JP2012190678A - Bus bar module for power storage unit - Google Patents

Abstract

In a bus bar module for a power storage unit, the cost for unitization is suppressed.
A bus bar module 20 includes a plurality of bus bars 50 and 51 formed of a low-resistance metal plate, and wiring that has one end connected to each bus bar 50 and 51 and the other end connected to a voltage detection connector. The pattern part 60 is sandwiched and integrated between the upper film and the lower film. Each bus bar 50 is provided with a hole 52 through which the electrodes of a plurality of power storage devices arranged in a line constituting the power storage unit are passed. The holes 52 of the bus bars 50 and 51 are aligned and arranged so as to have the same pitch P as the aligned arrangement pitch P of the plurality of power storage devices, and are arranged in two rows at intervals S between two electrodes of the power storage devices.
[Selection] Figure 2

Description

  The present invention relates to a bus bar module for a power storage unit, and in particular, connects each electrode terminal of a plurality of power storage devices of a power storage unit configured by arranging a plurality of power storage devices in an aligned manner to each power storage device. The present invention relates to a bus bar module for a power storage unit having wiring for detecting the voltage of the current.

  Since a power source for a vehicle is used with a high voltage and a large current, a plurality of power storage devices are connected in series, in parallel, or in series-parallel to form a power storage unit. In order to form a power storage unit, electrodes of adjacent power storage devices are connected by a connection member called a low resistance bus bar made of metal or the like. In addition, when the power storage unit is formed, in order to monitor the state of each power storage device, a voltage detection lead wire is drawn from the electrode of each power storage device and connected to the voltage detection device.

  For example, Patent Document 1 uses, as a power supply device for a vehicle, a printed circuit board in which a plurality of battery modules are arranged in parallel and a voltage detection line is provided in order to detect the voltage at the output terminal of each battery module. It is stated.

  Patent Document 2 discloses a wiring that includes a voltage detection line for detecting the voltage of each battery unit in a battery assembly that connects a plurality of battery units that are packaged with a laminate film and electrode terminals are drawn out from the inside of the laminate film. The use of plates is stated. It is described that one end of the voltage detection line of the wiring board is connected to an electrode terminal of each battery unit, and the other end is led out from one side of the wiring board corresponding to the battery alignment direction.

  Patent Document 3 discloses a configuration in which an elastic support base is bonded to the opposite side of the current-carrying joint surface with the connection terminal, and a waterproof gasket is integrally bonded to the joint surface with the connection terminal pack, as a power supply bus bar. ing.

  Patent Document 4 discloses a voltage detection line connection board provided with a connection clip corresponding to a voltage detection terminal of each cell in order to detect the voltage of each cell in an assembled battery in which a plurality of cells are stacked. And attaching each connection clip to each voltage detection terminal at one touch at a time.

  In Patent Document 5, as a battery module in which a plurality of thin batteries in which a power generation element is sealed by an exterior member is stacked in the thickness direction, an electrode of the thin battery and a part of the battery body are sandwiched from both sides in the stacking direction. The structure which has the plate-shaped clamping member to perform, and the connection part which connects an exterior member and the clamping member integrally is described. Thus, it is stated that stress can concentrate on the boundary between the electrode of the thin battery and the battery body due to vibration, and a crack can be avoided at the boundary.

JP 2006-73362 A Japanese Patent No. 3776726 JP-A-10-55790 JP-A-2005-116440 Japanese Patent No. 4379467

  For example, when N power storage devices arranged in an array are connected in series, the negative terminal of one power storage device of the adjacent power storage device and the positive electrode of the other power storage device are used using (N-1) bus bars. Terminal is connected. For example, fasteners such as bolts and nuts are used to connect the bus bar and the positive terminal or the negative terminal of the power storage device. Therefore, as N increases, the number of bus bars and the number of fasteners increase, and the number of man-hours for attaching and fastening the bus bars one by one increases. Further, in order to detect the voltage of each power storage device, it is necessary to pull out lead wires from the electrodes of each power storage device. If there are N power storage devices, N lead wires are pulled out, and as N increases, In addition, the number of lead wires increases, and the man-hours for the drawing work also increase. Thus, when the number of power storage devices increases, the cost for unitization increases.

  The objective of this invention is providing the bus-bar module for the electrical storage unit which can suppress the cost for unitization.

  A bus bar module for a power storage unit according to the present invention is for a power storage unit for connecting each electrode terminal of a plurality of power storage devices of a power storage unit configured by arranging a plurality of power storage devices in a predetermined connection method. A bus bar module having a plurality of bus bars made of metal plates for connection to respective electrode terminals of a plurality of power storage devices, a plurality of bus bar connection terminal portions at one end, and a plurality of voltages at the other end A wiring pattern portion comprising a conductor layer for transmitting a voltage measurement signal, a connection hole of the bus bar, and a voltage measurement terminal portion of the wiring pattern portion that has a measurement terminal portion; The upper and lower resin films are provided so as to be integrated with the bus bar and the wiring pattern portion sandwiched between the wiring pattern portion and the bus bar connection terminal portion of the wiring pattern portion.

  Further, in the bus bar module for the power storage unit according to the present invention, the plurality of bus bars are arranged along one direction at a predetermined one-way interval corresponding to a predetermined arrangement pitch of the plurality of power storage devices. Are arranged in two rows at predetermined intervals in the other direction corresponding to the interval between the positive terminal and the negative terminal of one power storage device, and the wiring pattern portion is arranged in two rows of bus bars. After being pulled out along the other direction from a plurality of bus bar connecting terminal portions connected to each bus bar constituting one row, the length is bent along the first one direction and predetermined in one direction. 1 row pattern portion extending in a second direction opposite to the first one direction and extending in the second one direction toward the voltage measuring terminal portion, and two rows of bus bar arrangements One row of A pattern portion for the other row for each bus bar, the pattern portion for the one row and a symmetrical pattern for the other row, wherein the upper and lower resin films are in the first one direction of the pattern for the one row. Between the portion extending in the first direction and the portion extending in the second one direction, along the one direction, up to the folded portion of the wiring pattern portion, and the first one direction of the other row pattern And a second slit provided along the one direction to the folded portion of the wiring pattern portion between the portion extending in the second one direction and the folded portion of the wiring pattern portion. By the way, it is preferable that the front and back can be reversed.

  In the bus bar module for the power storage unit according to the present invention, the upper and lower resin films may have a third slit extending in the other direction between the bus bars adjacent to each other of the plurality of bus bars arranged in one direction. preferable.

  According to the above configuration, the bus bar module for the power storage unit is integrated by sandwiching the bus bar and the wiring pattern portion while connecting the bus bar and the bus bar connecting terminal portion of the wiring pattern portion with the upper and lower resin films. . Since the wiring pattern is for voltage detection, it may have a certain amount of high resistance, but the bus bar needs to have a low resistance because it connects the electrodes of the adjacent power storage devices to flow current. In this way, different types of connection members having different resistance values are sandwiched between the upper and lower resin films in accordance with the purpose and integrated. This eliminates the need to attach a bus bar to each power storage device one by one and pull out the lead wires one by one, thereby reducing the cost of unitization.

  Further, in the bus bar module for the power storage unit, when the bus bars are arranged in two rows corresponding to the arrangement of the plurality of power storage devices, the wiring pattern portion is drawn out from each of the two rows of bus bar arrangements. After extending in the direction, fold back in the other direction. Then, the upper and lower resin films have slits between the wiring patterns that are folded back from one direction to the other direction. There are two slits corresponding to the two rows of bus bar arrangements. With these two slits, the upper and lower resin films can be turned upside down. Therefore, when two rows of bus bars of the bus bar module are attached in accordance with the arrangement arrangement of the plurality of power storage devices, the upper and lower resin films between the two rows of bus bar arrangements are reversed with the wiring pattern upside down to expose the plurality of power storage devices. can do. Thereby, the heat dissipation of the plurality of power storage devices can be effectively performed.

  In the bus bar module for the power storage unit, the upper and lower resin films have a third slit extending in the other direction between bus bars adjacent to each other of the plurality of bus bars arranged in one direction. In order to unitize a plurality of power storage devices, both ends are pressed by members called end plates. This pressing may change the interval of the bus bar arrangement, but by providing the third slit between the bus bars in the upper and lower resin films, it is possible to flexibly cope with this interval change.

It is a figure which shows the mode of the electrical storage unit to which the bus-bar module of embodiment which concerns on this invention was attached. It is a top view of the bus-bar module for electrical storage units in embodiment which concerns on this invention. It is a partially expanded view of the bus bar module for the power storage unit in the embodiment according to the present invention. It is a flowchart explaining the manufacture procedure of the bus-bar module for electrical storage units in embodiment which concerns on this invention. It is a figure explaining each component of a bus-bar module corresponding to FIG. It is a flowchart explaining another manufacturing procedure of the bus-bar module for electrical storage units in embodiment which concerns on this invention.

  Embodiments according to the present invention will be described below in detail with reference to the drawings. In the following description, a bus bar module for a power storage unit that is used in a power storage unit mounted on a vehicle will be described. This is described as a typical example of a power storage unit using a plurality of power storage devices. Other than this, any material may be used as long as it is used for a power storage unit for high voltage and large current use.

  In the following, it is assumed that the electrode of the power storage device protrudes from the upper surface side of the power storage unit, and that the bus bar module for the power storage unit is used so as to cover the electrode. May be better. For example, when the electrode of the power storage device protrudes from the side surface of the power storage unit, a bus bar module for the power storage unit can be provided on the side surface of the power storage unit. Further, in the following, a case where 24 flat power storage devices are arranged in a row in the thickness direction will be described, but this is an example, and the number of aligned power storage devices may be other than this, The arrangement of the power storage devices may be a plurality of rows instead of a single row.

The shapes, materials, dimensions, and the like described below are illustrative examples, and can be appropriately changed in accordance with the specifications of the bus bar module for the power storage unit.
Below, the same code | symbol is attached | subjected to the same element in all the drawings, and the overlapping description is abbreviate | omitted. In the description in the text, the symbols described before are used as necessary.

  FIG. 1 is a diagram showing a state in which a power storage unit bus bar module 20 is used in a power storage unit 10 mounted on a vehicle. Hereinafter, unless otherwise specified, the bus bar module 20 for the power storage unit will be simply described as the bus bar module 20.

  The power storage unit 10 is a single unit in which 24 power storage devices 16 are sandwiched and pressed by end plates 12 and 14 from both sides thereof. In FIG. 1, illustration of a fastening portion that sandwiches the 24 power storage devices 16 between the end plates 12 and 14 is omitted.

  The power storage device 16 is a flat secondary battery. In FIG. 1, the XYZ axes including the reference numerals are shown, but the thickness direction of the power storage device 16 is the X direction, the width direction is the Y direction, and the height direction is the Z direction. The power storage device 16 has a rectangular shape on the YZ plane, and has an electrode terminal 18 on the upper surface on the upper side in the Z direction. Two electrode terminals 18 are provided in one power storage device 16, one being a positive electrode and the other being a negative electrode. The two electrode terminals 18 are provided at both ends of the upper surface of the power storage device 16 in the Y direction, that is, in the width direction.

  In the case of FIG. 1, 24 power storage devices 16 are arranged along the X direction, that is, along the thickness direction. In this case, the electrodes of the adjacent power storage devices 16 are arranged so that the electrodes having opposite characteristics are adjacent to each other. For example, in FIG. 1, if the + Y side electrode terminal 18 of the power storage device 16 that contacts the left end plate 12 is a positive electrode, the + Y side electrode terminal 18 of the right power storage device 16 is a negative electrode. Further, the + Y side electrode terminal 18 of the right side power storage device 16 is a positive electrode. As described above, the electrode terminals 18 arranged on the + Y side of the power storage unit 10 are arranged in the + X direction along the positive electrode-negative electrode-positive electrode-negative electrode-positive electrode ..., positive electrode and negative electrode. Are alternately arranged.

  Similarly, the -Y side electrode terminal 18 of the power storage device 16 that contacts the left end plate 12 is a negative electrode, while the -Y side electrode terminal 18 of the right power storage device 16 is a positive electrode. Furthermore, the electrode terminal 18 on the −Y side of the power storage device 16 on the right side is a negative electrode. Thus, the electrode terminal 18 arranged in alignment on the −Y side of the power storage unit 10 has a negative electrode—a positive electrode—a negative electrode—a positive electrode—a negative electrode, and a negative electrode and a positive electrode along the + X direction. The electrodes are arranged alternately.

  In the case of this example, with respect to the electrode terminal 18 arranged on the + Y side of the power storage unit 10, starting from the right electrode terminal 18 except for the leftmost electrode terminal 18, the negative electrode and the right positive electrode thereof Are connected to each other. In addition, with respect to the electrode terminal 18 arranged in alignment on the −Y side of the power storage unit 10, starting from the leftmost electrode terminal 18, the negative electrode and the right positive electrode are connected to each other. In this way, the 24 power storage devices 16 are connected in series as a whole. The leftmost electrode terminal 18 of the electrode terminals 18 arranged on the + Y side of the power storage unit 10 serves as the positive electrode of the entire power storage unit 10, and the rightmost electrode terminal 18 serves as the entire power storage unit 10. Of the negative electrode.

  The bus bar module 20 has a function of connecting adjacent electrodes for connecting the 24 power storage devices 16 described above in series, and a function of drawing out a lead wire for detecting the voltage of each power storage device 16. It is a part.

  FIG. 2 is a plan view of the bus bar module 20, and FIG. 3 is an enlarged detailed view of a portion indicated by C in FIG. FIG. 3 shows a plan view of a portion C, a cross-sectional view taken along line DD, and a cross-sectional view taken along line EE.

  The bus bar module 20 is a film disposed so as to cover the electrode terminals 18 protruding to the upper surface side of the power storage unit 10, and has low resistance bus bars 50 and 51 for connecting between the adjacent electrode terminals 18 therein. And a relatively high resistance wiring pattern portion 60 connected to the bus bars 50 and 51 and drawn out to the end portion.

  The bus bar module 20 is composed of four parts. That is, one elongated portion 22 corresponding to the electrode terminal 18 aligned in the −Y direction on the upper surface side of the power storage unit 10, and the electrode terminal 18 aligned in the + Y direction on the upper surface side of the power storage unit 10. The other side elongated portion 24, the middle side elongated portion 26 separated halfway by the slits 70 and 72 between the one side elongated portion 22 and the other side elongated portion 24, the one side elongated portion 22, and the other side elongated portion 24. And the central elongate portion 26 are constituted by four portions of a folded portion 28 which is a portion connecting the base portions in the + X direction.

  The slit 70 is a cut provided between the one-side elongated portion 22 and the central-side elongated portion 26 and extends from the −X direction to the + direction to the folded portion 28. Similarly, the slit 72 is a cut provided between the other-side elongated portion 24 and the central-side elongated portion 26 and extends from the −X direction to the plus portion 28 to the folded portion 28. The slit lengths of the slit 70 and the slit 72 are set to be the same.

  In this way, a slit is provided between the one side elongated portion 22 and the center side elongated portion 26 and between the other side elongated portion 24 and the center side elongated portion 26 up to the folded portion 28. As shown in FIG. 5, the center side elongated portion 26 can be turned upside down at the folded portion 28. That is, the one side elongated portion 22 is disposed and attached to the electrode terminal 18 aligned in the −Y direction on the upper surface side of the power storage unit 10, and the other side elongated portion 24 is aligned in the + Y direction on the upper surface side of the energy storage unit 10. The central elongated portion 26 can be folded back so as to be peeled off from the upper surface side of the power storage unit 10 while being disposed and attached to the electrode terminal 18. Thus, the upper surface side of the power storage unit 10 is exposed where the central elongated portion 26 is peeled off, and for example, when the power storage unit 10 generates heat, it is easy to dissipate heat from the upper surface side to the atmosphere.

  In the bus bar module 20, unlike the slits 70 and 72, the slit 74 provided between the bus bars 50 and 51 extends in the Y direction. When the plurality of power storage devices 16 are unitized, as described with reference to FIG. 1, the plurality of power storage devices 16 are sandwiched and pressed by the end plates 12 and 14 at both ends. As a result, the interval between the arrangements of the bus bars 50 and 51 may change, but the slit 74 is provided so as to follow the change in the interval.

  As shown in FIG. 3, the bus bar module 20 is formed by superimposing a lower film 30 and an upper film 40 which are transparent resin films, and sandwiching the bus bars 50 and 51 and the wiring pattern portion 60 therebetween. It is a thing. 2 and 3 are plan views of the bus bar module 20 and correspond to a top view, but the upper film 40 is transparent, so that the bus bars 50 and 51 and the wiring pattern portion 60 can be seen.

  The lower film 30 and the upper film 40 are transparent resin films as described above, but films having insulating properties and appropriate heat resistance can be used. Here, a polyethylene terephthalate (PET) film is used. PET is used because of its low cost and easy availability. Of course, a film other than PET may be used, and a colored resin or the like may be used instead of being transparent.

  As shown in FIG. 3, a hole 33 formed in the lower film 30 and a hole 43 formed in the upper film 40 are for partially exposing the bus bars 50 and 51.

  The lower film 30 and the upper film 40 have almost the same shape including the slits 70, 72, 74 and the holes 33, 43, but either one is set short at the end on the −X side of the central elongated portion 26. Is done. This is because the wiring pattern portion 60 is exposed and connected to the connector 80 at the end. Hereinafter, the description will be continued on the assumption that the end portion of the upper film 40 is shorter than the end portion of the lower film 30 and the wiring pattern portion 60 is exposed at the −X side end portion of the central elongated portion 26 in the top view.

  Bus bars 50 and 51 are made of a metal plate, and are provided with holes 52 through which electrode terminals 18 of power storage device 16 are passed. The bus bar 50 connects the positive electrode of one power storage device 16 and the negative electrode of the other power storage device 16 between adjacent power storage devices 16 of the power storage devices 16 arranged in the X direction of the power storage unit 10. It is for connection. Accordingly, the bus bar 50 is provided with two holes 52 at a hole interval corresponding to the pitch P of the arrangement arrangement of the plurality of power storage devices 16 in the power storage unit 10 in the X direction. The bus bar 51 is a low resistance member in which the hole 52 is a single metal plate and does not have a function of connecting the two electrode terminals 18 to each other, but has a hole 52 through which the electrode terminal 18 passes and a current flows. This is common with the bus bar 50. Therefore, for convenience, this is also described as a bus bar.

  The bus bars 50 and 51 are arranged in two rows. That is, assuming that the X direction is one direction and the Y direction is the other direction, the bus bar has a predetermined one-way interval 2P corresponding to the arrangement pitch P of 24 power storage devices 16 that are a predetermined number. 50 arranged in one direction along one direction are arranged in two rows at the same other direction interval S corresponding to the interval S between the positive terminal and the negative terminal of one power storage device 16. The bus bar 51 is arranged so that the distance between the hole 52 and the hole 52 of the adjacent bus bar 50 is P.

  For the bus bars 50 and 51, an aluminum plate, a copper plate, or the like can be used. As an example of the dimensions of the bus bars 50 and 51, the thickness is about 1 mm, the width is about 15 mm, the length is about 28 mm, the inner diameter of the holes 52 is about 5 mm, and the interval between the holes 52 is about 16 mm. Of course, these dimensions can be changed according to the specifications of the power storage unit 10.

  The wiring pattern portion 60 is a wiring that is used to connect the bus bars 50 and 51 and the connector 80 and detect the voltage of each power storage device 16 connected to the bus bars 50 and 51 and is formed of a conductive layer. . Since the bus bars 50 and 51 use a low-resistance metal plate because a current flows, the wiring pattern portion 60 is for voltage detection and may have a relatively high resistance. As this wiring pattern part 60, what formed copper foil in the predetermined pattern can be used. The thickness of copper foil can use a general thing, for example, can set thickness to 16 micrometers. In the above example, if the bus bars 50 and 51 are body plates having a thickness of 1 mm, the wiring pattern portion 60 has a high resistance of 1000/16 = about 60 times that of the bus bars 50 and 51 compared with the same plane dimensions. is there.

  As shown in FIG. 3, the wiring pattern portion 60 is disposed so as to face the upper surface side of the lower film 30, that is, the lower surface side of the upper film 40 when integrated with the upper film 40. The wiring pattern portion 60 includes a bus bar connection terminal portion 62 connected to the bus bars 50 and 51 and a portion extending from the bus bar connection terminal portion 62 to reach the connector 80.

  The bus bar connection terminal portion 62 is a wiring whose tip is connected to the ends of the bus bars 50 and 51, and is formed as a meandering pattern. The meandering pattern is used to cope with the fact that the interval between the adjacent bus bars 50 and 51 may change as described with reference to the slit 74.

  The portion extending from the bus bar connection terminal portion 62 to the connector 80 includes one side pattern portion 64 in the one side elongated portion 22, the other side pattern portion 65 in the other side elongated portion 24, and a folded pattern portion 66 in the folded portion 28. 67 and a central pattern portion 68 in the central elongated portion 26.

  Actually, the one side pattern part 64, the folded pattern part 66, and a part of the center side pattern part 68 are connected to form a one line pattern part, and the other side pattern part 65, the folded pattern part 67, and the center side. The other row pattern portion is formed by being connected to a part of the pattern portion 68.

  That is, after being pulled out along the Y direction which is the other direction from the bus bar connection terminal portion 62 connected to each of the bus bars 50 and 51 constituting one row of the two rows of bus bar arrangements, in the first one direction. It is bent along a certain + X direction and extends as a one-side pattern portion 64 by a predetermined length in the X direction. Thereafter, the folded pattern portion 66 is folded in the −X direction, which is the second one direction opposite to the + X direction so far, and is connected to the connector 80 as a part of the center side pattern portion 68. Extends in the -X direction. These constitute a one-row pattern portion.

  The other row pattern row is symmetrical with the one row pattern portion with respect to the axis extending in the X direction. That is, after being pulled out along the Y direction from the bus bar connection terminal portion 62 connected to each bus bar 50, 51 constituting the other one row of the two rows of bus bar arrangements, it is bent along the + X direction, The other side pattern portion 65 extends in a predetermined length in the X direction. Thereafter, the folded pattern portion 67 is folded back in the −X direction opposite to the + X direction so far, and as a part of the center side pattern portion 68, toward the end connected to the connector 80 in the −X direction. Extend. These constitute the other row pattern portion.

  The bus bar module 20 having the configuration shown in FIGS. 2 and 3 is used as follows. That is, as shown in FIG. 1, the plurality of power storage devices 16 are arranged in the X direction with the thickness direction being the X direction, and both sides thereof are sandwiched and pressed by the end plates 12 and 14. In this state, on the upper surface side of the power storage device 16, the electrode terminals 18 arranged in a line with a pitch P along the X direction protrude in two rows with an interval of S in the Y direction. The holes 52 of the bus bar module 20 are covered with the two rows of electrode terminals 18. Since the holes 52 of the bus bar module 20 are arranged at a pitch P in the X direction and at an interval S in the Y direction, the electrode terminals 18 protrude from the holes 52 of the bus bar module 20, respectively.

  A part of the bus bars 50 and 51 is exposed around the hole 52 of the bus bar module 20 by the hole 33 of the lower film 30 and the hole 43 of the upper film 40. Further, male screws are engraved in advance on the electrode terminals 18 of the power storage device 16. Therefore, using the nut, the electrode terminal 18 of each power storage device 16 and the bus bars 50 and 51 exposed in the holes 43 of the bus bar module 20 are firmly mechanically fastened and electrically connected. Since the bus bars 50 and 51 are arranged so that the plurality of power storage devices 16 are connected in series, the leftmost electrode terminal 18 of the electrode terminals 18 arranged in the + Y direction of the power storage unit 10 is the positive electrode as the entire power storage unit 10. It becomes an electrode, and the rightmost electrode terminal 18 becomes a negative electrode as the whole power storage unit 10.

  As described above, the bus bar module 20 is integrated with the plurality of bus bars 50 and 51 arranged at the predetermined pitch P and the interval S, so that the bus bars 50 and 51 are attached to the electrode terminals 18 one by one. There is no need. Thereby, the man-hour for comprising the electrical storage unit 10 reduces significantly.

  In the bus bar module 20, each of the bus bars 50 and 51 includes a bus bar connection terminal portion 62, one side pattern portion 64, the other side pattern portion 65, folded pattern portions 66 and 67, and a wiring pattern portion 60 including a center side pattern portion 68. Thus, the connector 80 is connected to the end of the central elongated portion 26. The connector 80 is connected to a voltage detection device (not shown).

  As described above, the bus bar module 20 is integrated with the wiring pattern portion 60 that connects the bus bars 50 and 51 and the connector 80. Therefore, it is necessary to connect voltage detection lead wires to the electrode terminals 18 one by one. Absent. As a result, a large number of lead wires for voltage detection can be eliminated, and man-hours for wiring for voltage detection can be greatly reduced.

  4 and 5 are diagrams for explaining a manufacturing procedure of the bus bar module 20. FIG. 4 is a flowchart showing the manufacturing procedure, and FIG. 5 is a diagram in which the components of the bus bar module 20 are arranged from the lower side to the upper side according to the manufacturing procedure.

  In order to manufacture the bus bar module 20, first, a PET sheet (A) is prepared as the lower film 30, and set in a vacuum press apparatus (S10). The state of the prepared lower film 30 is shown on the lowermost side of FIG. Corresponding to the one side elongated portion 22, the other side elongated portion 24, the center side elongated portion 26, and the folded portion 28 of the bus bar module 20, the one side elongated portion 32, the other side elongated portion 34, and the center side elongated portion of the lower film 30. 36, a folded portion 38 is shown. Moreover, a mode that the hole 33 for exposing the bus-bars 50 and 51 is provided in the lower film 30 is shown.

  The shape of the lower film 30 can be obtained by punching a PET sheet using a press processing apparatus. Or it can also shape | mold into a predetermined shape using an etching technique.

  Next, the copper foil pattern that is the wiring pattern portion 60 is set on the upper surface of the PET sheet (A) that is the lower film 30 in a predetermined arrangement relationship (S12). A jig can be used for setting, and an appropriate fixing adhesive or the like can be used. In the second row from the bottom of FIG. 5, the prepared wiring pattern portion 60 is shown. Such a wiring pattern portion can be obtained by etching a copper foil into a predetermined pattern using a photolithographic technique or the like.

  Next, the bus bars 50 and 51 are set in a predetermined arrangement relationship on the upper surface of the PET sheet (A) on which the wiring pattern portion 60 is arranged (S14). The predetermined arrangement relationship is to arrange them in the X direction at an arrangement pitch of 2P and arrange them in two rows at intervals S in the Y direction. A jig can be used for setting, and an appropriate fixing adhesive or the like can be used. In the third row from the bottom of FIG. 5, the prepared bus bars 50 and 51 are in a predetermined arrangement relationship. FIG. 5 shows a state in which holes 52 through which the electrode terminals 18 of the power storage device 16 are provided are provided in the bus bars 50 and 51.

  Next, a PET sheet (B) as the upper film 40 is prepared and set on the upper surface of the PET sheet (A) on which the bus bars 50 and 51 and the wiring pattern portion 60 are arranged in a predetermined arrangement relationship. A jig can be used for the set. Then, the vacuum press apparatus is operated under a predetermined condition (S16). Accordingly, the bus bars 50 and 51 and the wiring pattern portion 60 are sandwiched and integrated between the PET sheet (B) and the PET sheet (A) in a predetermined arrangement relationship. The integrated state is as described in FIG.

  The PET sheet (B) as the prepared upper film 40 is shown on the uppermost side of FIG. Corresponding to the one side elongated portion 22, the other side elongated portion 24, the center side elongated portion 26, and the folded portion 28 of the bus bar module 20, the one side elongated portion 42, the other side elongated portion 44, and the center side elongated portion of the upper film 40. 46 and the folding | returning part 48 are shown. Further, the upper film 40 is shown with holes 43 for exposing the bus bars 50 and 51. Further, in order to connect to the connector 80, the end of the central elongated portion 46 of the lower film 30 is the end of the central elongated portion 46 of the upper film 40 corresponding to the shortened portion 47 so that the wiring pattern portion 60 is exposed. It is shown that it is shorter than the part.

  Thus, when integrated by a vacuum press, it will take out from a vacuum press apparatus (S18), and the assembly | attachment of the connector 80 will be performed (S20). Specifically, each of the wires constituting the wiring pattern portion 60 exposed at the end of the central elongated portion 26 of the bus bar module 20 is connected to each terminal of the connector 80. When the connector 80 is an insertion type, the end of the central elongated portion 26 of the bus bar module 20 is inserted into the connector 80. As a result, each voltage state of each power storage device 16 constituting the power storage unit 10 is measured by the voltage detection device via the connector 80.

  In the above description, the wiring pattern portion 60 is described as using a copper foil molded into a predetermined pattern. Unlike the bus bars 50 and 51 through which a current flows, the wiring pattern portion 60 is for detecting a voltage, and therefore may have a high resistance to some extent. Therefore, a method of printing a conductive paste can be used. FIG. 6 is a flowchart showing a manufacturing procedure of the bus bar module 20 in which a silver paste is used as the conductive paste and a predetermined wiring pattern is formed on the lower film 30 by screen printing.

  Here, first, the PET sheet (A) as the lower film 30 is set in a screen printing machine (S30). Then, a screen plate is set on the upper surface of the PET sheet (A) in a predetermined positional relationship (S32). The screen plate is one in which a pattern similar to the wiring pattern portion 60 described in FIGS. 2 and 4 is opened. The predetermined positional relationship satisfies the positional relationship of the wiring pattern portion 60 with respect to the lower film 30, as shown in FIG. Next, a silver paste is printed using this screen plate (S34). That is, the wiring pattern part 60 made of silver paste is formed on the upper surface of the PET sheet (A) that is the lower film 30. The thickness of the silver paste can be, for example, about 30 μm to about 50 μm.

  When printing is finished, the PET sheet (A) on which the wiring pattern portion 60 is formed is taken out from the screen printer (S36), set in a baking furnace (S38), and baked (S40). Firing can be performed at about 90 ° C., for example. When the baking is finished, the PET sheet (A) having the wiring pattern portion 60 that has been baked is taken out from the baking furnace (S42).

The silver paste has a characteristic of 4 × 10 ⁻⁵ Ωcm after proper firing. Since copper is 1.7 × 10 ⁻⁶ Ωcm, silver paste is about 20 times higher resistance than copper when it has the same thickness and the same planar dimensions. At this level, there is no problem as a voltage detection wiring.

  And PET sheet (A) with the wiring pattern part 60 is set to a vacuum press apparatus (S42). This step has the same contents as S10 in FIG. Then, the bus bars 50 and 51 are set on the PET sheet (A) with the wiring pattern portion 60 (S46). This step has the same contents as S14 in FIG. Compared with FIG. 4, the process of S14 which sets the wiring pattern part 60 to a PET sheet (A) becomes unnecessary.

  The subsequent steps are the same as S16, S18, and S20 described in FIG. That is, the PET sheet (B) which is the upper film 40 is set and vacuum pressed (S48), and the one integrated by the vacuum press is taken out (S50), and the connector is assembled (S52). Thus, a bus bar module using the conductive paste can be manufactured.

  The bus bar module for a power storage unit according to the present invention can be used for, for example, a power storage unit mounted on a vehicle.

  DESCRIPTION OF SYMBOLS 10 Electric storage unit, 12, 14 End plate, 16 Electric storage apparatus, 18 Electrode, 20 Busbar module, 22 One side elongate part, 24 Other side elongate part, 26 Center side elongate part, 28 Folding part, 30 Lower film, 32 (lower part One side elongated portion, 33,43 holes, 34 (lower film) other elongated portion, 36 (lower film) middle elongated portion, 38 (lower film) folded portion, 40 upper film, 42 One side elongated portion (of the upper film), 44 (other portion of the upper film), 46 (center portion of the upper film), 47 shortened portion, 48 (upper film) folded portion, 50, 51 bus bar, 52 (Bus bar) hole, 60 wiring pattern part, 62 bus bar connection terminal part, 64 one side pattern part, 65 other side pattern part, 66 67 fold pattern portion 68 center side pattern portions, 70 and 72 (for folding) slit, between 74 busbar) slit 80 connector.

Claims (3)

A bus bar module for a power storage unit for connecting each electrode terminal of a plurality of power storage devices of a power storage unit configured by arranging a plurality of power storage devices in a predetermined connection method,
A plurality of bus bars made of metal plates for connecting to the respective electrode terminals of the plurality of power storage devices;
A wiring pattern portion having a plurality of bus bar connection terminal portions on one end, a plurality of voltage measurement terminal portions on the other end, and comprising a conductor layer for transmitting a voltage measurement signal;
The bus bar connection hole and the voltage measurement terminal part of the wiring pattern part are exposed, and the bus bar and the wiring pattern part are sandwiched together while connecting the bus bar and the bus bar connection terminal part of the wiring pattern part. Upper and lower resin films,
A bus bar module for a power storage unit. In the bus bar module for a power storage unit according to claim 1,
Multiple busbars
A plurality of power storage devices that are aligned and arranged along one direction at a predetermined one-way interval corresponding to a plurality of predetermined power storage device alignment arrangement pitches are the positive and negative terminals of one power storage device. Are arranged in two rows at predetermined intervals in the other direction corresponding to the interval between
The wiring pattern part
After being pulled out along the other direction from a plurality of bus bar connecting terminal portions connected to each bus bar constituting one row of the two rows of bus bar arrangements, the direction is bent along the first one direction. A one-row pattern portion extending in a second length toward the voltage measurement terminal portion by being folded back in a second one direction opposite to the first one direction. ,
A pattern portion for the other row for each bus bar constituting one row of the two rows of bus bar arrangements, wherein the pattern portion for the other row is symmetrical to the one row pattern portion;
Have
The upper and lower resin films are
A first slit provided in one direction between the portion extending in the first one direction of the one-row pattern and the portion extending in the second one direction, up to the folded portion of the wiring pattern portion;
A second slit provided along the one direction between the portion extending in the first one direction of the pattern for the other row and the portion extending in the second one direction to the folded portion of the wiring pattern portion;
A bus bar module for a power storage unit, characterized in that it can be turned upside down at the folded portion of the wiring pattern portion. The bus bar module for a power storage unit according to claim 2,
The upper and lower resin films are
A bus bar module for a power storage unit, having a third slit extending in the other direction between adjacent bus bars of a plurality of bus bars arranged in one direction.

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