be reduced by simply connecting the bus bar housing cover to the main body of the resin case with a hinge, as with the wire housing cover, there remains a problem in facilitating the assembly process. ..

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a resin case for a bus module that can exhibit good assembling property while reducing costs by reducing the number of parts. be. At the same time, an object of the present invention is to provide a bus bar module including the resin case and a power supply device including the bus bar module.

In order to achieve the above-mentioned object, the resin case, the bus bar module, and the power supply device of the bus bar module according to the present invention are characterized by the following (1) to (4).
(1) A bus bar accommodating portion having a top opening and accommodating a bus bar connecting between electrodes of adjacent batteries of a battery assembly inside.
An electric wire accommodating portion having an upper surface opening, adjacent to and coupled to the bus bar accommodating portion, and internally accommodating electric wires electrically connected to the bus bar.
A first cover that is rotatably coupled to a portion of the electric wire accommodating portion opposite to the bus bar accommodating portion by a first hinge and closes the upper surface opening of the electric wire accommodating portion by a rotation operation in the closing direction.
The first cover is rotatably coupled to the tip edge opposite to the first hinge by a second hinge, and is rotated in the closing direction while the first cover is in the closed position. A second cover that closes the upper opening of the bus bar housing,
With the first cover in the closed position, the second cover is temporarily locked in an open position in which it rises upward from the second hinge in an independent posture, and in that state, the second cover rotates in the closing direction. Temporary locking means that releases the temporary locking by being operated, and
A locking means for locking the first cover and the second cover in a closed position,
As an integrated resin molded product,
Resin case for Basba module.
(2) A bus bar accommodating portion having a top opening and accommodating a bus bar connecting between electrodes of adjacent batteries of a battery assembly inside.
An electric wire accommodating portion having an upper surface opening, adjacent to and coupled to the bus bar accommodating portion, and internally accommodating electric wires electrically connected to the bus bar.
A first cover that is rotatably coupled to a portion of the electric wire accommodating portion opposite to the bus bar accommodating portion by a first hinge and closes the upper surface opening of the electric wire accommodating portion by a rotation operation in the closing direction.
The first cover is rotatably coupled to the tip edge opposite to the first hinge by a second hinge, and is rotated in the closing direction while the first cover is in the closed position. A second cover that closes the upper opening of the bus bar housing,
With the first cover in the closed position, the second cover is temporarily locked in the open position in an independent posture, and in that state, the second cover is rotated in the closing direction to release the temporary lock. Temporary locking means and
A locking means for locking the first cover and the second cover in a closed position,
As an integrated resin molded product,
The temporary locking means is
A flexible temporary locking rib projecting from the second cover,
Wherein provided in the bus bar accommodating portion, sealed and tentatively retaining freestanding position said second cover to said open position by said first cover ride the tip of the temporary engaging rib in the closed position, in that state When the second cover is rotated in the closing direction, the tip of the temporary locking rib is slid to release the temporary locking state, and the temporary locking rib is allowed to rotate in the closing direction. Locking slope and
including,
The resin case of the bus module that is characterized by this.
(3) A plurality of buses that electrically connect between the positive electrode and the negative electrode of the adjacent batteries so that the batteries of the battery assembly consisting of a plurality of batteries arranged linearly are connected in series.
A plurality of voltage detection lines electrically connected to the positive electrode or the negative electrode via the respective bus bars, and
A resin case accommodating at least one bus bar and the plurality of voltage detection lines, and
With
As the resin case, the resin case having the above configuration (1) or (2) is used.
The bus bar is housed in the bus bar accommodating portion of the resin case.
The plurality of voltage detection lines are housed in the wire accommodating portion of the resin case.
Bus bar module.
(4) A battery assembly composed of a plurality of linearly arranged batteries, and a bus module that is mounted on the battery assembly and electrically connects the batteries to each other.
In a power supply with
As the bus module, the bus module according to (3) above is provided.
Power supply.

According to the resin case of the bus bar module having the configuration of (1) above, after closing the upper surface opening of the electric wire accommodating portion with the first cover, the operation of closing the second cover that closes the bus bar accommodating portion can be performed separately. .. As a specific process sequence, first, the bus bar is assembled to the bus bar accommodating portion of the resin case. At the same time, the voltage detection line is arranged to accommodate the voltage detection line in the electric wire accommodating portion of the resin case. Then, in that state, only the first cover is closed in order to prevent the voltage detection line from popping out from the electric wire accommodating portion. At this time, in order to fix the bus bar to the battery in the next step, the second cover is temporarily locked in an open state in an independent posture by a temporary locking means. Next, the bus bar is fixed to the electrode of the battery through the opening on the upper surface of the bus bar accommodating portion. After finishing this step, the second cover is rotated in the closing direction. Then, the temporary locking state by the temporary locking means is automatically released, and the second cover can be rotated in the closing direction. Then, by rotating the second cover in the closing direction, the upper surface opening of the bus bar accommodating portion can be covered with the second cover. As a result, it is possible to insulate and protect the fixed portion between the bus bar and the electrode to prevent electric shock and the like.
As described above, when the bus bar module is assembled to the battery (when the bus bar is fixed to the battery), the first cover covering the electric wire accommodating portion can be kept closed. Therefore, the bus module can be assembled to the battery with the width of the resin case reduced. Therefore, the resin case does not interfere with the battery, and the workability of assembling the bus module is not impaired. Further, when the battery of the bus bar module is assembled, the first cover covering the electric wire accommodating portion can be kept closed, while the second cover covering the bus bar accommodating portion can be kept open in a self-supporting posture. Therefore, the assembly work of fastening the bus bar to the electrode of the battery with bolts, nuts, or the like can be easily proceeded.
Further, a second cover that closes the bus bar accommodating portion is integrally provided at the tip of the first cover that closes the electric wire accommodating portion. Therefore, the cost can be reduced by reducing the number of parts as compared with the case where the cover of the bus bar accommodating portion is provided separately from the resin case. Further, since the second cover is only connected to the tip of the first cover via a hinge, the structure is simple, the molding cost can be reduced, and the cost can be reduced. Further, since the first cover and the second cover are configured as an integral cover, the voltage detection line electrically connected to the bus bar is routed without being disturbed by the cover with the cover fully opened. be able to.
According to the resin case of the bus module having the configuration of (2) above, the temporary locking rib and the temporary locking slope can be engaged with each other to temporarily hold the second cover in the open position in an independent posture. .. Further, by rotating the second cover in the closing direction in that state, the tip of the temporary locking rib can be slid along the temporary locking slope, and the temporary locking can be released. Therefore, the temporary locking and the temporary locking of the second cover can be performed with a simple configuration and a simple operation, which can contribute to cost reduction.
According to the bus module having the configuration of (3) above, the above-mentioned effects can be obtained by using the resin case having the configuration of (1) or (2) above.
According to the power supply device having the configuration (4), the above-mentioned effects can be obtained by using the bus module having the configuration (3).

According to the present invention, good assembling property can be exhibited while reducing the cost by reducing the number of parts.

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. ..

FIG. 1 is a partial external perspective view of the power supply device according to the embodiment of the present invention. FIG. 2 is a partially exploded perspective view of the bus module according to the embodiment of the present invention. FIG. 3 is a cross-sectional view of the resin case according to the embodiment of the present invention when the cover is fully opened. 4A and 4B are cross-sectional views of the resin case according to the embodiment of the present invention when the first cover is closed, where FIG. 4A is an overall view and FIG. 4B is an enlarged view of part A1 of FIG. 4A. 5A and 5B are cross-sectional views of the first cover and the second cover of the resin case according to the embodiment of the present invention when the first cover and the second cover are closed. FIG. 5A is an overall view, and FIG. .. FIG. 6 is a partially exploded perspective view of the power supply device of the comparative example. FIG. 7 is a partial external perspective view of the power supply device of the comparative example. FIG. 8 is a partial external perspective view of the bus module of the comparative example. FIG. 9 is a schematic cross-sectional view of another comparative example. FIG. 10 is a schematic cross-sectional view of still another comparative example. FIG. 11 is a schematic cross-sectional view of still another comparative example.

Specific embodiments of the present invention will be described below with reference to the respective figures.
Hereinafter, the resin case, the bus bar module, and the power supply device of the bus bar module according to the present embodiment will be described with reference to the drawings. FIG. 1 is a partial external perspective view of the power supply device according to the present embodiment, and FIG. 2 is a partially exploded perspective view of the bus bar module. 3 is a cross-sectional view of the resin case when the cover is fully opened, FIG. 4 is a cross-sectional view of the resin case when the first cover is closed, FIG. 3A is an overall view, and FIG. It is a figure. 5A and 5B are cross-sectional views of the first cover and the second cover of the resin case when the first cover and the second cover are closed. FIG. 5A is an overall view, and FIG. 6 is a partially disassembled perspective view of the power supply device of the comparative example, FIG. 7 is a partial external perspective view of the power supply device of the comparative example, and FIG. 8 is a partial external perspective view of the bus bar module of the comparative example. For convenience of explanation, arrows X, Y, and Z are used in each figure to indicate the arrangement direction of each member. These arrows X, Y, and Z are orthogonal to each other.

The power supply device 1 shown in FIG. 1 includes a battery assembly 2 and a bus module 10 mounted on the battery assembly 2 in an overlapping manner. The power supply device 1 is mounted on and used in an electric vehicle traveling by using an electric motor, a hybrid vehicle traveling by using an engine and an electric motor in combination, and the like, and supplies power to the electric motor.

The battery assembly 2 is composed of a plurality of batteries 3 that are linearly arranged in a line along one direction (arrow X direction) and fixed to each other. Since the configuration of the battery assembly 2 is the same as that of the comparative example of FIG. 6, it will be described with reference to FIG. Each battery 3 is provided with a pair of electrodes 4A and 4B at one end and the other end of the upper surface of the rectangular parallelepiped battery body. Of the pair of electrodes 4A and 4B, one electrode is the positive electrode 4A and the other electrode is the negative electrode 4B. The pair of electrodes 4A and 4B are each formed in a columnar shape by a conductive metal. Each battery 3 is arranged so that the surface (upper surface) including the pair of electrodes 4A and 4B faces upward and the adjacent batteries 3 are in contact with each other. Moreover, the positive electrode 4A of one battery 3 and the negative electrode 4B of the other adjacent batteries 3 are arranged so as to be alternately adjacent to each other. Therefore, the positive electrode 4A and the negative electrode 4B are alternately arranged along the arrow X direction on one end side and the other end side in the arrow Y direction, respectively.

The bus module 10 shown in FIGS. 1 and 2 connects the plurality of batteries 3 described above in series. The bus bar module 10 includes a bus bar 11, a voltage detection terminal 12, a voltage detection line (electric wire) 13, and a resin case 20. Here, the resin case 20 is formed with a size corresponding to the four batteries 3 as one unit N, and by sequentially connecting the resin cases 20 having a size of the unit N, the resin case 20 corresponds to all the batteries 3. It is configured in size.

The bus bar 11 is attached to the positive electrode 4A and the negative electrode 4B (see FIG. 6) of the batteries 3 adjacent to each other in the battery assembly 2, so that each of the batteries 3 is connected in series. The bus bar 11 is obtained by pressing a conductive metal plate or the like, and a pair of positive electrode 4A and negative electrode 4B of batteries 3 adjacent to each other are passed through a metal plate having a substantially rectangular plate shape. Has a hole 11a. These pair of holes 11a are arranged along the longitudinal direction (X direction) of the bus bar 11 at the same intervals as the positive electrode 4A and the negative electrode 4B of the batteries 3 adjacent to each other. Further, the bus bar 11 is attached to the battery 3 by screwing nuts (not shown) into the positive electrode 4A and the negative electrode 4B passed through the holes 11a, and is electrically connected to the positive electrode 4A and the negative electrode 4B. Will be done.

The voltage detection terminal 12 is arranged so as to be overlapped with the corresponding bus bar 11, and is connected to the positive electrode 4A and the negative electrode 4B of the batteries 30 adjacent to each other via the bus bar 11. The voltage detection terminal 12 is obtained by pressing a conductive metal plate or the like, and includes a bus bar connection portion 12a and an electric wire attachment portion 12b.

The bus bar connection portion 12a is a portion that is overlapped with the bus bar 11 and electrically connected to the bus bar 11, and one hole 12c is provided in the central portion thereof. The hole 12c is overlapped with one of the pair of holes 11a of the bus bar 11, and the positive electrode 4A or the negative electrode 4B of the battery 3 is passed through the hole 12c. The bus bar connection portion 12a is attached to the battery 3 by the nut in a state of being overlapped with the bus bar 11.

The electric wire mounting portion 12b extends in parallel from the bus bar connecting portion 12a, and the voltage detection line 13 is electrically connected to the tip portion. Therefore, the voltage detection line 13 is connected to the positive electrode 4A and the negative electrode 4B of each battery 3 via the bus bar 11. The voltage detection line 13 is connected to a voltage detection circuit included in an ECU (Electronic Control Unit) (not shown). Then, the ECU detects the remaining amount, charge / discharge state, etc. of each battery 3 based on the potential difference (voltage) between the pair of electrodes 4A and 4B in each battery 3 detected by the voltage detection circuit. The voltage detection wire 13 is a well-known covered electric wire, and the core wire exposed by peeling the insulating coating at the tip is crimped to the voltage detection terminal 12.

The resin case 20 accommodates and holds the above-mentioned bus bar 11, the voltage detection terminal 12, and the voltage detection line 13, and is made of an integrally molded synthetic resin. Here, two bus bars 11 and two voltage detection terminals 12 are housed in a resin case 20 having one unit N corresponding to the four batteries 3. The bus bar 11 is arranged so as to straddle the positive electrode 4A and the negative electrode 4B of two adjacent batteries 3 among the four batteries 3 arranged side by side. N1 in FIG. 2 indicates a unit (corresponding to two batteries 3) in which each one bus bar 11 is arranged.

As shown in the cross section in FIG. 3, the resin case 20 has a structure in which the case main body 21 and the cover 41 are integrally connected via a hinge (first hinge 45). The case main body 21 is provided with a bus bar accommodating portion 22, an electric wire accommodating portion 23, and a connecting portion 24 connecting the bus bar accommodating portion 22 and the electric wire accommodating portion 23. The bus bar 11 and the voltage detection terminal 12 are housed in the bus bar accommodating portion 22. The voltage detection line 13 is accommodated in the electric wire accommodating portion 23. The cover 41 is provided with a first cover 42, a second cover 43, and a hinge (second hinge 46) for connecting the first cover 42 and the second cover 43. Further, a temporary locking means and a locking means, which will be described later, are provided between the case body 21 and the cover 41.

The bus bar accommodating portion 22 of the resin case 20 has a bottom wall 31 on which the bus bar 11 and the voltage detection terminal 12 are placed, and a pair of side walls 32 and 33 rising from both ends in the Y direction of the bottom wall 31. The pair of side walls 32 and 33 are provided along the arrangement direction of the batteries 3 (the X direction in FIG. 2), and an upper surface opening 22a is provided above the pair of side walls 32 and 33.

The electric wire accommodating portion 23 of the resin case 20 is a gutter-shaped portion accommodating a bundle of voltage detection lines 13, and includes a bottom wall 34 and a pair of side walls 35 and 36 rising from both ends in the Y direction of the bottom wall 34. Have. The pair of side walls 35 and 36 are provided along the arrangement direction of the batteries 3 (the X direction in FIG. 2), and an upper surface opening 23a is provided above the pair of side walls 35 and 36.

The connecting portion 24 of the resin case 20 connects the adjacent side walls 33 and 35 of the bus bar accommodating portion 22 and the electric wire accommodating portion 23 arranged adjacent to each other. The connecting portion 24 is provided with a groove portion (not shown) for accommodating a connecting portion between the electric wire mounting portion 12b of the voltage detection terminal 12 and the voltage detection line 13. Then, the connecting portion can be inserted into the groove from above.

The cover 41 of the resin case 20 is formed as a bendable rectangular plate having a size capable of covering from the electric wire accommodating portion 23 to the bus bar accommodating portion 22. The cover 41 has a first cover 42 and a second cover 43 connected by a hinge (second hinge 46). The first cover 42 is rotatably connected to the upper end of the side wall 36 on the side opposite to the bus bar accommodating portion 22 of the electric wire accommodating portion 23 by the first hinge 45 as shown by an arrow A in FIG. Then, the first cover 42 closes the upper surface opening 23a of the electric wire accommodating portion 23 by the rotation operation in the closing direction. The second cover 43 is rotatably connected to the tip edge of the first cover 42 opposite to the first hinge 45 by a second hinge 46 as shown by an arrow B in FIG. Then, by rotating the first cover 42 in the closing direction while the first cover 42 is in the closed position, the upper surface opening 22a of the bus bar accommodating portion 22 is closed.

A flexible temporary locking rib 51 and a temporary locking rib 51 are provided at the vicinity of the second hinge 46 of the second cover 43 and the upper end of the side wall 33 on the connecting portion 24 side of the corresponding bus bar accommodating portion 22 as temporary locking means. A locking slope 52 and a locking slope 52 are provided respectively. As shown in FIG. 4, the temporary locking rib 51 and the temporary locking slope 52 have a second cover for opening the upper surface opening 22a of the bus bar accommodating portion 22 when the first cover 42 is in the closed position. The 43 is temporarily locked in the open position in an independent posture. Further, as shown in FIG. 5, the temporary locking rib 51 and the temporary locking slope 52 are temporarily locked by rotating the second cover 43 in the closing direction (arrow B direction) in the temporarily locked state. Release the lock.

That is, as shown in FIG. 4, the temporary locking rib 51 and the temporary locking slope 52 are formed by the tip of the temporary locking rib 51 riding on the temporary locking slope 52 while the first cover 42 is in the closed position. , The second cover 43 is temporarily locked in the open position in an independent posture. Further, in this state, the second cover 43 is rotated in the closing direction, so that the tip of the temporary locking rib 51 is slid on the temporary locking slope 52 as shown by the arrow C in FIG. 5 (b). To release the temporary locked state. Then, the second cover 43 can be rotated in the closing direction.

Further, between the case body 21 of the resin case 20 and the cover 41, a set of first to third locked portions 37, 38, 39 and lock portions 47, 48, 49 that engage with each other as locking means. Is provided.

The pair of the first locked portion 37 and the locked portion 47 restrains the portion of the first cover 42 close to the first hinge 45 when the first cover 42 closes the upper surface opening 23a of the electric wire accommodating portion 23. Therefore, the first locked portion 37 and the locked portion 47 are the upper end of the side wall 36 of the electric wire accommodating portion 23 opposite to the bus bar accommodating portion 22, which is close to the first hinge 45, and the base end portion of the first cover 42. And are provided respectively.

The pair of the second locked portion 38 and the locked portion 48 restrains the portion of the first cover 42 close to the second hinge 46 when the first cover 42 closes the upper surface opening 23a of the electric wire accommodating portion 23. Therefore, the second locked portion 38 and the locked portion 48 are provided at the upper end of the side wall 35 on the bus bar accommodating portion 22 side of the electric wire accommodating portion 23 and the tip end portion of the first cover 42, which are close to the second hinge 46. ing.

The pair of the third locked portion 39 and the locked portion 49 restrains the tip end portion of the second cover 43 when the second cover 43 closes the upper surface opening 22a of the bus bar accommodating portion 22. Therefore, the third locked portion 39 and the locked portion 49 are provided at the upper end of the side wall 32 on the side opposite to the electric wire accommodating portion 23 of the bus bar accommodating portion 22 and at the tip end portion of the second cover 43.

Next, the operation will be described.
When this resin case 20 is used, as shown in FIGS. 4 and 5, the upper surface opening 23a of the electric wire accommodating portion 23 is closed by the first cover 42, and then the second cover 43 that closes the bus bar accommodating portion 22 is closed. The operations can be performed separately.

As a specific process sequence, first, the bus bar 11 and the voltage detection terminal 12 are assembled to the bus bar accommodating portion 22 of the resin case 20. At the same time, the voltage detection line 13 is arranged to accommodate the voltage detection line 13 in the electric wire accommodating portion 23 of the resin case 20. Then, in that state, in order to prevent the voltage detection line 13 from popping out from the electric wire accommodating portion 23, as shown in FIG. 4, it is rotated in the direction of the arrow A to close only the first cover 42.

At this time, the first locked portion 37 and the locked portion 47 are engaged with each other, the second locked portion 38 and the locked portion 48 are engaged with each other, and the first cover 42 is locked in the closed position. Further, in order to fix the bus bar 11 to the battery 3 in the next step, the second cover 43 is temporarily locked in an open state by a temporary locking means (temporary locking rib 51 and temporary locking slope 52) in a self-supporting posture. Locked. That is, when the tip of the temporary locking rib 51 rides on the temporary locking slope 52, the second cover 43 is temporarily held in the open position in an independent posture.

Next, in this state, the bus bar 11 is fixed to the electrodes 4A and 4B of the battery 3 with nuts through the upper surface opening 22a of the bus bar accommodating portion 22. After completing this step, the second cover 43 is rotated in the closing direction (in the direction of arrow B in FIG. 5). Then, the temporary locking state by the temporary locking means (temporary locking rib 51 and the temporary locking slope 52) is automatically released, and the second cover 43 can be rotated in the closing direction. That is, when the second cover 43 is rotated in the closing direction in the state shown in FIG. 4, the tip of the temporary locking rib 51 slides along the temporary locking slope 52. As a result, the temporary locking is released, and the second cover 43 can be rotated in the closing direction.

Then, by rotating the second cover 43 in the closing direction, the upper surface opening 22a of the bus bar accommodating portion 22 can be covered with the second cover 43. At this time, the second cover 43 is locked in the closed position by engaging the third locked portion 39 and the locked portion 49 with each other. As a result, the fixed portions of the bus bar 11 and the electrodes 4A and 4B are insulated and protected to prevent electric shock and the like.

In this way, when the bus bar module 10 is assembled to the battery 3 (when the bus bar 11 is fastened to the battery 3), the first cover 42 that covers the electric wire accommodating portion 23 can be kept closed. Therefore, the bus module 10 can be assembled to the battery 3 with the width of the resin case 20 reduced. Therefore, the resin case 20 does not interfere with the battery 3 and the assembly workability of the bus module 10 is not impaired.

Further, when the bus bar module 10 is assembled to the battery 3, the first cover 42 covering the electric wire accommodating portion 23 is kept closed, while the second cover 43 covering the bus bar accommodating portion 22 is kept open in a self-supporting posture. Can be left. Therefore, the assembly work of fastening the bus bar 11 to the electrodes 4A and 4B of the battery 3 with nuts can be easily proceeded.

Further, a second cover 43 that closes the bus bar accommodating portion 22 is integrally provided at the tip of the first cover 42 that closes the electric wire accommodating portion 23. Therefore, as compared with the case where the cover of the bus bar accommodating portion 22 is provided separately from the resin case (comparative example described later), the cost can be reduced by reducing the number of parts.

Further, since the second cover 43 is simply connected to the tip of the first cover 42 via a hinge (second hinge 46), the structure is simple, the molding cost can be reduced, and the cost is reduced. Can contribute to.

Further, since the first cover 42 and the second cover 43 are configured as one plate-shaped cover 41, the cover 41 is electrically opened to the bus bar 11 without being disturbed by the cover 41. The connected voltage detection line 13 can be arranged.

Further, the temporary locking means for temporarily holding the second cover 43 in the open position is composed of the temporary locking rib 51 and the temporary locking slope 52. Therefore, the temporary locking and the temporary locking of the second cover 43 can be performed with a simple configuration and a simple operation, which can contribute to cost reduction.

Next, the advantages of this embodiment as compared with the comparative example will be described. In each figure showing a comparative example, the same components as those in the present embodiment are designated by the same reference numerals and the description thereof will be omitted.

First, the bus module 110 shown as a comparative example will be described with reference to FIGS. 6 to 8.
6 is a partially disassembled perspective view of the power supply device of the comparative example, FIG. 7 is a partial external perspective view of the power supply device of the comparative example, and FIG. 8 is a partial external perspective view of the bus bar module of the comparative example.

As shown in FIGS. 6 to 8, the resin case 120 of the bus bar module 110 of the first comparative example includes a bus bar accommodating portion 122, an electric wire accommodating portion 123, an electric wire accommodating portion cover 142, and a hinge 145. It has one. However, the bus bar accommodating portion cover 143 is provided separately from the resin case 120. As described above, if the bus bar accommodating portion cover 143 that covers the bass bar accommodating portion 122 is provided separately from the resin case 120, the number of parts increases by that amount, and the cost tends to increase.

On the other hand, in the resin case 20 of the present embodiment, as shown in FIG. 3, a first cover 42 covering the electric wire accommodating portion 23 and a second cover 43 covering the bus bar accommodating portion 22 are integrally provided in the resin case 20. ing. Therefore, the cost can be reduced by reducing the number of parts.

Next, the advantages of the present embodiment will be described as compared with the comparative example in which the cover covering the electric wire accommodating portion and the cover covering the bus bar accommodating portion are both integrally provided in the resin case.

In the resin case 320 according to the second comparative example shown in FIG. 9, a plate-shaped cover 341 having a size that covers the electric wire accommodating portion 23 and the bus bar accommodating portion 22 together is connected to the case main body 21 via a hinge 345. ing. However, a hinge (second hinge 46 in the present embodiment) that allows the electric wire accommodating portion 23 and the bus bar accommodating portion 22 to be individually closed is not provided. In the resin case 320 of this comparative example, the cover of the bus bar accommodating portion 22 cannot be opened while the electric wire accommodating portion 23 is closed by the cover. Therefore, there is a problem in individually proceeding with the wiring work of the voltage detection line 13 and the fixing work of the bus bar 11.

On the other hand, in the resin case 20 of the present embodiment, as shown in FIG. 3, the first cover 42 covering the electric wire accommodating portion 23 and the second cover 43 covering the bus bar accommodating portion 22 are rotated by the second hinge 46. It is connected as possible. Therefore, the second cover 43 of the bus bar accommodating portion 22 can be opened while the electric wire accommodating portion 23 is closed by the first cover 42. Therefore, it becomes easy to individually proceed with the work of arranging the voltage detection line 13 and the work of fixing the bus bar 11.

In this second comparative example, by providing a hinge (corresponding to the second hinge 46 of the present embodiment) in the middle of the cover 341, the electric wire accommodating portion 23 is closed by the cover, and the bus bar accommodating portion 22 is provided. It is possible to keep the open. However, simply adding a hinge (corresponding to the second hinge 46 of the present embodiment) inevitably makes the portion of the cover 341 that covers the bus bar accommodating portion 22 unstable. Therefore, when fixing the bus bar module, it takes extra time to open the cover portion that covers the bus bar accommodating portion 22.

On the other hand, in the resin case 20 of the present embodiment, as shown in FIG. 4, the second cover 43 covering the bus bar accommodating portion 22 is opened while the first cover 42 covering the electric wire accommodating portion 23 is closed. Can be temporarily held in an independent position. Therefore, when fixing the bus bar module, it is not necessary to manually open the second cover 43 that covers the bus bar accommodating portion 22.

In the resin case 420 according to the third comparative example shown in FIG. 10, the covers 442 and 443 that can independently cover the electric wire accommodating portion 23 and the bus bar accommodating portion 22 are individually attached to the case main body 21 by hinges 445 and 446. It is connected to. In this comparative example, the two covers 442 and 443 are connected to the side walls 36 and 32 of the electric wire accommodating portion 23 and the bus bar accommodating portion 22 which are farthest from each other by hinges 445 and 446, and rotate in opposite directions. It can be opened and closed.

In this comparative example, the bus bar accommodating portion 22 can be opened while the electric wire accommodating portion 23 is closed by the cover. Therefore, in that respect, advantages common to those of the present embodiment can be obtained. However, since the cover 443 of the bus bar accommodating portion 22 and the cover 442 of the electric wire accommodating portion 23 are rotated in opposite directions, there is a problem in securing a work space and a mold cost at the time of molding is required. Cheap.

In the resin case 520 according to the fourth comparative example shown in FIG. 11, the covers 542 and 543 that can independently cover the electric wire accommodating portion 23 and the bus bar accommodating portion 22 are individually attached to the case main body 21 by hinges 545 and 546. It is connected to. However, in this comparative example, the cover 542 of the electric wire accommodating portion 23 is connected to the upper end of the side wall 36 on the side opposite to the bus bar accommodating portion 22 of the electric wire accommodating portion 23 by a hinge 545. Further, the cover 543 of the bus bar accommodating portion 22 is connected to the upper end of the side wall 33 on the electric wire accommodating portion 23 side of the bus bar accommodating portion 22 by a hinge 546. Therefore, both covers 542 and 543 can be opened and closed by rotating in the same direction.

Also in this comparative example, the bus bar accommodating portion 22 can be kept open while the electric wire accommodating portion 23 is closed by the cover. Therefore, in that respect, advantages common to those of the present embodiment can be obtained. Further, since the cover 543 of the bus bar accommodating portion 22 and the cover 542 of the electric wire accommodating portion 23 are rotated in the same direction, the problem of securing a work space is solved. However, there is a problem that the mold cost at the time of molding tends to be high.

Further, the connecting portion 24 connecting the adjacent side walls 33 and 35 of the bus bar accommodating portion 22 and the electric wire accommodating portion 23 has a groove portion into which the electric wire mounting portion 12b of the voltage detection terminal 12 is inserted from above. Therefore, if the cover 543 is connected to the side wall 33 via the hinge 546, the electric wire mounting portion 12b of the voltage detection terminal 12 may not be inserted into the groove from above. Therefore, the configuration as in this comparative example is not preferable because it may cause another problem in performing the assembly work.

In that respect, in the resin case 20 of the present embodiment, the upper parts of the electric wire accommodating portion 23 and the bus bar accommodating portion 22 can be left open at the time of arranging the voltage detection line 13, and therefore, as described above for assembling. Problem does not occur.

As described above, according to the present embodiment, it is possible to exhibit good assembling property while reducing the cost by reducing the number of parts.

Here, the features of the resin case of the bus module according to the present invention, the bus module, and the embodiment of the power supply device described above are briefly summarized and listed below in [1] to [4], respectively.
[1]
A bus bar accommodating portion 22 having an upper surface opening (22a) and accommodating a bus bar 11 that connects the electrodes (4A, 4B) of adjacent batteries (3) of the battery assembly (2) inside.
It has an upper surface opening (23a), is arranged adjacent to the bus bar accommodating portion (22) and is coupled, and internally, an electric wire (voltage detection line 13) electrically connected to the bus bar (11) is accommodated. Electric wire accommodating part (23) and
The electric wire accommodating portion (23) is rotatably coupled to a portion of the electric wire accommodating portion (23) opposite to the bus bar accommodating portion (22) by a first hinge (45), and the electric wire accommodating portion (23) is rotatably connected by a rotation operation in the closing direction. The first cover (42) that closes the upper surface opening (23a) and
The first cover (42) is rotatably coupled to the tip edge opposite to the first hinge (45) by the second hinge (46), and the first cover (42) is in the closed position. A second cover (43) that closes the upper surface opening (22a) of the bus bar accommodating portion (22) by being rotated in the closing direction.
With the first cover (42) in the closed position, the second cover (43) is temporarily locked in the open position in an independent posture, and in that state, the second cover (43) is rotated in the closed direction. Temporary locking means (temporary locking rib 51 and temporary locking slope 52) for releasing the temporary locking, and
Locking means (locked portions 37, 38, 39 and locking portions 47, 48, 49) for locking the first cover (42) and the second cover (43) in a closed position,
As an integrated resin molded product,
The resin case (20) of the bus module, which is characterized in that.
[2]
The resin case (20) of the bus module according to the above [1].
The temporary locking means is
A flexible temporary locking rib (51) projecting from the second cover (43) and
The second cover (43) is set to the open position by the tip of the temporary locking rib (51) provided in the bus bar accommodating portion (22) and the first cover (42) is in the closed position. Temporarily locks in a self-supporting posture, and in that state, the second cover (43) is rotated in the closing direction, so that the tip of the temporary lock rib (51) is slid to bring the temporary lock state. A temporary locking slope (52) that is released and allows the second cover (43) to rotate in the closing direction, and
including,
The resin case (20) of the bus module, which is characterized in that.
[3]
The positive electrode (4A) and the negative electrode (4B) of the adjacent batteries (3) are connected in series so that the batteries (3) of the battery assembly (2) composed of a plurality of batteries (3) arranged linearly are connected in series. ), And a plurality of buses (11) that electrically connect to each other.
A plurality of voltage detection lines (13) electrically connected to the positive electrode (4A) or the negative electrode (4B) via the respective bus bars (11), respectively.
A resin case (20) accommodating at least one bus bar (11) and the plurality of voltage detection lines (13), and a resin case (20).
With
The resin case (20) according to the above [1] or [2] is used as the resin case (20).
The bus bar (11) is housed in the bus bar accommodating portion (22) of the resin case (20).
The plurality of voltage detection lines (13) are housed in the electric wire accommodating portion (23) of the resin case (20).
A bus module (10) characterized by the above.
[4]
A battery assembly (2) composed of a plurality of batteries (3) arranged linearly, and
A bus module (10) that is mounted on the battery assembly (2) and electrically connects the batteries (3) to each other.
In the power supply device (1) provided with
As the bus module (10), the bus module according to the above [3] is provided.
A power supply unit (1).

1 Power supply 2 Battery assembly 3 Battery 4A Positive electrode (electrode)
4B Negative electrode (electrode)
10 Bus bar module 11 Bus bar 13 Voltage detection line 20 Resin case 22 Bus bar accommodating part 22a Top opening 23 Wire accommodating part 23a Top opening 37, 38, 39 Locked part (locking means)
42 1st cover 43 2nd cover 45 1st hinge 46 2nd hinge 47, 48, 49 Lock part (locking means)
51 Temporary locking rib (temporary locking means)
52 Temporary locking slope (temporary locking means)

Claims (4)

A bus bar accommodating portion having a top opening and accommodating a bus bar that connects electrodes of adjacent batteries of a battery assembly inside.
An electric wire accommodating portion having an upper surface opening, adjacent to and coupled to the bus bar accommodating portion, and internally accommodating electric wires electrically connected to the bus bar.
A first cover that is rotatably coupled to a portion of the electric wire accommodating portion opposite to the bus bar accommodating portion by a first hinge and closes the upper surface opening of the electric wire accommodating portion by a rotation operation in the closing direction.
The first cover is rotatably coupled to the tip edge opposite to the first hinge by a second hinge, and is rotated in the closing direction while the first cover is in the closed position. A second cover that closes the upper opening of the bus bar housing,
With the first cover in the closed position, the second cover is temporarily locked in an open position in which it rises upward from the second hinge in an independent posture, and in that state, the second cover rotates in the closing direction. Temporary locking means that releases the temporary locking by being operated, and
A locking means for locking the first cover and the second cover in a closed position,
As an integrated resin molded product,
The resin case of the bus module that is characterized by this. A bus bar accommodating portion having a top opening and accommodating a bus bar that connects electrodes of adjacent batteries of a battery assembly inside.
An electric wire accommodating portion having an upper surface opening, adjacent to and coupled to the bus bar accommodating portion, and internally accommodating electric wires electrically connected to the bus bar.
A first cover that is rotatably coupled to a portion of the electric wire accommodating portion opposite to the bus bar accommodating portion by a first hinge and closes the upper surface opening of the electric wire accommodating portion by a rotation operation in the closing direction.
The first cover is rotatably coupled to the tip edge opposite to the first hinge by a second hinge, and is rotated in the closing direction while the first cover is in the closed position. A second cover that closes the upper opening of the bus bar housing,
With the first cover in the closed position, the second cover is temporarily locked in the open position in an independent posture, and in that state, the second cover is rotated in the closing direction to release the temporary lock. Temporary locking means and
A locking means for locking the first cover and the second cover in a closed position,
As an integrated resin molded product,
The temporary locking means is
A flexible temporary locking rib projecting from the second cover,
Wherein provided in the bus bar accommodating portion, sealed and tentatively retaining freestanding position said second cover to said open position by said first cover ride the tip of the temporary engaging rib in the closed position, in that state When the second cover is rotated in the closing direction, the tip of the temporary locking rib is slid to release the temporary locking state, and the temporary locking rib is allowed to rotate in the closing direction. Locking slope and
including,
The resin case of the bus module that is characterized by this. A plurality of buses that electrically connect between the positive electrode and the negative electrode of the adjacent batteries so that the batteries of the battery assembly consisting of a plurality of linearly arranged batteries are connected in series.
A plurality of voltage detection lines electrically connected to the positive electrode or the negative electrode via the respective bus bars, and
A resin case accommodating at least one bus bar and the plurality of voltage detection lines, and
With
The resin case according to claim 1 or 2 is used as the resin case.
The bus bar is housed in the bus bar accommodating portion of the resin case.
The plurality of voltage detection lines are housed in the wire accommodating portion of the resin case.
A bus module that features that. A battery assembly composed of a plurality of linearly arranged batteries,
A bus module that is mounted on top of the battery assembly and electrically connects the batteries to each other.
In a power supply equipped with
The bus module according to claim 3 is provided as the bus module.
A power supply that is characterized by that.

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