JP4993935B2 - Assembled battery - Google Patents

Description

  In the present invention, a number of batteries are arranged in a multi-stage multi-row in a parallel posture, a plurality of batteries are connected in parallel, and further, batteries connected in parallel are further connected in series. The present invention relates to an assembled battery that is connected in series and in multiple parallels and stored in a holder case.

The assembled battery can increase the output current by increasing the number of batteries connected in parallel, and can increase the output voltage by the number of batteries connected in series. For this reason, battery packs used in applications that require high output, such as bicycles, motorcycles, tools, uninterruptible power supplies, automobiles, etc., connect multiple batteries in parallel and connect them in series. To increase the output. Because it is necessary to change the number of built-in batteries depending on the application, it is important to simplify the design change to change the number of batteries and to produce the optimum assembled battery for the application at low cost in large quantities. is there. The present inventor has developed an assembled battery having the structure shown in FIG. 1 for the purpose of realizing this. (See Patent Document 1)
JP 2005-56721 A

  In this assembled battery, batteries 91 arranged vertically and horizontally are divided into a plurality of parallel units 96. In each parallel unit 96, a plurality of batteries 91 are arranged in a plurality of rows in the same direction, and lead plates 95 are connected to electrodes at both ends of the batteries to be connected in parallel. A plate-like spacer 97 is disposed between the parallel units 96. The lead plate 95 of the parallel unit 96 is connected to a circuit board 94 arranged perpendicular to one side. With this structure, the circuit board 94 and the parallel unit 96 are connected to form a battery block 93, and the battery block 93 is housed in the outer case 92.

  The assembled battery of FIG. 1 can easily change the number of batteries to be stored. However, an assembled battery that accommodates a large number of batteries becomes heavier as a whole, so that a stronger strength is required, and further, it is necessary to improve the safety of the battery. This is because an assembled battery used for an application with a large output becomes heavier due to an increase in the number of batteries stored therein, and a probability that the heat generation of the battery increases and a thermal runaway increases.

  The present invention has been developed for the purpose of solving the above-mentioned drawbacks. An important object of the present invention is to store a large number of batteries, change the number of batteries to be stored easily, store a large number of batteries and connect them to a strong integrated structure, and improve safety. It is to provide a battery pack that can be used.

The assembled battery of the present invention has the following configuration in order to achieve the above-described object.
The assembled battery includes a holder case 2 in which a plurality of batteries 1 are stored in a plurality of rows in parallel with each other, and a circuit board 4 that is electrically connected to the batteries 1 stored in the holder case 2. With. The holder case 2 is divided into a plurality of parallel cases 3 formed by connecting a plurality of built-in batteries 1 in parallel, and the plurality of parallel cases 3 are stacked in the step direction and connected to each other. Furthermore, in each parallel case 3, a plurality of batteries 1 are accommodated in a single row with the positive and negative electrodes oriented in the same direction to form parallel units 6. The parallel unit 6 connects the lead plate 5 to the electrode of each battery 1 housed in the parallel case 3, and connects the plurality of batteries 1 housed in the parallel case 3 with the lead plate 5 in parallel with each other. ing. Further, the parallel unit 6 is provided with a connecting portion 5 </ b> A by projecting the lead plate 5 from the parallel case 3. In the assembled battery, adjacent parallel units 6 are stacked with the connecting portions 5A of the lead plates 5 disposed on the opposing surface of the circuit board 4, and the connecting portions 5A of the lead plates 5 are directly or directly adjacent to the parallel units 6. Are connected to the circuit board 4 via the connecting portion 5A, and the parallel units 6 stacked together via the lead plate 5 and the circuit board 4 are integrally connected.

  The assembled battery of the present invention includes a substrate holder 7 that accommodates the circuit board 4, and the substrate holder 7 and the parallel unit 6 can be connected to a fixed position by a fitting structure. Furthermore, the assembled battery of the present invention has a connecting plate 8 disposed on the opposite side of the parallel case 3 to the substrate holder connecting side, and a plurality of parallel cases 3 stacked and connected in multiple stages are connected to the substrate holder 7. Arranged between the connecting plates 8, the parallel case 3 can be connected to both the substrate holder 7 and the connecting plate 8.

  In the assembled battery of the present invention, adjacent parallel cases 3 can be stacked by being connected to each other in a fixed position with a fitting structure. Moreover, the assembled battery of this invention can adhere | attach and laminate | stack the adjacent parallel case 3 with a double-sided adhesive tape.

  In the assembled battery of the present invention, spacer ribs 14 disposed between the batteries 1 to be housed can be provided in the parallel case 3 so as to protrude from the inner surface.

  In the assembled battery of the present invention, the battery 1 accommodated in the parallel case 3 is a cylindrical battery, and the parallel case 3 is formed by forming a side plate 3a on the uneven surface along the outer surface of the cylindrical battery to be accommodated. The juxtaposed case 3 can be stacked such that the convex portions are located in the concave portions of the side surface plate 3a.

  In the assembled battery of the present invention, as a lead plate 5, a metal plate is bent into a groove shape, the outer can of the battery 1 is placed in the groove, and an electrode connected to the outer can is connected to the lead plate 5. be able to.

  The assembled battery of the present invention can be potted in the parallel case 3 by filling the parallel case 3 with the insulating resin 17.

  The assembled battery of the present invention is characterized in that it can accommodate a large amount of batteries while simplifying the change of the number of batteries to be accommodated, and that the entire battery can have a strong integrated structure. That is, the assembled battery of the present invention connects a plurality of batteries in parallel with lead plates, puts them in a parallel case to form a parallel unit, and further connects the plurality of parallel units to the circuit board with lead plates. This is because it is linked to the structure. In particular, the assembled battery having this structure is characterized in that the impact strength can be increased even if the batteries are stored in multiple stages and in multiple rows and the weight of the battery is considerably increased. This is because the batteries are arranged in a row and housed in a parallel case to form a parallel unit, which is stacked in multiple stages, so that the weight of the battery can be distributed and supported in the parallel unit. Moreover, the assembled battery of this invention can disperse | distribute and accommodate a battery in a parallel unit, and can improve safety | security. This is because when one of the batteries becomes thermal runaway, the parallel unit can prevent the induction of thermal runaway.

  Embodiments of the present invention will be described below with reference to the drawings. However, the example shown below illustrates the assembled battery for embodying the technical idea of the present invention, and the present invention does not specify the assembled battery as follows.

  Further, in this specification, in order to facilitate understanding of the scope of claims, numbers corresponding to the members shown in the examples are indicated in the “claims” and “means for solving problems” sections. It is added to the members. However, the members shown in the claims are not limited to the members in the embodiments.

  The assembled battery shown in FIG. 2 and FIG. 6 is electrically connected to a holder case 2 in which a plurality of batteries 1 are stored in a plurality of rows in a plurality of rows in parallel with each other, and a battery 1 stored in the holder case 2. Circuit board 4. Further, in the assembled battery of FIG. 6, the circuit board 4 is accommodated in the board holder 7. In the assembled battery shown in these drawings, a plurality of parallel units 6 and a circuit board 4 are connected in an integrated structure to form a battery core pack 10. In the battery pack of FIG. 5, the battery core pack 10 is housed in an outer case 9. However, the assembled battery of the present invention does not necessarily contain the battery core pack in the outer case. In particular, the assembled battery incorporated in the device can be incorporated in the device in a core pack state. Further, the battery core pack surface can be covered with an insulating film such as a heat-shrink film without being housed in an outer case.

  In the assembled battery, the holder case 2 is divided into a plurality of parallel cases 3. The parallel case 3 is manufactured by molding an insulating material such as plastic. The parallel case 3 contains a plurality of batteries 1 connected in parallel to each other. The parallel cases 3 divided into a plurality are stacked in the step direction (vertical direction in the figure) and connect the upper and lower parallel cases 3 to each other.

  Further, each parallel case 3 accommodates a plurality of batteries 1 arranged in a row with the orientation of the positive and negative electrodes facing the same direction. A lead plate 5 is connected to the electrode of each battery 1 accommodated in the parallel case 3, and a plurality of batteries 1 accommodated in the parallel case 3 are connected in parallel with the lead plate 5, and are connected in parallel. Unit 6 is used. Furthermore, the lead plate 5 protrudes from the parallel case 3 in the column direction (horizontal direction in FIGS. 2 and 6) of the batteries 1 housed in the parallel case 3, and the protruding portion serves as a connection portion 5A.

  The parallel unit 6 of the assembled battery of FIG. 2 and the battery 1 housed in the parallel unit 6 are shown in FIG. 3 and FIG. In the parallel unit 6 of FIG. 3, the parallel case 3 is formed of plastic in a box shape that can store one battery 1. The parallel case 3 having this shape includes a box-shaped main body 3A that opens a portion into which the battery 1 is inserted, and a lid member 3B that closes the opening of the main body 3A. As shown in FIG. 4, the parallel case 3 having this structure inserts the battery 1 connected with the lead plate 5 into the main body 3 </ b> A, and then closes the opening with the lid member 3 </ b> B. Can be stored. However, the main body does not necessarily need to close the opening with a lid. The lead plate 5 is connected to the electrode of the battery 1 by resistance welding such as spot welding or laser welding.

  The parallel case 3 of FIGS. 2 and 3 is formed in a box shape with the outside as a plane, and this is laminated in the step direction of the battery 1 to form a holder case 2. The parallel case 3 having this structure can be laminated in a state where the adjacent parallel cases 3 are in contact with each other over a wide area. For this reason, the adjacent parallel cases 3 can be connected with excellent vibration resistance. Furthermore, the assembled battery having this structure can be connected to a fixed position by adhering opposing surfaces of the parallel cases 3 stacked in the step direction with a double-sided adhesive tape.

  In the assembled battery of FIG. 6, the battery 1 of the adjacent parallel unit 6 is arranged in a valley formed between the batteries 1 arranged in multiple stages of the parallel unit 6 in order to increase space efficiency. In order to realize this, the pair of side surface plates 3 a disposed on both sides of the parallel case 3 is formed as an uneven surface along the outer surface of the cylindrical battery 1 to be accommodated. The inner shape of the pair of side plates 3a is a shape that allows the cylindrical battery 1 to be inserted separately, that is, a curved surface having a slightly larger curvature radius than the outer diameter of the cylindrical battery 1. The pair of side surface plates 3a are open at both ends. In this parallel case 3, the battery 1 is inserted between the pair of side plates 3 a, and the lead plate 5 is welded and connected to the electrode at the end of the battery by a method such as spot welding or laser welding. In this parallel case 3, after the battery 1 is inserted between the pair of side plates 3a, the lead plate 5 is connected to the electrodes at both ends of the battery. However, the battery 1 can also be inserted between the pair of side plates 3a in a state where the lead plate 5 is connected to one end of the plurality of batteries 1. In this parallel case 3, the battery 1 is inserted between the pair of side plates 3 a, and then the lead plate 5 is connected to the electrode at the other end of the battery 1.

  In the assembled battery of FIG. 6, the concave grooves and the convex stripes can be alternately formed by the unevenness of the side plate 3 a on the opposing surface of the adjacent parallel case 3. The parallel cases 3 stacked in multiple stages guide the protrusions into the recessed grooves of the adjacent parallel cases 3 and arrange the batteries 1 in a multi-stage multi-row in a stacked state. As shown in the partially enlarged view of FIG. 6, the parallel case 3 is firmly connected to a fixed position with an fitting structure. The fitting structure shown in the figure is formed by integrally forming hook-shaped ridges 11 connected to each other on the surface. The hook-like ridges 11 are connected, and the adjacent parallel cases 3 are firmly connected to each other in a fixed position by the fitting structure so as not to come off.

  The parallel case 3 of FIG. 6 is provided with hook-like ridges 11 on the surface of the side plate 3a to connect the adjacent parallel cases 3, but the mechanism for connecting the parallel cases with the fitting structure is the shape of FIG. It can also be used for the parallel case 3. The parallel case 3 in FIG. 7 is connected to a fixed position by providing a connecting portion 12 having a fitting structure on the surfaces abutting each other. In this fitting structure, for example, a concave portion 12A is provided on one side, and a convex portion 12B that is fitted to the concave portion 12A is provided on the other side, and the convex portion 12B is inserted into the concave portion 12A and connected to a fixed position. Moreover, it can also be set as the structure which narrows the opening part of a recessed part by making the recessed part and convex part which are mutually connected and connected into an undercut shape. In this fitting structure, the convex portions can be connected so as not to come out into the concave portion, and the adjacent parallel cases can be connected so as not to be detached by the fitting structure or to be difficult to come off.

  In addition, the assembled battery of FIG. 6 has a specific parallel case 3, for example, a parallel case 3 stacked in an even number or an odd number, so that adjacent parallel cases 3 can be stacked by guiding the ridges into the concave grooves. A position adjustment protrusion 13 is provided. The assembled battery shown in the figure is provided with a position adjustment protrusion 13 in a parallel case 3 stacked in an even number of stages. In the illustrated parallel case 3, the position adjustment protrusion 13 is inserted into the fitting portion 8 </ b> A of the connecting plate 8, and the parallel case 3 at each stage is stacked so as to guide the protrusions into the recess grooves.

  Further, the parallel case 3 of FIG. 8 is provided with spacer ribs 14 disposed between the adjacent batteries 1 so as to protrude from the inner surface. The parallel case 3 includes a rib case 3X in which spacer ribs 14 are integrally formed and a box case 3Y formed in a box shape. The rib case 3X is provided with a plurality of spacer ribs 14 in parallel. A U-shaped groove 15 into which the cylindrical battery 1 can be inserted is provided between the spacer ribs 14. The U-shaped groove 15 is open at both ends. The parallel case 3 can hold the cylindrical battery 1 in the U-shaped groove 15 and hold it in a fixed position, and connect the lead plates 5 to both ends of the battery 1 by a method such as spot welding. Therefore, the battery 1 can be held at a fixed position by using the rib case 3X together with a jig for connecting the lead plate 5. Further, since the adjacent battery 1 is isolated by the spacer rib 14 and accommodated in the parallel unit 6, when any one of the batteries 1 undergoes thermal runaway, the thermal runaway is prevented from being induced in the adjacent battery 1. Safety can be improved. In this parallel case 3, after the battery 1 is inserted into the U-shaped groove 15 of the rib case 3X and the lead plate 5 is connected to the battery 1, the battery 1 and the rib case 3X are put together in the box case 3Y, and the box case 3Y and the rib case 3 Connect 3X. The box case 3Y is provided with a slit 16 for guiding the lead plate 5.

  The batteries 1 housed in the parallel case 3 are connected in parallel by connecting the lead plates 5 to the positive and negative electrodes at both ends by a method such as spot welding. The lead plate 5 shown in FIGS. 2 to 6 and 8 is obtained by cutting a metal plate into a predetermined width. The lead plate 5 is connected to both ends of the battery, and a portion protruding from the parallel case 3 is a connecting portion 5A. The lead plate 5 shown in FIGS. 9 and 10 has a wider battery connecting portion 5B connected to the battery 1 and a smaller connecting portion 5A than the battery connecting portion 5B. The lead plate 5 that widens the width of the battery connecting portion 5B can connect the batteries 1 housed in the parallel case 3 in a firm and tough state. Further, the wide battery connecting portion 5B has a small electric resistance, and the batteries 1 housed in the parallel case can be connected in parallel in a state of electric resistance.

  In particular, in FIG. 9, one lead plate 5 is a groove-shaped lead plate 5X in which a metal plate is bent into a groove shape. The grooved lead plate 5X has a groove whose inner width is substantially equal to the outer diameter of the outer can so that the battery 1 is not inserted into the groove and no gap is formed between the battery 1 and the outer can. It is shaped like a letter. The grooved lead plate 5X protects the outer can of the battery 1 by placing the battery 1 in the groove. In addition, the groove-shaped lead plate 5X connects the groove bottom 5a to the bottom surface of the outer can by a method such as spot welding. Further, the groove-shaped lead plate 5X can electrically connect the battery 1 placed in the parallel case 3 with low resistance by electrically connecting the side plates 4b provided on both sides of the groove bottom 5a to the outer can. The groove-shaped lead plate 5X can more reliably connect the side plate 5b and the battery 1 by connecting the side plate 5b to the outer can by a method such as spot welding. The structure in which the grooved lead plate 5X is brought into contact with the outer can of the battery 1, that is, the structure in which the grooved lead plate 5X and the outer can of the battery 1 are thermally coupled can efficiently cool the battery 1 with the grooved lead plate 5X. Furthermore, there is an effect that the temperature difference between the batteries 1 connected in parallel can be reduced. A battery 1 formed by connecting one electrode with a grooved lead plate 5X and connecting the other electrode with a lead plate 5 including a wide battery connecting portion 5B and a narrow connecting portion 5A is housed in a parallel case 3. Thus, the parallel unit 6 is obtained.

  The parallel unit 6 in FIG. 10 is filled with an insulating resin 17 inside the parallel case 3. The insulating resin 17 is a synthetic resin such as urethane. In the parallel unit 6, the battery 1 to be placed inside the parallel case 3 is potted by the insulating resin 17 and is securely held in place. The parallel case 3 has a frame shape that opens at both ends. The frame-shaped parallel case 3 has upper and lower ends opened in the figure. The battery 1 is put in the parallel case 3, and the lead plate 5 is connected to the opening at the bottom. The lead plate 5 connects the batteries 1 in parallel and closes the opening at the bottom of the parallel case 3. In this state, the parallel case 3 is filled with uncured and pasty insulating resin 17, and the battery 1 is potted inside the parallel case 3. After the insulating resin 17 is cured and the battery 1 is fixed in a fixed position, the lead plate 5 is connected to the other end of the battery 1 by a method such as resistance welding or laser welding to form the parallel unit 6. The parallel unit 6 is also characterized in that the battery 1 housed in the parallel case 3 is potted with the insulating resin 17, so that the temperature of the battery 1 can be made uniform while the battery 1 is firmly fixed in place. However, the parallel case filled with the insulating resin may be a box shape having one end opened.

  The assembled battery of FIG. 6 connects the opposing surfaces of the stacked parallel cases 3 via the substrate holder 7 and the connecting plate 8. This assembled battery includes a substrate holder 7 for housing the circuit board 4 and a connecting plate 8. The substrate holder 7 is made of plastic in a box shape having a peripheral wall around the bottom plate. The circuit board 4 is housed inside the board holder 7 and fixed in place. Preferably, the substrate holder 7 is filled with an insulating resin, and the circuit board 4 is potted inside the substrate holder 7. The structure in which the circuit board 4 is fixed to the board holder 7 in this state can be protected by potting the circuit board 4.

  The parallel unit 6 is connected to the circuit board 4 fixed to the circuit board holder 7 by connecting the connection portion 5 </ b> A of the lead plate 5 to the circuit board holder 7 and the circuit board 4. Furthermore, the assembled battery of the figure has connected the parallel unit 6 and the board | substrate holder 7 in the fixed position by the fitting structure. In order to connect the parallel units 6 with a fitting structure, the substrate holder 7 shown in the figure has a connecting concave portion 7A for fitting the end portion of the parallel case 3 on the bottom surface and a fitting concave portion 7B for fitting the connecting portion 5A of the lead plate 5. It is provided on each side. The parallel unit 6 is mounted at a fixed position of the substrate holder 7 with the end of the parallel case 3 being inserted into the connecting recess 7A and the connecting portion 5A of the lead plate 5 into the fitting recess 7B. Are connected to the circuit board 4 by a method such as soldering. When the connecting portion 5A is coupled to the circuit board 4, the board holder 7 disposed between the circuit board 4 and the parallel unit 6 is disposed between the circuit board 4 and the parallel unit 6 at a fixed position. . In the assembled battery in which the circuit board 4 is potted on the board holder 7, the connecting portion 5A of the lead plate 5 is connected to the circuit board 4, and then the board holder 7 is filled with an insulating resin, and the circuit board 4 is embedded in the insulating resin. .

  Furthermore, the assembled battery of FIG. 6 has connected the parallel unit 6 to the connection plate 8 with the fitting structure. In this assembled battery, a connecting plate 8 is disposed on the side opposite to the board holder connecting side of the parallel case 3. The plurality of parallel cases 3 stacked and connected in multiple stages are disposed between the substrate holder 7 and the connection plate 8 and connected to both the substrate holder 7 and the connection plate 8.

  The connecting plate 8 is provided with a fitting portion 8A into which one end portion of the parallel unit 6 can be fitted. The connecting plate 8 in the figure has a fitting portion 8A as a through hole. However, the insertion portion can be a recess, and the end of the parallel unit can be inserted here and connected to a fixed position. With this structure, adjacent parallel units 6 can be firmly connected to the circuit board 4 and the connection plate 8.

  In the above assembled battery, the connection portion 5A of each parallel unit 6 is directly connected to the circuit board 4. The assembled battery is connected to the parallel units 6 in series or in series and parallel with connection leads (not shown) mounted on the circuit board 4 or wired on the circuit board 4. In the assembled battery of the present invention, it is not always necessary to directly connect the connection portion 5A of each parallel unit 6 to the circuit board 4. In the assembled battery shown in FIG. 11 to FIG. 17, the connecting portion 5A of the parallel unit 6 is connected to the connecting portion 5A of the adjacent parallel unit 6 by a method such as welding. These assembled batteries connect the connection part 5A of the parallel unit 6 to the circuit board 4 via the connection part 5A of the adjacent parallel unit 6. These assembled batteries do not need to connect the parallel units 6 in series with the connection leads provided on the circuit board 4, and connect the connecting portion 5A directly to the lead plate 5 of the adjacent parallel unit 6 to connect the connecting portion 5A. The electrical resistance can be reduced. The assembled battery shown in FIGS. 12 to 17 does not show a circuit board. However, in these assembled batteries, the circuit board is housed in the substrate holder 7, and the connection portion 5A of the parallel unit 6 is connected to the circuit substrate via a connection lead or the like.

  In the assembled battery shown in FIGS. 12 to 17, a plurality of parallel units 6 are stacked in a step direction, and a plurality of parallel cases 3 are stacked together to form a holder case 2. These battery packs are provided with a plurality of parallel cases 3 disposed between the substrate holder 7 and the connecting plate 8 in order to connect and connect the parallel cases 3 stacked in multiple stages at a fixed position. 3 are connected to the substrate holder 7 and the connecting plate 8 by a fitting structure. In order to connect the parallel case 3 to the substrate holder 7 and the connecting plate 8 with a fitting structure, the parallel case 3 shown in the figure is provided with positioning protrusions 18 protruding from both end faces facing the substrate holder 7 and the connecting plate 8. ing. The substrate holder 7 is provided with a connecting concave portion 7A into which the positioning convex portion 18 of the parallel case 3 is fitted. Further, the connecting plate 8 is provided with a fitting portion 8A into which the positioning convex portion 18 of the parallel case 3 is fitted. In a state where the plurality of parallel cases 3 are stacked in the step direction, the positioning projections 18 at both ends are fitted into the coupling recesses 7A of the substrate holder 7 and the fitting portions 8A of the coupling plate 8 and are connected to a fixed position.

  Furthermore, the assembled battery shown in the figure is a connection portion 5A drawn out from a plurality of parallel cases 3 stacked in multiple stages, and alternately connects the connection portions 5A of the parallel units 6 adjacent to each other, thereby providing a plurality of parallel units. 6 batteries 1 are connected in series. The connecting portions 5A connected to each other are connected to a circuit board (not shown) accommodated in the board holder 7. The substrate holder 7 shown in the figure is provided with insertion recesses 7B into which the connection portions 5A of the lead plate 5 are inserted, respectively. The plurality of parallel units 6 are mounted at fixed positions on the substrate holder 7 with the positioning protrusions 18 of the parallel case 3 inserted into the connecting recesses 7A and the connection portions 5A of the lead plates 5 inserted into the insertion recesses 7B. The five connecting portions 5A are connected to the circuit board by a method such as soldering.

  In the assembled battery shown in FIGS. 12 to 14, a plurality of parallel cases 3 are formed in a box shape having a flat outer surface. The parallel case 3 includes a rib case 3X in which spacer ribs 14 disposed between adjacent batteries 1 are integrally formed, and a box case 3Y formed in a box shape. This parallel case 3 is provided with a U-shaped groove 15 into which a cylindrical battery can be inserted between a plurality of spacer ribs 14 provided in parallel to each other. In this parallel case 3, after the battery 1 is inserted into the U-shaped groove 15 and the lead plate 5 is connected to the battery 1, the battery 1 and the rib case 3X are put together in the box case 3Y, and the box case 3Y and the rib case 3X are connected. To do. The rib case 3X is provided with a positioning projection 18 integrally formed at one end. The box case 3Y is formed by integrally molding the positioning convex portion 18 at one end opposite to the positioning convex portion 18 provided in the rib case 3X. However, the positioning protrusions can be provided at both ends of the rib case.

  In the assembled battery of FIGS. 15 to 17, a plurality of parallel cases 3 are formed in a shape having an uneven surface on the outside. In the parallel case 3 shown in the figure, the pair of side plates 3a disposed on both sides is formed as an uneven surface along the outer surface of the cylindrical battery to be housed. The parallel case 3 includes a partition wall 19 disposed between adjacent batteries 1, and both ends of the partition wall 19 are connected to a pair of side plates 3a. That is, the parallel case 3 shown in the figure is integrally formed into a shape having a cylindrical portion that houses the battery 1 therein, as a shape in which a pair of side plates 3a are connected by a plurality of partition walls 19. The cylindrical portion has a cylindrical shape whose inner diameter is substantially equal to the outer diameter of the cylindrical battery so that the cylindrical battery can be inserted. In this assembled battery, a parallel case 3 having an uneven surface on the outside is laminated to form a holder case 2. However, as in the assembled battery shown in FIG. 6, a protruding line is formed in the concave groove of the side plate 3 a of the adjacent parallel case 3. They are not arranged in the state of guiding them, that is, in the stacked state. In this assembled battery, the protrusions of the side plates 3a of the parallel cases 3 adjacent to each other are stacked in an array in which the ridges face each other. The structure in which the parallel units 6 are stacked in multiple stages in this structure is such that when one of the parallel unit batteries is thermally runaway, the thermal runaway is induced in the battery 1 of the parallel unit 6 disposed adjacent thereto. It has the feature that it can effectively prevent and improve safety. Further, in this assembled battery, a gap is formed by the recessed grooves of the side plates 3a facing each other in the adjacent parallel case 3, so that the battery can be efficiently radiated by blowing air into the gap.

It is sectional drawing of the assembled battery which the present applicant developed previously. It is a perspective view of the assembled battery concerning one Example of this invention. It is a disassembled perspective view of the parallel unit of the assembled battery shown in FIG. It is a disassembled perspective view of the parallel unit shown in FIG. It is sectional drawing of the assembled battery concerning the other Example of this invention. It is a disassembled perspective view of the assembled battery concerning the other Example of this invention. It is an enlarged side view which shows an example of the connection structure of a parallel case. It is a disassembled perspective view which shows another example of a parallel unit. It is a disassembled perspective view which shows another example of a parallel unit. It is a disassembled perspective view which shows another example of a parallel unit. It is a perspective view of the assembled battery concerning the other Example of this invention. It is a perspective view of the assembled battery concerning the other Example of this invention. It is a disassembled perspective view of the assembled battery shown in FIG. It is sectional drawing of the assembled battery shown in FIG. It is a perspective view of the assembled battery concerning the other Example of this invention. It is a disassembled perspective view of the assembled battery shown in FIG. It is sectional drawing of the assembled battery shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Battery 2 ... Holder case 3 ... Parallel case 3A ... Main-body part
3B ... Cover material
3a ... Side plate
3X ... Rib case
3Y ... Box case 4 ... Circuit board 5 ... Lead plate 5A ... Connection part
5B ... Battery connection part
5X ... Channel type lead plate
5a ... groove bottom
5b ... Side plate 6 ... Parallel unit 7 ... Substrate holder 7A ... Connection recess
7B: Insertion recessed part 8 ... Connection plate 8A ... Insertion part 9 ... Outer case 10 ... Core pack 11 ... Convex strip 12 ... Connection part 12A ... Concave part
12B ... Convex part 13 ... Position adjustment protrusion part 14 ... Spacer rib 15 ... U-shaped groove 16 ... Slit 17 ... Insulating resin 18 ... Positioning convex part 19 ... Partition wall 91 ... Battery 92 ... Outer case 93 ... Battery block 94 ... Circuit board 95 ... Lead plate 96 ... Parallel unit 97 ... Spacer

Claims (8)

A plurality of batteries (1) are electrically connected to the holder case (2), which is stored in multiple rows in multiple rows, and the battery (1), which is stored in the holder case (2), in a parallel posture. An assembled battery comprising a circuit board (4),
The holder case (2) is divided into a plurality of parallel cases (3) formed by connecting a plurality of built-in batteries (1) in parallel, and the divided parallel cases (3) are arranged in the step direction. Stacked and connected to each other,
Furthermore, in each parallel case (3), a plurality of batteries (1) are arranged in a single row with the positive and negative electrodes oriented in the same direction to form parallel units (6). The lead plate (5) is connected to the electrode of each battery (1) stored in the parallel case (3), and a plurality of batteries stored in the parallel case (3) with the lead plate (5) ( 1) are connected in parallel to each other, and the parallel unit (6) is further provided with a connecting portion (5A) by protruding the lead plate (5) from the parallel case (3),
Adjacent parallel units (6) are stacked with the connecting portion (5A) of the lead plate (5) disposed on the facing surface of the circuit board (4), and each stacked parallel unit (6) is The connection part (5A) of the lead plate (5) is connected to the circuit board (4) directly or via the connection part (5A) of the adjacent parallel unit (6), and the lead board (5) and the circuit board are connected. (4) Ri greens and integrally connected to parallel unit (6) via,
An assembled battery comprising a substrate holder (7) for storing a circuit board (4), and connecting the substrate holder (7) and the parallel unit (6) in place with a fitting structure . A connection plate (8) is arranged on the opposite side of the parallel case (3) to the substrate holder connection side, and multiple parallel cases (3) stacked and connected in multiple stages are connected to the substrate holder (7). The assembled battery according to claim 1 , wherein the battery pack is disposed between the plates (8) to connect the parallel case (3) to both the substrate holder (7) and the connecting plate (8). A plurality of batteries (1) are electrically connected to the holder case (2), which is stored in multiple rows in multiple rows, and the battery (1), which is stored in the holder case (2), in a parallel posture. An assembled battery comprising a circuit board (4),
The holder case (2) is divided into a plurality of parallel cases (3) formed by connecting a plurality of built-in batteries (1) in parallel, and the divided parallel cases (3) are arranged in the step direction. Stacked and connected to each other,
Furthermore, in each parallel case (3), a plurality of batteries (1) are arranged in a single row with the positive and negative electrodes oriented in the same direction to form parallel units (6). The lead plate (5) is connected to the electrode of each battery (1) stored in the parallel case (3), and a plurality of batteries stored in the parallel case (3) with the lead plate (5) ( 1) are connected in parallel to each other, and the parallel unit (6) is further provided with a connecting portion (5A) by protruding the lead plate (5) from the parallel case (3),
Adjacent parallel units (6) are stacked with the connecting portion (5A) of the lead plate (5) disposed on the facing surface of the circuit board (4), and each stacked parallel unit (6) is The connection part (5A) of the lead plate (5) is connected to the circuit board (4) directly or via the connection part (5A) of the adjacent parallel unit (6), and the lead board (5) and the circuit board are connected. (4) Ri greens and integrally connected to parallel unit (6) via,
The battery (1) stored in the parallel case (3) is a cylindrical battery, and the parallel case (3) has a side plate (3a) formed on the uneven surface along the outer surface of the cylindrical battery to be stored. An assembled battery in which the arranged parallel cases (3) are laminated so that the convex portions are positioned in the concave portions of the side surface plate (3a). A plurality of batteries (1) are electrically connected to the holder case (2), which is stored in multiple rows in multiple rows, and the battery (1), which is stored in the holder case (2), in a parallel posture. An assembled battery comprising a circuit board (4),
The holder case (2) is divided into a plurality of parallel cases (3) formed by connecting a plurality of built-in batteries (1) in parallel, and the divided parallel cases (3) are arranged in the step direction. Stacked and connected to each other,
Furthermore, in each parallel case (3), a plurality of batteries (1) are arranged in a single row with the positive and negative electrodes oriented in the same direction to form parallel units (6). The lead plate (5) is connected to the electrode of each battery (1) stored in the parallel case (3), and a plurality of batteries stored in the parallel case (3) with the lead plate (5) ( 1) are connected in parallel to each other, and the parallel unit (6) is further provided with a connecting portion (5A) by protruding the lead plate (5) from the parallel case (3),
Adjacent parallel units (6) are stacked with the connecting portion (5A) of the lead plate (5) disposed on the facing surface of the circuit board (4), and each stacked parallel unit (6) is The connection part (5A) of the lead plate (5) is connected to the circuit board (4) directly or via the connection part (5A) of the adjacent parallel unit (6), and the lead board (5) and the circuit board are connected. (4) Ri greens and integrally connected to parallel unit (6) via,
The lead plate (5) bends the metal plate into a groove shape, puts the outer can of the battery (1) into the groove, and connects the electrode connected to the outer can to the lead plate (5) Assembled battery. The assembled battery according to any one of claims 1 to 4 , wherein adjacent parallel cases (3) are connected to each other in a fixed position in a fitting structure and stacked. The assembled battery according to any one of claims 1 to 4 , wherein adjacent parallel cases (3) are bonded and laminated with a double-sided adhesive tape. The assembled battery according to any one of claims 1 to 6 , wherein the parallel case (3) is provided with spacer ribs (14) disposed between the batteries (1) to be housed so as to protrude from the inner surface. The assembled battery according to any one of claims 1 to 7 , wherein the parallel case (3) is filled with an insulating resin (17), and the battery (1) is potted inside the parallel case (3).

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