JP2008041369A - Power-supply unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce a short current even when either of batteries causes a failure such as an internal short while reducing internal resistance by connecting the batteries in parallel with each other. <P>SOLUTION: This power-supply unit is provided with a battery pack 2 where parallel blocks 3 formed by connecting a plurality of batteries 1 in parallel with one another are connected in series to one another. In this battery pack 2, each parallel block 3 is divided into small blocks 3A formed by connecting the plurality of batteries 1 in parallel with one another, each series block 4 is formed by connecting the divided small blocks 3A in series to one another, and the output sides of the series blocks 4 are connected in parallel to each other while intermediate connection points of the small blocks 3A are brought into a non-connection state. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention mainly relates to a power supply apparatus that is optimal for driving a motor for driving a vehicle such as an automobile, a motorcycle, or a bicycle. In particular, a plurality of batteries are connected in parallel to increase output current, and the batteries are connected in series. The present invention relates to a power supply device that is connected to increase an output voltage.

In order to increase the power supplied to the motor for traveling, a power supply device in which a large number of batteries are connected in series has been developed. (See Patent Document 1)
JP 2000-223096 A

  This power supply device can increase the output voltage in proportion to the number of batteries connected in series. A power supply device with a high output voltage can increase the power supplied to the motor, but safety measures such as electric shock are complicated when mounted on a vehicle. Although the output voltage can be lowered to increase safety, the power supplied to the motor, that is, the horsepower of the motor is reduced. In recent years, a system for boosting the output voltage of a power supply device with a DC / AC inverter and supplying the boosted voltage to a motor has been put into practical use. This system can increase the output by increasing the supply voltage of the motor while decreasing the output voltage of the power supply device. However, since the battery current increases in proportion to the voltage boosted by the DC / AC inverter, it is important to reduce the internal resistance of the power source. This is because the voltage drop due to the internal resistance increases in proportion to the current, and the output voltage of the power supply device decreases due to the internal resistance, making it impossible to supply sufficient power to the motor. The internal resistance of the power supply device can be reduced by connecting batteries in parallel. For example, a power supply apparatus that connects two sets of batteries in parallel can be solved by connecting a plurality of batteries in parallel to form a parallel block, and connecting the parallel blocks in series. A power supply device in which a plurality of batteries are connected in parallel and in series can realize the characteristics that the output voltage can be lowered to improve safety and the internal resistance can be further reduced. However, since this power supply device incorporates a large number of batteries, the probability that the batteries will fail increases. For example, when one of the batteries has a failure such as an internal short circuit, an adverse effect is caused in which a very short circuit current flows from another battery connected in parallel with the battery.

  The present invention has been developed for the purpose of solving this drawback. An important object of the present invention is to provide a power supply device capable of reducing a short-circuit current even when a battery is damaged such as an internal short circuit while the batteries are connected in parallel to reduce the internal resistance.

The power supply device of the present invention has the following configuration in order to achieve the above-described object.
The power supply device includes assembled batteries 2 and 32 in which parallel blocks 3 and 33 formed by connecting a plurality of batteries 1 in parallel are connected in series. The assembled batteries 2 and 32 are obtained by dividing the parallel blocks 3 and 33 into small blocks 3A and 33A formed by connecting a plurality of batteries 1 in parallel, and connecting the divided small blocks 3A and 33A in series. 4 and 34, and the series blocks 4 and 34 are connected in parallel to each other on the output side while the intermediate connection point of the small blocks 3A and 33A is not connected.

  The power supply device of the present invention can divide the parallel block 3 into two small blocks 3A. Further, in the power supply device of the present invention, the small blocks 3A and 33A can connect 2 to 6 batteries 1 in parallel. Furthermore, in the power supply device of the present invention, the serial blocks 4 and 34 can connect 5 to 50 small blocks 3A and 33A in series. Furthermore, in the power supply device of the present invention, the battery 1 can be a lithium ion secondary battery.

  Furthermore, the power supply device of the present invention includes a voltage detection circuit that detects the battery voltage of the small blocks 3A and 33A constituting each of the series blocks 4 and 34, and the small blocks 3A and 33A that are detected by the voltage detection circuit. And a control circuit for controlling the charge / discharge current with voltage.

  Further, the power supply device of the present invention is provided with wiring spaces 31 and 51 between the adjacent series blocks 4 and 34, and the output leads 9 of the series blocks 4 and 34 are located at both ends of the wiring spaces 31 and 51. 39, and the output leads 9, 39 of the plurality of serial blocks 4, 34 can be connected to the output terminals 13, 43, and the output terminals 9, 39 can be arranged in the wiring spaces 31, 51.

The power supply device according to the present invention has a feature that the safety can be improved by reducing the short-circuit current even if any battery has a failure such as an internal short circuit while the batteries are connected in parallel to reduce the internal resistance. In the power supply device of the present invention, a parallel block in which a plurality of batteries are connected in parallel is divided into small blocks formed by connecting a plurality of batteries in parallel, and the divided small blocks are connected in series. This is because the block is a block, and the intermediate connection point of the small blocks is not connected, and the output sides are connected in parallel.
The power supply device having this structure can improve safety by reducing the short-circuit current when any battery shorts internally. This is because the parallel block is divided into small blocks, so that the number of batteries connected in parallel with the internally shorted battery is reduced.

  Furthermore, the power supply device with this structure divides a parallel block in which a large number of batteries are connected in parallel into a plurality of small blocks, and the small blocks are connected in series to form a serial block. The output current can be taken out well. Regardless of this structure, for example, when a large number of batteries are connected in parallel with a lead plate and current is output from a specific part of the lead plate, the output current from the battery connected to the lead plate away from the current extraction point This causes a negative effect. This is because the electrical resistance of the lead plate of each battery connected to the lead plate increases as the distance from the current extraction point increases, and the electrical resistance of the lead plate becomes unbalanced by the battery. For this structure, the power supply device of the present invention divides the parallel block into a plurality of small blocks, so the number of batteries connected in parallel with the lead plate is small, and the electrical resistance of the lead plate of each battery is small, In addition, the electric resistance unbalance is reduced, and current can be made to flow uniformly from all the batteries.

  Furthermore, the power supply device of the present invention has a feature that the overall rigidity can be improved. That is, the parallel block is divided into small blocks and these are connected in series to form a serial block, i.e., all the batteries are divided into a plurality of serial blocks, so the weight of the serial block is the number of the total weight. This is because a plurality of lightened series blocks can be connected and assembled as a power supply device.

  Moreover, since the power supply apparatus of this invention isolate | separates the whole battery into a some series block, the heat_generation | fever at the time of heat radiation is disperse | distributed to plurality, and the characteristic which can heat-dissipate a battery more effectively is also implement | achieved. This is because the heat radiation area can be increased by dividing into a plurality of parts.

  Furthermore, since the power supply device of the present invention divides the battery into a plurality of series blocks, it also realizes a feature that enables efficient maintenance. This is because the assembly to be exchanged for maintenance can be divided into a single serial block.

  Embodiments of the present invention will be described below with reference to the drawings. However, the embodiments described below exemplify a power supply device for embodying the technical idea of the present invention, and the present invention does not specify the power supply device 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 power supply apparatus shown in the block diagram of FIG. 1 and the perspective views of FIGS. 2 to 6 includes an assembled battery 2 in which parallel blocks 3 connecting a plurality of batteries 1 in parallel are connected in series. As shown in the circuit diagram of FIG. 1, the assembled battery 2 of this power supply device divides the parallel block 3 into small blocks 3 </ b> A that connect a plurality of batteries 1 in parallel. The divided small blocks 3A are connected in series to form a serial block 4. Furthermore, the serial block 4 connects the output sides of both ends in parallel with each other in a disconnected state in which the intermediate connection point of the small block 3A is not connected.

  In the power supply apparatus shown in FIG. 2, four batteries 1 are connected in parallel to form a small block 3A, and further, ten small blocks 3A are connected in series to form a serial block 4. Further, since the parallel block 3 is divided into two sets of small blocks 3A, the battery pack 2 has two sets of series blocks 4 connected in parallel. However, the present invention does not specify the number of batteries connected in parallel by the parallel block as four. The parallel block can connect two to six batteries in parallel. Further, the number of serial blocks connecting the small blocks in series is not limited to 10, and the serial block can connect 5 to 50 small blocks in series.

  2 to 6, FIG. 2 shows two sets of series blocks 4 connected in parallel to each other, FIG. 3 shows a state in which the two sets of series blocks 4 are accommodated in the rear case 15, and FIG. 4 shows a state in which the rear case 15 and the front case 16 are accommodated, and FIGS. 5 and 6 show a state in which the series block 4 is accommodated in the rear case 15, the front case 16, and the top case 17. The power supply device shown in these drawings includes two sets of series blocks 4 whose output sides are connected in parallel to each other, and an inner case 21 that houses the two sets of series blocks 4.

  As shown in FIGS. 2 to 4, the two sets of series blocks 4 are connected to the plurality of batteries 1 connected in parallel and in series via the lead plate 5 and to the plurality of batteries 1 via the lead plate 5. A circuit board 6 and a substrate holder 7 for housing the circuit board 6. Furthermore, each battery 1 is disposed at a fixed position by an insulating holder 8 that is disposed at a fixed position while insulating adjacent batteries 1. As shown in FIGS. 2 to 4, the two sets of series blocks 4 are arranged with a wiring space 31 provided therebetween. Each series block 4 has output leads 9 located at both ends (upper and lower in the figure) of the wiring space 31, and each output lead 9 is connected by a parallel connection lead 10, and the output side is connected in parallel. is doing.

  The series block 4 in FIGS. 2 and 3 is provided with a plus-side output lead 9 and a minus-side output lead 9 at the upper and lower ends in the drawing. The positive and negative output leads 9 are lead plates 5 connected to the end faces of the four batteries 1. The positive output lead 9 provided in each series block 4 is connected by a parallel connection lead 10 and connected to the positive output terminal 13. The negative output lead 9 is also connected to each other via the parallel connection lead 10 and connected to the negative output terminal 13. The parallel connection leads 10 that connect the output leads 9 in parallel are connected to the output terminals 13 between the series blocks 4, that is, at both ends of the wiring space 31, and an output formed by connecting the parallel connection leads 10. The terminal 13 is disposed in the wiring space 31. In this way, the structure in which the parallel connection leads 10 that connect the output leads 9 of each series block 4 in parallel are connected between the adjacent series blocks 4 and connected to the output terminal 13 has the parallel connection leads connected in series blocks. Compared to the structure that is connected on the outside, the difference in length of each parallel connection lead can be reduced. That is, by connecting parallel connection leads 10 between adjacent series blocks 4, the length of each parallel connection lead 10 is made shorter than the width of the series block 4, and the length of each parallel connection lead 10 is reduced. Because it can balance. Since the power supply device having this structure can reduce the difference in length of each parallel connection lead 10 and balance these electric resistances, the output current can be taken out from each series block 4 in a balanced manner. In addition, even when the battery 1 is charged, each series block 4 can be energized with good balance. In this way, the power supply apparatus that can charge and discharge each series block 4 in a well-balanced manner effectively prevents the degree of deterioration of the batteries between the series blocks from becoming uneven, and the entire assembled battery is There is a feature that can extend the service life. Each of the plus side and minus side output terminals 13 is connected to the output connector 12 via the lead wires 14 by connecting two lead wires 14 to each other. The two lead wires 14 connect the output lead 9 to the output connector 12 with a small electric resistance.

  The battery 1 is a rechargeable secondary battery and is a lithium ion secondary battery. However, the battery may be a nickel metal hydride battery or a nickel cadmium battery. Furthermore, in the illustrated battery pack, the battery 1 is a cylindrical battery, but may be a square battery. In the illustrated series block 4, four batteries 1 are arranged in a straight line and connected in parallel to form a small block 3 </ b> A, and the small blocks 3 </ b> A are arranged in 10 stages and connected in series by a lead plate 5. The battery 1 is held at a fixed position by an insulating holder 8 so that the end faces are located on the same plane. The insulating holder 8 has a holding cylinder into which each battery 1 is inserted independently, and the battery 1 is inserted therein and held in place. The insulating holder 8 is manufactured by molding an insulating plastic.

  The battery 1 has a lead plate 5 welded to its end face and is connected in series and in parallel. In the illustrated serial block 4, each lead plate 5 is connected to a circuit board 6. The lead plate 5 is provided with a connecting portion 5A connected to the circuit board 6 so as to protrude from the end portion. The lead plate 5 is connected to the connecting portion 5A by soldering lead pins 11, lead wires, and the like, and is connected to the circuit board 6 through these.

  As shown in FIG. 4, the two sets of serial blocks 4 each include an independent circuit board 6. Each circuit board 6 is mounted with a protection circuit that controls charging / discharging of the battery 1. The protection circuit detects the battery voltage of each small block 3A, and controls the charge / discharge current. Although not shown, this protection circuit detects the battery voltage of the small block 3A constituting each series block 4 and the charging / discharging current with the voltage of the small block 3A detected by the voltage detection circuit. And a control circuit for controlling. When the battery voltage of any of the small blocks 3A becomes lower than the minimum voltage, the protection circuit switches off a switching element (not shown) that cuts off the discharge current to cut off the discharge current. Further, when the battery voltage of any of the small blocks 3A becomes higher than the maximum voltage, the switching element for stopping charging is switched off to stop charging. The switching element that cuts off the discharging current and the switching element that cuts off the charging current are connected in series to each series block 4 or connected to the output side where the series blocks 4 are connected in parallel. Moreover, the switching element connected to the output side in which the series blocks 4 are connected in parallel can also be provided in a vehicle or the like equipped with a power supply device. The power supply device which detects the battery voltage of each small block 3A independently and controls the charging / discharging with the detected voltage on the circuit board 6 is safe while protecting all the batteries 1 Can be charged and discharged.

  Furthermore, the protection circuit also includes an arithmetic circuit that calculates the remaining capacity of the battery to be charged / discharged. Since the power supply apparatus shown in the figure detects the battery voltage of each small block, the arithmetic circuit calculates the remaining capacity of each small block. The arithmetic circuit calculates the charging capacity by integrating the battery voltage and charging current of the small block, calculates the discharging capacity by integrating the battery voltage and discharging current of the small block, and calculates the calculated charging capacity and discharging capacity. To calculate the remaining capacity of the small block. Further, the arithmetic circuit adds the remaining capacity of each small block to calculate the remaining capacity of the series block, and calculates the remaining capacity of the entire assembled battery from the remaining capacity of each series block. The remaining capacity of the assembled battery calculated by the arithmetic circuit is displayed on the remaining capacity display unit 18. The power supply device shown in the figure includes a display board 19 at the upper part of a case, and a plurality of LEDs 20 are arranged on the display board 19 and a capacity display switch 30 for operating the display state of the remaining capacity is arranged to provide a remaining capacity display section. 18 and so on. The circuit board 6 is connected to the display board 19 via lead wires (not shown). When the capacity display switch 30 is operated, the remaining capacity display unit 18 displays the remaining capacity of the assembled battery by changing the lighting state of these LEDs 20, for example, the number of lighting and the lighting color, or changing the blinking state. . The lighting state and blinking state of the plurality of LEDs 20 are controlled by the control circuit according to the remaining capacity of the assembled battery calculated by the arithmetic circuit.

  The substrate holder 7 accommodates the circuit board 6 and arranges it at a predetermined position. The substrate holder 7 shown in FIG. 4 is provided with a peripheral wall around a bottom plate (not shown) and has a box shape with an upper opening. The circuit board 6 is accommodated inside the peripheral wall and arranged at a predetermined position. Yes. The substrate holder 7 is connected and fixed to a fixed position of the insulating holder 8.

  The substrate holder 7 protrudes from the bottom plate and is provided with a support portion (not shown). The circuit board 6 is fixed to the support portion with a set screw, and the circuit substrate 6 is fixed at a position away from the bottom plate. In this structure, an electronic component (not shown) that realizes a protection circuit or the like is disposed on the surface of the circuit board 6 facing the bottom plate. Thus, the structure in which the electronic component is arranged on the opposing surface of the bottom plate of the substrate holder 7 can protect the electronic component with the circuit board 6.

  Furthermore, the substrate holder 7 can pot the insulating resin to embed the circuit board 6 and protect the circuit board 6 with the potting resin, and the electronic component mounted on the circuit board 6 can be embedded in the potting resin. Can protect electronic components.

  The circuit board 6 is connected to the output connector 12 via a communication lead wire (not shown). The circuit board 6 includes a detection circuit that detects information of the battery 1 and a communication circuit that communicates signals of the detection circuit, and the communication circuit is connected to the output connector 12 with a lead wire. This power supply device transmits information of the battery 1 to a main body device such as a vehicle on which the power supply device is mounted. The main device controls the current for charging / discharging the battery 1 with the battery information transmitted from the power supply device.

  As shown in FIGS. 3 to 8, the above power supply apparatus stores the assembled battery 2 composed of two sets of series blocks 4 in an inner case 21 composed of a rear case 15, a front case 16, and a top case 17. The inner case 21 is housed in the outer case 22. The inner case 21 has a storage portion for storing two sets of series blocks 4 separately so that a wiring space 31 is formed between them.

  The rear case 15 shown in FIG. 7 includes two sets of box-shaped storage portions 15A, and the series block 4 is stored in each storage portion 15A. Further, the rear case 15 shown in the figure includes a central connecting portion 15b between the storage portions 15A in order to provide a wiring space 31 between the adjacent serial blocks 4 arranged. The front case 16 is connected to the rear case 15 in a state where the series block 4 is stored in each storage portion 15A. The rear case 15 and the front case 16 are connected to each other by connecting screws 15 a and 16 a provided on the outer periphery of the opposed openings with a set screw 23 and also with a set screw 24 at the center. The rear case 15 shown in the figure is connected to a central connecting portion (not shown) provided in the central portion of the front case 16 by screwing a set screw 24 into the central connecting portion 15b. Further, the front case 16 is provided with bosses 25 for connecting the top case 17 on the inner surface of the peripheral wall and the central connecting portion. The boss 25 provided in the central connection portion is disposed in the wiring space 31. A set screw 26 passing through the top case 17 is screwed into these bosses 25, and the top case 17 is connected to the front case 16.

  As described above, the structure in which the assembled battery 2 is divided into two sets of series blocks 4 and stored in the inner case 21 stores the divided series blocks 4 that are lighter in the respective storage portions. As a tough structure, the overall rigidity can be increased. Further, since the assembled battery 2 is divided into a plurality of series blocks 4 and accommodated in the inner case 21, there is a feature that each battery can be dissipated more effectively by dispersing the heat generated by many batteries. Particularly, since the wiring space 31 is provided between the adjacent series blocks 4, there is a feature that heat can be efficiently radiated from this space. As described above, the structure that dissipates heat from the wiring space 31 has an advantage that heat can be effectively dissipated between the series blocks that are the central portion of the assembled battery 2 where heat is particularly likely to be trapped. Therefore, this power supply apparatus efficiently radiates heat not only from both side portions of the assembled battery 2 but also from the central portion provided with the wiring space 31 with respect to a large number of batteries 1 constituting the assembled battery 2. There is also a feature that the temperature difference between the central part side and the both end parts side of each battery 1 is reduced, and the partial temperature spots in each battery can be reduced to extend the life.

  The outer case 22 houses the inner case 21 containing the assembled battery 2 by connecting the plastic first case 22A and the second case 22B. The first case 22A and the second case 22B are provided by integrally molding the peripheral wall 27. Further, the exterior case 22 shown in the figure has a boss 28 protruding from the inside. The bosses 28 are provided at a plurality of locations on the inner surface of the peripheral wall 27 and at the central portion. Set screws 29 are inserted into these bosses 28, and the first case 22A and the second case 22B are connected by the set screws 29. The first case 22A and the second case 22B are closed by bringing the opening edges of the peripheral walls 27 into contact with each other without a gap.

  The outer case 22 of FIG. 7 has a structure in which a central boss 28 </ b> A provided at the central portion is passed through and connected to the inner case 21. In the rear case 15, a through hole 15c is opened in the central connecting portion 15b, and a central boss 28A is inserted into the through hole 15c. The central bosses 28A penetrating the central connecting portion are inserted into the wiring space 31 provided between the series units 4 and are connected to each other. As described above, the structure in which the wiring space 31 is provided between the series units 4 has an advantage that the central boss 28A can be ideally disposed in the central portion of the exterior case by using the wiring space 31. The first case 22A and the second case 22B are connected in a state where the central bosses 28A are connected to each other and the inner case 21 is held in a fixed position. The outer case 22 has a feature that the rigidity of the entire outer case can be improved because the inner case 21 that houses the assembled battery 2 is connected to each other via a boss 28 that passes through the middle of the series block 4.

  Further, the outer case 22 is provided with an opening window 22a on the bottom surface for exposing the output connector 12 for outputting the power of the battery 1 to the outside. In this power supply device, an opening window 22a is provided at a connecting portion between the first case 22A and the second case 22B, and the output connector 12 is sandwiched between the opening windows 22a of the first case 22A and the second case 22B. Then, the output connector 12 is exposed from the opening window 22 a of the outer case 22. In this power supply apparatus, the output connector 12 is connected to a power supply unit of an electric device (not shown), and is connected to a fixed position. The output connector 12 exposes a power supply terminal (not shown) of the power supply device. The power supply terminal is connected to the output terminal 13 via the lead wire 14. Further, in this power supply apparatus, the output connector 12 is also connected to a charging connection portion of a charger (not shown). The charger connects the output connector 12 to the charging connection portion, connects the power supply device at a fixed position, and charges.

  Further, the first case 22A is provided with an operation window 22b and a display window 22c on the surface for allowing the capacity display switch 30 and the LED 20 of the power supply device to be exposed to the outside. The operation window 22b exposes the capacity display switch 30 provided on the display substrate 19 to the outside. The display window 22c displays the light of the LED 20 to the outside.

  In the above power supply apparatus, the parallel block 3 is divided into two sets, and the two series blocks 4 are connected in parallel on the output side. The power supply apparatus of the present invention is as shown in FIGS. In addition, the parallel block 33 can be divided into three small blocks 33A, and the three series blocks 34 can be connected in parallel on the output side. Although not shown, the parallel block is divided into four or more sets and divided. Further, four or more sets of series blocks can be connected in parallel.

  As shown in FIG. 9 to FIG. 11, the power supply device in which three sets of series blocks 34 are connected in parallel to form the assembled battery 32 is adjacent to each other, similar to the power supply device in which two sets of series blocks are connected in parallel. Three sets of series blocks 34 are arranged in a state where a wiring gap 51 is formed between the series blocks 34. Further, in this power supply apparatus, the plus side output lead 39 and the minus side output lead 39 provided in each series block 34 are connected by the parallel connection lead 40, and each series block 34 is connected in parallel to each other. Connected. The parallel connection leads 40 that connect the output leads 39 in parallel are connected to the output terminals 43 between the series blocks 34, that is, at both ends of the wiring space 51, and an output formed by connecting the parallel connection leads 40. Terminals 43 are arranged in the wiring space 51. Further, one or a plurality of lead wires 44 are connected to the plus and minus output terminals 43, and are connected to the output connector 42 via the lead wires 44. 9 to 11, reference numeral 36 denotes a circuit board, 45 denotes a rear case, 46 denotes a front case, and 48 denotes a remaining capacity display portion.

2 to 8 is assembled in the following steps.
(1) The battery 1 is put in the insulating holder 8 and held at a fixed position, and the lead plates 5 are connected to both ends of the battery 1 by a method such as spot welding or laser welding. The series block 4 in the figure connects the lead plate 5 to the end faces of the four batteries 1 and the end faces of the eight batteries 1. The lead plate 5 connected to the eight batteries 1 connects the small blocks 3A connecting the four batteries 1 in parallel. The lead plate 5 connected to the four batteries 1 becomes the output lead 9 of the series block 4. In this step, a series block 4 is completed, which is formed by connecting 10 batteries 1 in series with 10 batteries 4 in parallel, that is, four batteries 1 in parallel.
(2) As shown in FIG. 2, the output leads 9 of each series block 4 are connected by parallel connection leads 10 to connect two sets of series blocks 4.
(3) As shown in FIG. 3, the serial blocks 4 connected to each other are stored in the rear case 15.
(4) As shown in FIG. 4, the front case 16 is connected to the rear case 15, the board holder 7 that fixes the circuit board 6 is connected to a fixed position, and the lead plate 5 is connected via the lead pins 11. The part 5A is connected to the circuit board 6. Further, the circuit board 6 and the parallel connection lead 10 are connected to the output connector 12 via the lead wire 14.
(5) The top case 17 is fixed and the opening of the front case 16 is closed.

It is a block diagram of the assembled battery of the power supply device concerning one Example of this invention. It is a perspective view which shows the assembled battery of the power supply device concerning one Example of this invention. FIG. 3 is a perspective view showing a state in which the assembled battery shown in FIG. 2 is housed in a rear case. FIG. 3 is a perspective view showing a state in which the assembled battery shown in FIG. 2 is housed in a rear case and a front case. FIG. 3 is a perspective view showing a state in which the assembled battery shown in FIG. 2 is housed in a rear case, a front case, and a top case. FIG. 6 is a rear perspective view of the power supply device shown in FIG. 5. It is a disassembled perspective view of the power supply device concerning one Example of this invention. It is the disassembled perspective view which looked at the power supply device shown in FIG. 7 from the bottom face. It is a block diagram of the assembled battery of the power supply device concerning the other Example of this invention. It is a perspective view of the power supply device concerning the other Example of this invention. It is a perspective view which shows the assembled battery of the power supply device shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Battery 2 ... Assembly battery 3 ... Parallel block 3A ... Small block 4 ... Series block 5 ... Lead board 5A ... Connection part 6 ... Circuit board 7 ... Board holder 8 ... Insulation holder 9 ... Output lead 10 ... Parallel connection lead 11 ... Lead pin 12 ... Output connector 13 ... Output terminal 14 ... Lead wire 15 ... Rear case 15A ... Storage section
15a ... Connecting collar
15b ... Central connecting part
15c ... Through-hole 16 ... Front case 16a ... Connecting flange 17 ... Top case 18 ... Remaining capacity display unit 19 ... Display substrate 20 ... LED
21 ... Inner case 22 ... Exterior case 22A ... First case
22B ... Second case
22a ... Open window
22b ... Operation window
22c ... Display window 23 ... Set screw 24 ... Set screw 25 ... Boss 26 ... Set screw 27 ... Peripheral wall 28 ... Boss 28A ... Central boss 29 ... Set screw 30 ... Capacity display switch 31 ... Wiring space 32 ... Battery pack 33 ... Parallel block 33A ... small block 34 ... series block 36 ... circuit board 39 ... output lead 40 ... parallel connection lead 42 ... output connector 43 ... output terminal 44 ... lead wire 45 ... rear case 46 ... front case 48 ... remaining capacity display portion 51 ... wiring space

Claims (7)

A parallel block (3) formed by connecting a plurality of batteries (1) in parallel, a battery pack (2) connected in series with (33), and a power supply device comprising (32),
The assembled batteries (2) and (32) are divided by dividing the parallel blocks (3) and (33) into small blocks (3A) and (33A) formed by connecting a plurality of batteries (1) in parallel. Small blocks (3A) and (33A) are connected in series to form serial blocks (4) and (34), and these serial blocks (4) and (34) are connected intermediately between the small blocks (3A) and (33A). A power supply device comprising outputs connected in parallel with each other in a non-connected state.   The power supply device according to claim 1, wherein the parallel block (3) is divided into two small blocks (3A).   The power supply device according to claim 1, wherein the small blocks (3A) and (33A) connect two to six batteries (1) in parallel.   The power supply apparatus according to claim 1, wherein the series blocks (4) and (34) are formed by connecting 5 to 50 small blocks (3A) and (33A) in series.   The power supply device according to claim 1, wherein the battery (1) is a lithium ion secondary battery.   A voltage detection circuit that detects the battery voltage of the small blocks (3A) and (33A) constituting each series block (4) and (34), and a small block (3A) that this voltage detection circuit detects ( The power supply device according to claim 1, further comprising a control circuit that controls a charge / discharge current with a voltage of 33A). Wiring spaces (31), (51) are provided between the adjacent series blocks (4), (34), and the serial blocks (4), located at both ends of the wiring spaces (31), (51), (34) Output leads (9), (39) are arranged, and a plurality of serial blocks (4), (34) output leads (9), (39) are connected to output terminals (13), The power supply device according to claim 1, wherein (43) is arranged in the wiring space (31), (51).

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