DE102017129702A1 - battery device - Google Patents

Abstract

A battery device houses a battery unit and an electrical circuit. The battery unit and the electrical circuit are connected by a connecting member. Two surfaces of the battery unit in a thickness direction prescribe a first virtual plane and a second virtual plane. The electrical circuit is arranged between the first virtual level and the second virtual level. The electric circuit is arranged to the battery unit side in a width direction and a depth direction. Both ends of the connection member prescribe a third virtual plane and a fourth virtual plane with respect to a connection direction of the battery unit. At least part of the electrical circuit is arranged between the third virtual level and the fourth virtual level. A thickness of a battery section housing the battery unit is held down. A circuit portion housing the electrical circuit is thinner than the battery portion.

Description

[Technical area]

The present disclosure relates to a battery device.

[State of the art]

Japanese Patent Laid-Open No. 5942644 discloses a battery device. The battery device has a composite battery module (battery pack module) and a substrate. The assembled battery module has a plurality of battery cells. The substrate provides an electrical circuit or an electrical circuit. The substrate has a portion that overlaps the battery cells and a portion that is not overlapped by the battery cells. The descriptions in the Japanese Patent Laid-Open No. 5942644 The prior art is incorporated herein by reference as descriptions of technical elements in the present specification.

In the configuration that in the Japanese Patent Laid-Open No. 5942644 is described, the battery cells and the substrate, which provides the electrical circuit, arranged in an overlapping manner. Therefore, the battery device is thick. In some cases, the space available for installation of a battery device is small. Consequently, installation of a thick battery device is difficult. For example, when the battery device is thick in height, installation of the battery device into a cavity that is small in height is difficult. In addition, z. For example, when the battery device is thick in width, installation of the battery device into a cavity that is narrow is difficult. From the foregoing perspective, as well as other perspectives that are not mentioned, further improvements in battery devices are needed.

It is therefore desirable to provide a thin battery device. It is also desired to provide a battery device having a portion thinner than a thickness of a battery unit.

SUMMARY

An example embodiment provides a battery device including: a battery unit in which a terminal of a battery cell is disposed on a terminal surface; and a switching component that connects and disconnects a power supplied from the terminal. The battery unit and the switching component are arranged not to overlap in a thickness direction and to be aligned in one or both of a width direction and a depth direction.

According to the battery device of the example embodiment, the battery unit and the switching component do not overlap in the thickness direction. In addition, the battery unit and the switching component are aligned in one or both of the width direction and the depth direction. Therefore, the thickness of the battery device in the thickness direction can be reduced.

The variety of aspects disclosed in the present specification use different technical means to accomplish such tasks. Reference numerals in parentheses in the claims indicate corresponding relationships with portions in accordance with the embodiments described hereinafter and are not intended to limit the technical scope of the present disclosure. Objects, characteristics and advantages disclosed in the present specification will be further clarified by the detailed description below and with reference to the attached drawings.

list of figures

• 1 ist eine perspektivische Ansicht einer Batterievorrichtung gemäß einer ersten Ausführungsform;
• 2 ist eine perspektivische Ansicht der Batterievorrichtung gemäß der ersten Ausführungsform, in der eine Abdeckung entfernt ist;
• 3 ist eine perspektivische Explosionsansicht der Batterievorrichtung gemäß der ersten Ausführungsform;
• 4 ist eine perspektivische Explosionsansicht einer Batterieeinheit gemäß der ersten Ausführungsform;
• 5 ist eine perspektivische Ansicht einer Basis gemäß der ersten Ausführungsform;
• 6 ist eine perspektivische Ansicht der Basis gemäß der ersten Ausführungsform;
• 7 ist eine perspektivische Ansicht einer Sammelschieneneinheit gemäß der ersten Ausführungsform;
• 8 ist eine Draufsicht der Sammelschieneneinheit gemäß der ersten Ausführungsform;
• 9 ist eine Draufsicht der Batterievorrichtung gemäß der ersten Ausführungsform, in der die Abdeckung entfernt ist;
• 10 ist eine schematische Querschnittsansicht eines Einrichtungs- bzw. Installationszustands der Batterievorrichtung gemäß der ersten Ausführungsform;
• 11 ist eine schematische perspektivische Ansicht der Batterievorrichtung;
• 12 ist eine schematische perspektivische Ansicht der Batterievorrichtung;
• 13 ist eine schematische perspektivische Ansicht der Batterievorrichtung;
• 14 ist eine schematische perspektivische Ansicht der Batterievorrichtung;
• 15 ist eine schematische perspektivische Ansicht der Batterievorrichtung;
• 16 ist eine schematische perspektivische Ansicht der Batterievorrichtung;
• 17 ist eine schematische perspektivische Ansicht einer Installationsorientierung bzw. -Ausrichtung der Batterievorrichtung;
• 18 ist eine schematische perspektivische Ansicht eines Laminierzustands einer Vielzahl von Batteriezellen;
• 19 ist eine schematische perspektivische Ansicht einer Orientierung der Batterieeinheit;
• 20 ist eine schematische Querschnittsansicht eines Einrichtungs- bzw. Installationszustands einer Batterievorrichtung gemäß einer zweiten Ausführungsform;
• 21 ist eine schematische Querschnittsansicht eines Installationszustands einer Batterievorrichtung gemäß einer dritten Ausführungsform;
• 22 ist eine schematische Querschnittsansicht eines Installationszustands einer Batterievorrichtung gemäß einer vierten Ausführungsform;
• 23 ist eine schematische Querschnittsansicht einer Batterievorrichtung gemäß einer fünften Ausführungsform;
• 24 ist eine schematische Querschnittsansicht der Batterievorrichtung gemäß der fünften Ausführungsform;
• 25 ist eine schematische Querschnittsansicht einer Batterievorrichtung gemäß einer sechsten Ausführungsform;
• 26 ist eine schematische Querschnittsansicht der Batterievorrichtung gemäß der sechsten Ausführungsform;
• 27 ist eine schematische Querschnittsansicht einer Batterievorrichtung gemäß einer siebten Ausführungsform;
• 28 ist eine schematische Querschnittsansicht der Batterievorrichtung gemäß der siebten Ausführungsform;
• 29 ist eine schematische Querschnittsansicht einer Batterievorrichtung gemäß einer achten Ausführungsform;
• 30 ist eine schematische Querschnittsansicht der Batterievorrichtung gemäß der achten Ausführungsform;
• 31 ist eine schematische Querschnittsansicht einer Batterievorrichtung gemäß einer neunten Ausführungsform;
• 32 ist eine schematische Querschnittsansicht der Batterievorrichtung gemäß der neunten Ausführungsform;
• 33 ist eine schematische Querschnittsansicht einer Batterievorrichtung gemäß einer zehnten Ausführungsform;
• 34 ist eine schematische Querschnittsansicht der Batterievorrichtung gemäß der zehnten Ausführungsform;
• 35 ist eine schematische Querschnittsansicht einer Batterievorrichtung gemäß einer elften Ausführungsform;
• 36 ist eine schematische Querschnittsansicht einer Batterievorrichtung gemäß einer zwölften Ausführungsform;
• 37 ist eine schematische Querschnittsansicht einer Batterievorrichtung gemäß einer dreizehnten Ausführungsform; und
• 38 ist eine schematische Querschnittsansicht einer Batterievorrichtung gemäß einer vierzehnten Ausführungsform.

In the attached drawings:

• 1 is a perspective view of a battery device according to a first embodiment;
• 2 FIG. 15 is a perspective view of the battery device according to the first embodiment in which a cover is removed; FIG.
• 3 FIG. 11 is an exploded perspective view of the battery device according to the first embodiment; FIG.
• 4 FIG. 13 is an exploded perspective view of a battery unit according to the first embodiment; FIG.
• 5 is a perspective view of a base according to the first embodiment;
• 6 FIG. 12 is a perspective view of the base according to the first embodiment; FIG.
• 7 FIG. 15 is a perspective view of a bus bar unit according to the first embodiment; FIG.
• 8th FIG. 10 is a plan view of the bus bar unit according to the first embodiment; FIG.
• 9 Fig. 10 is a plan view of the battery device according to the first embodiment in which the cover is removed;
• 10 FIG. 12 is a schematic cross-sectional view of an installation state of the battery device according to the first embodiment; FIG.
• 11 Fig. 12 is a schematic perspective view of the battery device;
• 12 Fig. 12 is a schematic perspective view of the battery device;
• 13 Fig. 12 is a schematic perspective view of the battery device;
• 14 Fig. 12 is a schematic perspective view of the battery device;
• 15 Fig. 12 is a schematic perspective view of the battery device;
• 16 Fig. 12 is a schematic perspective view of the battery device;
• 17 FIG. 12 is a schematic perspective view of an installation orientation of the battery device; FIG.
• 18 Fig. 10 is a schematic perspective view of a laminating state of a plurality of battery cells;
• 19 Fig. 12 is a schematic perspective view of an orientation of the battery unit;
• 20 FIG. 12 is a schematic cross-sectional view of a state of installation of a battery device according to a second embodiment; FIG.
• 21 FIG. 12 is a schematic cross-sectional view of an installation state of a battery device according to a third embodiment; FIG.
• 22 FIG. 12 is a schematic cross-sectional view of an installation state of a battery device according to a fourth embodiment; FIG.
• 23 FIG. 12 is a schematic cross-sectional view of a battery device according to a fifth embodiment; FIG.
• 24 FIG. 12 is a schematic cross-sectional view of the battery device according to the fifth embodiment; FIG.
• 25 FIG. 12 is a schematic cross-sectional view of a battery device according to a sixth embodiment; FIG.
• 26 FIG. 12 is a schematic cross-sectional view of the battery device according to the sixth embodiment; FIG.
• 27 FIG. 12 is a schematic cross-sectional view of a battery device according to a seventh embodiment; FIG.
• 28 FIG. 12 is a schematic cross-sectional view of the battery device according to the seventh embodiment; FIG.
• 29 FIG. 12 is a schematic cross-sectional view of a battery device according to an eighth embodiment; FIG.
• 30 FIG. 12 is a schematic cross-sectional view of the battery device according to the eighth embodiment; FIG.
• 31 FIG. 12 is a schematic cross-sectional view of a battery device according to a ninth embodiment; FIG.
• 32 FIG. 12 is a schematic cross-sectional view of the battery device according to the ninth embodiment; FIG.
• 33 FIG. 12 is a schematic cross-sectional view of a battery device according to a tenth embodiment; FIG.
• 34 FIG. 12 is a schematic cross-sectional view of the battery device according to the tenth embodiment; FIG.
• 35 FIG. 12 is a schematic cross-sectional view of a battery device according to an eleventh embodiment; FIG.
• 36 FIG. 12 is a schematic cross-sectional view of a battery device according to a twelfth embodiment; FIG.
• 37 FIG. 12 is a schematic cross-sectional view of a battery device according to a thirteenth embodiment; FIG. and
• 38 FIG. 16 is a schematic cross-sectional view of a battery device according to a fourteenth embodiment. FIG.

DESCRIPTION OF THE EMBODIMENTS

A variety of embodiments will be described with reference to the drawings. According to the plurality of embodiments, either the one or both of portions that correspond functionally and / or structurally to each other and portions that are related to each other may have the same reference numerals. Alternatively, such portions may be provided with reference numerals whose counters differ from each other at the hundredth place or higher. Descriptions according to other embodiments may be referenced for corresponding and / or affected sections.

First Embodiment

1 shows a battery device 10 , 1 shows a perspective view of the battery device 10 in a regular installation state. Hereinafter corresponds to the top / bottom in the regular installation state top / bottom in the drawings, unless otherwise indicated. A thickness direction TH which is the up / down direction or a height direction (HD), a width direction WD and a depth direction DD are indicated in the drawings. According to the present embodiment, the thickness direction TH is the direction of gravity. The width direction WD and the depth direction DD are lateral directions that are perpendicular to the thickness direction TH.

The battery device 10 has a cover 11 and a base 30 , The cover 11 and the base 30 form an outer shell of the battery device 10. The cover 11 and the base 30 provide a housing of the battery device 10 , The cover 11 is composed of a resin. The cover 11 provides the outer shell in an upper portion of the battery device 10. The base 30 provides the outer jacket in a lower portion of the battery device 10 , The battery device 10 is mounted in a vehicle.

The battery device 10 is mounted inside the vehicle. An example of the vehicle is an automobile. For example, the battery device 10 mounted under a seat of the vehicle. The battery device 10 has a height suitable for mounting under a seat of a vehicle.

2 shows the battery device 10 in a state where the cover 11 is removed. The battery device 10 works in cooperation with a motor generator (MG) 15 of the vehicle. The battery device 10 provides an engine system of the vehicle. The motor generator 15 is with an internal combustion engine (EG) 16 connected. The battery device 10 is connected to electrical loads (LD1 and LD2) 17 and 18 of the vehicle. The electrical load 17 includes electrical loads, such. B. a battery and a starter, through which a large current flows. The electrical load 18 includes some or all of a variety of electrical loads of the vehicle except the battery and the starter.

The motor generator 15 works as a power generator by being powered by the engine 16 , At least part of the electrical power generated by the motor generator 15 is supplied to the battery device 10 is supplied. In this case, the battery device 10 loaded. The motor generator 15 also gets electrical power from the battery device 10 provided. In this case, the motor generator works 15 as an engine. The motor generator 15 works as a power source together with the internal combustion engine 16 , For example, the motor generator leads 15 Power or current that exceeds the power provided by the internal combustion engine 16 or power that supplements the power supplied by the internal combustion engine 16 is supplied, too. For example, a rated voltage of the battery device 10 12 Volt.

3 shows the battery device 10 in an explosion state. In 3 has the battery device 10 a battery unit 20 , the base 30 , a busbar unit 40 and an electrical circuit 50 on. The battery unit 20 , the busbar unit 40 and the electrical circuit 50 are in the base 30 assembled. The base 30 has a recessed shaped container section 31 , the battery unit 20 receives. The base 30 accommodates only a portion of the battery pack 20 in the container section 31 , The remaining part or section (upper section) of the battery unit 20 sticks out from the base 30 in front. The battery unit 20 , the busbar unit 40 and the electrical circuit 50 are mounted in the base 30 along the height direction HD, which is an assembling direction. The battery unit 20 , the busbar unit 40 and the electrical circuit 50 are at the base 30 by a variety of fastening components, such. As screws or bolts, fixed.

The battery device 10 has a connection component 80 for the electrical connection of the battery unit 20 and the electrical circuit 50 , The battery unit 20 has a main terminal or a main terminal. The main terminal provides an output line which is controlled so that an output is connected and disconnected. The main connection is a positive connection or a positive terminal of the battery unit 20 (also called a total positive pole). The connection component 80 is a metal component that connects the positive terminal of the battery unit 20 and the electrical circuit 50 combines.

According to the present embodiment, the connecting member is 80 as a bus bar, which is a metal plate having a predetermined shape. In a manufacturing method of the battery device, the bus bar is formed by a metal plate which is cut into a predetermined shape and then bent into a predetermined shape. The connection component 80 has a first busbar 81 and a second busbar 82 , The first busbar 81 is with the battery unit 20 connected. The second busbar 82 is with the electrical circuit or the electrical circuit 50 connected. The connection component 80 has a fastening component 83 that's the first busbar 81 and the second busbar 82 is attached. The attachment member 83 is a bolt or a screw.

The first busbar 81 is electrically connected to the positive connection or positive pole of the battery unit 20 by being fixed to the positive terminal of the battery unit 20 connected by a fastening means or a fastening device. The fastener is a weld. The fastening means may also be provided by various means, such as. As soldering, screwing and tightening. The first busbar 81 has an opening portion for receiving the fastening component 83 , The second busbar 82 is electrically connected to the electrical circuit 50 by being fixed to the electrical circuit 50 connected by a fastener. The fastener is a solder. The fastening means may also be provided by various means, such as. As a weld, a screw and tightening. The second busbar 82 has a plurality of terminal portions for connecting to the electric circuit 50 , The second busbar 82 has an opening portion for receiving the fastening component 83 ,

Returning to 2 has the battery unit 20 a housing 22 containing a variety of battery cells 21 houses. The housing 22 is composed of an electrically insulating resin. The housing 22 is a part of a container containing the multitude of battery cells 21 houses. The housing 22 fixes the multitude of battery cells 21 together. In addition, the housing 22 is a fixing member that holds the plurality of battery cells 21 at the base 30 fixed. The housing 22 has a plurality of holders for fixing the battery unit 20 at the base 30 , The housing 22 has a plurality of ribs, one or both of increased wall thickness and wall thickness and a reduction of a gap between the housing 22 and the base 30 to reach.

The battery unit 20 has a monitor module or a monitoring module 23 , The monitoring module 23 has an electrically insulating resin component 24 and the monitor connection components 25 , The monitoring connection components 25 are with the variety of battery cells 21 connected. The audit connection component 25 is in the resin component 24 embedded by an insert molding. The audit connection component 25 leads through the resin component 24 through and connects the battery cell 21 and the electrical circuit 50 , In 2 For example, a plurality of monitor connection components 25 are exposed at a portion connected to the electric circuit 50 connected is.

The monitoring module 23 has a humidity sensor 60 (Not shown). The moisture sensor 60 has a plurality of humidity detecting electrodes (not shown). The monitoring module 23 is along a surface of the housing 22 arranged, which is a hexahedron. The monitoring module 23 also serves as a lid of the housing 22 , A detailed form of the battery unit 20 will be described below.

The base 30 is formed of a conductive metal. The base 30 is also referred to as a carrier. The base 30 is made by an aluminum die casting. The base 30 has a high rigidity. The base 30 has a container section 31 , the battery unit 20 receives. The base 30 has a variety of supports 32a . 32b . 32c and 32d , The pillars 32a to 32d become collectively as supports 32 designated. The pillars 32 are fixing portions for fixing the battery device 10 on the vehicle. The pillars 32 have a variety of shapes.

The busbar unit 40 provides a current path, which differs from a power connector of the battery unit 20 extends out. The bus bar unit 40 has an electrically insulating resin member and power connection members. The power connection components are with the battery unit 20 connected. The busbar unit 40 is based 30 fixed. The busbar unit 40 has electricity connections 41 . 42 and 43 , The busbar unit 40 has at least two power connection components. One of the power connection components is between a power connector of the battery unit 20 and each of the variety of power connections 41 . 42 and 43 provided and provides an electrical connection. The power connection 41 that is on an outer side is with the motor generator 15 connected. The power connection 42 Being on an inner side is with the electrical load 17 connected. The power connection 43 is with the electrical load 18 connected.

The electrical circuit 50 is based 30 fixed. The electrical circuit 50 expands over an area adjacent to the battery pack 20 out. The electrical circuit or the electrical circuit 50 spreads over an area next to an area of the battery unit 20 and another surface of the battery unit 20 out. The electrical circuit 50 may be referred to as an L-shaped type or a hook-shaped type. The battery unit 20 is in a corner portion of the substantially rectangular base 30 arranged. The electrical circuit 50 occupies a hook-shaped area on the base 30 that is next to the battery unit 20 expands. The electrical circuit 50 is along the monitoring module 23 arranged. A part or a section of the electrical circuit 50 is arranged to move over an area adjacent to the side of the monitoring module 23 the battery unit 20 expand. Another part or section of the electrical circuit 50 is arranged to an area next to the battery unit 20 and adjacent to a peripheral surface of the battery module 23 to prove. An arrangement like this contributes to an effective arrangement of the battery 20 and the electrical circuit 50 that communicate with each other.

The electrical circuit 50 has a substrate 51 and a variety of electrical components 52 , The substrate 51 is a so-called printed circuit board or board. The substrate 51 may be referred to as an L-shaped type or a hook-shaped type. The substrate 51 spreads out over a horizontal area caused by the electrical circuit 50 is occupied, which is described above. The substrate 51 is a single substrate. The variety of electrical components 52 is on the substrate 51 arranged. The substrate 51 has a plurality of connecting portions. Some or all of the plurality of connection portions provide connection between the power connection components of the busbar unit 40 and the electrical components 52 ,

The electrical circuit 50 is with the variety of battery cells 21 connected. The variety of electrical components 52 offers a control unit. The control unit monitors the voltage of each of the plurality of battery cells 21 included in the battery unit 20 are included. The control unit monitors a state of charge and a discharge state of each of the plurality of battery cells 21 , The control unit appropriately controls the state of charge of each of the plurality of battery cells 21 ,

The variety of electrical components 52 includes a single or a plurality of switching components 53 , The switching component 53 is controlled to go through the electrical circuit 50 to be switched on and off. The switching component 53 controls the output of the battery unit 20 to connect and disconnect the output. The switching component 53 connects and disconnects a current from a positive pole or a positive terminal (also called a total positive pole) 20p of the battery unit 20 is supplied. The switching component 53 is on or on the substrate 51 assembled. The switching component 53 is a semiconductor switch widely known as a transistor, a metal oxide semiconductor (MOS), an insulated gate bipolar transistor (IGBT), or the like. As described below, the switching component 53 away from the substrate 51 being held. In addition, the switching component 53 be provided by a relay which is opened and closed electromagnetically.

The connection component 80 electrically connects the positive terminal of the battery unit 20 and the switching component 53 , The connection component 80 sees at least part of a conductive component between the positive terminal of the battery 20 and the switching component 53 in front. The connection component 80 is near the battery unit 20 on the substrate 51 arranged. The connection component 80 is at one edge of the substrate 51 next to the battery unit 20 arranged. The connection component 80 is in a section of the substrate 51 next to the main terminal of the battery unit 20 connected or connected. A variety of connections for the connection component 80 is on the substrate 51 along the battery unit 20 trained or arranged. The switching component 53 is near the connection component 80 arranged.

In cases where water is splashed on the seat, a wet occupant uses the seat, or the vehicle is submerged in water, water may enter the interior of the battery device 10 infiltrate. In this case, the battery device 10 perform a discharge using the water as a delivery path. According to the present embodiment, the humidity sensor is 60 provided, the moisture in the battery device 10 detected. In addition, a control unit is also provided which performs a countermeasure process when moisture is detected. The control unit monitors an infiltration of water into the battery device 10 , When an infiltration of water is detected, the control unit performs a countermeasure process. For example, the countermeasure process is to turn off a breaker element that is one of the plurality of electrical components 52 is.

A control system through the electrical circuit 50 is provided provides a control device, which is an electronic control unit (ECU). The control device has at least a single central processing unit (CPU) and at least one single memory unit (memory-mapped register [MMR]). The storage unit serves as a storage medium for storing programs and data. The control device is provided by a microcomputer having a computer readable storage medium. The storage medium is a computer-readable, non-transitory, tangible storage medium that stores a program in a non-permanent manner. The storage medium may be through a semiconductor memory, a magnetic disk or the like be provided. The controller may be provided by a single computer or a set of computer resources interconnected by a data link device. As a result of the control device executing the program, the control device functions as the device described in the present specification, and is capable of performing the method described in the present specification.

The control system has a plurality of signal sources as input devices. The plurality of signal sources provide signals indicative of formations input to the controller. The control system obtains information by the controller storage of information in the storage unit. The control system has a plurality of control destinations as output devices. The behaviors of the plurality of control targets are controlled by the control device. The control system controls the behavior of the control targets by converting the information stored in the memory unit into signals and providing the signals to the control targets.

The controller, the signal sources, and the control targets included in the control system provide various elements. At least some of these elements may be referred to as a block for providing a function. From a different perspective, at least some of these elements may be referred to as a module or section that is interpreted as a configuration. Further, an element included in the control system may also be referred to as a means for updating a function only if so desired.

One or both of the means and functions offered by the control system may be provided by software stored in a tangible storage device or a computer operating the software, by software alone, by hardware alone, or by a combination thereof be. For example, when the control device is provided by an electronic circuit that is hardware, the control device may be provided by a digital circuit having a plurality of logic circuits or an analog circuit. The electrical circuit 50 may comprise a circuit serving as one or both of an inverter and a converter, and having a monitoring circuit which monitors the voltages of the plurality of battery cells 21 supervised. In this case, the control device is housed in a separate container for an electrical circuit.

4 is an exploded perspective view of the battery unit 20 , The battery unit 20 is designed as a cuboid or a cuboid. The battery unit 20 has the plurality of battery cells 21 on. In 4 four battery cells 21 are shown. The battery cell 21 is a flat cuboid. The battery cell 21 is a hexahedron. Positive and negative connections or terminals 21a are on a narrow surface of the battery cell 21 arranged. The battery cell 21 is laterally or laterally arranged such that the terminals 21a are exposed on a lateral side surface. The variety of battery cells 21 is laminated so that a widest major surface 21b from each battery cell 21 the width direction WD faces.

The battery cell 21 has two widest main surfaces 21b , As the battery cell 21 swells, the major surfaces become 21b significantly impaired. Because the variety of battery cells 21 is laminated such that the plurality of major surfaces 21b parallel to these, swelling occurs in the direction in which the major surfaces 21b facing each other. In the example that is in 4 is shown swells the plurality of battery cells 21 in the lateral direction. The direction in which the battery cells 21 swell, the width direction is WD. In other words, the multiplicity of battery cells swells 21 significantly in the lamination direction thereof, ie, the width direction WD. In other words, the multiplicity of battery cells swells 21 along the surface of the base 30 at. In other words, the multiplicity of battery cells swells 21 in the width direction WD perpendicular to the assembling direction.

The variety of battery cells 21 is in the case 22 houses. The housing 22 has an opening portion on a front surface of the hexahedron. The housing 22 has a mug 22a and a cap 22b , The cup 22a is a first housing and the cap 22b is a second housing. The cup 22a divides the interior of the case 22 for each of the plurality of battery cells 21. The cap 22b is a lid body containing a variety of ladders 26 holds.

The battery unit 20 has the variety of ladders 26 containing the variety of battery cells 21 connect. The variety of ladders 26 connects the multitude of battery cells 21 in row. The battery unit 20 has a multiplicity of monitor connections or monitoring connections 27 , The monitoring terminals 27 are used to at least the voltages of the battery cells 21 capture. In the example that is in 4 shown has the battery unit 20 five battery cells 21 , The Variety of ladders 26 is in 4 shown. In the example that is in 4 Shown are six monitoring ports 27 intended. A single monitoring connection 27 is for a single conductor 26 intended. The condition of each of the five battery cells 21 is through the six monitoring ports 27 supervised. The variety of monitoring ports 27 is in 4 shown.

The monitoring module 23 has the variety of monitoring connection components 25 , The monitoring connection components 25 take the surveillance connection 27 on. The audit connection component 25 and the monitoring port 27 are electrically connected. The monitoring module 23 and the humidity sensor 60 are by dividing the resin component 24 integrated. The monitoring module 23 and the humidity sensor 60 can be handled as a single component. The moisture sensor 60 has the variety of moisture detection electrodes 61 ,

The battery unit 20 has a sealing component 28 , The sealing component 28 is between the multitude of battery cells 21 and the monitoring module 23 arranged.

In a normal product installation state, the assembly direction of the components of the battery unit 20 laterally relative to the housing 22 , The assembly direction is the depth direction DD. The variety of battery cells 21 is positioned such that the plurality of terminals 21 on the laterally facing surface. Therefore, the plurality of battery cells 21 and the electrical circuit or circuit 50 to be connected with few components. The variety of battery cells 21 is laminated such that the plurality of major surfaces 21b in which swelling occurs significantly, facing the lateral direction. That is why in cases where the multitude of battery cells 21 swells, the main direction of swelling the width direction WD.

The first busbar 81 is in 4 shown. The first busbar 81 is also one of the ladders 26 , As a result of the plurality of battery cells 21 that come in series through the multitude of ladders 26 are connected, the positive terminal or positive pole of a single battery cell is used 21 as the positive connection or positive pole 20p the battery unit 20 , In a similar manner, a negative terminal is for a single battery cell 21 as a negative terminal (also called a total minus pole) 20n of the battery unit 20. The positive terminal or positive terminal 20p is the main connection of the battery unit 20 , The first busbar 81 is with the positive connection 20p the battery unit 20 connected.

5 is a perspective view of the base 30 which is seen at an angle from the front and from the top. 6 is a perspective view of the base 30 which is seen from the opposite side. The base 30 is plate or plate-shaped. The base 30 has a shape that can be called a flat plate shape or a flat cup shape. In the container section 31 sticks out the shape of the base 30 down in front and deepens from above. The base 30 has a high rigidity against an external force that tries to base 30 to twist. The base 30 has a high rigidity against an external force in the lateral direction in which the container portion 31 is opened, and in particular the width direction WD. The base 30 has a high rigidity with respect to the direction in which the plurality of 21 swells significantly.

The container section 31 has sidewalls 31a and 31b , a bottom wall 31c , a rear wall or a rear wall 31d and a front wall or front wall 31e , In other words, the base has 30 side walls 31a and 31b , the bottom wall 31c , the back wall 31d and the front wall 31e , In the description hereinafter, the monitor module side of the battery unit is 20 the front. The container section 31 is an open container having an opening portion which is open at the top.

The side walls 31a and 31b are on both sides of the tank section 31 intended. The side walls 31a and 31b are in the lamination direction of the plurality of battery cells 21 , ie the width direction WD, positioned. The inner surfaces of the side walls 31a and 31b provide side surfaces 33a and 33b. The side surfaces 33a and 33b are to the container section 31 turned. The side surfaces 33a and 33b are arranged opposite each other. The side surfaces 33a and 33b are part of a wide area that runs through the side walls 31a and 31b is provided. The side surfaces 33a and 33b are the battery unit 20 with a tiny gap (clearance) in between, or are with the battery pack 20 in contact. The side wall 31a has a plurality of bolt holes 34 for fixing the housing 22 , The side wall 31b has a variety of bolt holes or screw holes 34 for fixing the housing 22 , The screw hole 34 has a hole having a depth in the height direction HD, which is in the assembling direction, and an internal thread formed on an inner surface of the hole. Both side walls 31a and 31b see the screw holes 34 in front. That's why the side walls have 31a and 31b complex shapes. One from the multitude of screw holes 34 is above the middle of the main area 21b in a sidewall 31a educated. Also, one of the multitude of screw holes 34 above the middle of the main surface 21b in the other side wall 31b educated. The side walls 31a and 31b also have other screw holes for attaching the cover 11 , as well as other screw holes for attaching components for an electrical connection.

The bottom wall 31c is at the bottom of the container section 31 positioned. The bottom wall 31c is the bottom wall of the base 30 , The bottom wall 31c connects the lower end of the side wall 31a and the lower end of the side wall 31b. The inner surface of the bottom wall 31c sees a floor area 33c in front. The floor area 33c is in the container section 31 looking. The floor area 33c is considered the top surface of the base 30 turned upwards.

The back wall or rear wall 31d is on the back of the tank section 31 positioned. The back wall 31d connects the side wall 31a , the side wall 31b and the bottom wall 31c , The inner surface of the back wall 31d sees a back surface 33d in front. The back surface 33d is in the container section 31 looking. The back wall 31d connects the upper portions of the side walls 31a and 31b. The back wall 31d connects the side walls 31a and 31b in a straight way. The back wall 31d serves as a bar between the side walls 31a and 31b is provided. The back wall 31d resists an external force affecting the sidewalls 31a and 31b collapsed outward to widen the top.

The front wall or front wall 31e is on the front of the container section 31 positioned. The front wall 31e is with the bottom wall 31c connected. The front wall 31e can also with the sidewall 31a , the side wall 31b and the bottom wall 31c be connected. The inner surface of the front wall 31e sees a front surface 33e in front. The front surface 33e is in the container section 31 turned in. The front wall 31e is a section of a stepped wall that lies between the bottom wall 31c and a heat dissipation wall 35 is trained. The front wall 31e connects the side walls 31a and 31b , The front wall 31e serves as a bar between the side walls 31a and 31b is provided. The front wall 31e resists an external force affecting the sidewalls 31a and 31b collapsed outwards to widen on the top.

Returning to 3 are some of the electrical components 52 over the heat dissipation wall 35 arranged. Some of the electrical components 52 require heat dissipation. For example, the switch component 53 the electrical circuit or the electrical circuit 50 over the heat dissipation wall 35 arranged. An insulating plate 59 is between the heat dissipation wall 35 and the electrical circuit 52 arranged. As a result, the electrical component conducts 52 Heat to the heat dissipation wall 35 over the insulating plate 59 from. In the base 30 protrudes the heat dissipation wall 35 upwards and deepens from below. Therefore, the heat dissipation wall looks 35 a heat dissipation section projecting from below on the lower surface of the base 30 is deepened.

7 and 8th show a condition in which the battery unit 20 , the busbar unit 40 and the connection component 80 on or at the base 30 are mounted. The connection component 80 is also part of the busbar unit 40 , The busbar unit 40 connects the plurality of terminals 41, 42, 43, the battery unit 20 and the electrical circuit 50 ,

The busbar unit 40 has a variety of busbars 45 . 46 and 47. The variety of busbars 45 . 46 and 47 have sections that extend along the battery unit 20 extend. The variety of busbars 45 , 46 and 47 extend in parallel. The variety of busbars 45 . 46 and 47 are arranged to be on both sides of the heat dissipation wall 35 to be distributed. An arrangement such as this provides an arrangement suitable for connection to the electrical components 52 that over the heat dissipation wall 35 are arranged. For example, the arrangement is effective in shortening a track over which a relatively large current flows through the switching components 53 disconnected and connected. As a result, the current path can be shortened and heat generation by the electric circuit 50 itself can be suppressed while dissipating heat from a variety of electrical components 52 through the heat dissipation wall 35 is encouraged. The variety of connection sections, which in 7 and 8th are shown is with the substrate 51 connected.

The connection component 80 is between the battery unit 20 and the heat dissipation wall 35 arranged. The connection component 80 , which is also a section of the busbar unit 40 is adjacent to the heat dissipation wall 35. Therefore, the connection member carries 80 also to suppress heat generation in the electrical circuit 50 at.

In 9 is the battery unit 20 in the base 30 assembled. The housing 22 is at the base 30 through a variety of bolts or screws 71 fixed. The variety of bolts or screws 71 is in the screw holes 34 used. The housing 22 has a variety of holders 22c . 22d . 22e and 22f , The variety of holders 22c . 22d . 22e and 22f are designed to from the side surfaces of the housing 22 to stand out. The variety of holders 22c . 22d . 22e and 22f are with the case 22 integrally formed by the resin, which is the housing 22 forms. The variety of screws 71 pulls the plurality of holders 22c, 22d, 22e and 22f toward the base 30 towards. The variety of screws 71 serves as tightening components or fastening components.

The connection component 80 is in 9 shown. The first busbar 81 has a shape along the depth direction DD of the battery unit 20 to the substrate 51 protrudes. The fastening component 53 attaches the first busbar 81 along the thickness direction TH. The fastening component 83 attaches the second busbar 81 along the thickness direction TH. The second busbar 82 extends from the fastening or tightening position around the underside of the substrate 51 around to the substrate 51 out. The second busbar 82 has a variety of connections through the substrate 51 pass through.

10 shows an installation state of the battery device 10 , 10 shows a schematic cross-sectional view of a plurality of components to show relative positions of a plurality of components. The battery device 10 is arranged in a gap which is small in height. The gap is between a seat ST1 and a floor ST2, which are structures of a vehicle. The gap expands widely between the seat ST1 and the floor ST2. The seat ST1 has a portion protruding downward and a portion recessed upward. The floor ST2 has a section which projects upwards and deepens downwards. Therefore, the gap has a narrow gap portion and a wide gap portion.

The battery device 10 is set across both the narrow gap portion and the wide gap portion. A thickness direction TH of the gap is also the thickness direction TH of the battery device 10 , The battery device 10 is set in the gap such that the battery unit 20 is placed towards the rear of the vehicle and the electrical circuit 50 placed to the front of the vehicle. The section where the battery unit 20 is housed as a battery section 10a designated. The section where the electric circuit or the electric circuit 50 is housed as a circuit section 10b designated. The circuit section 10b is thinner than the battery section 10a ,

The battery unit 20 is a hexahedron. Each surface has protrusions and depressions. The area on which the positive connection 20p the battery unit 20 is arranged, is a connection surface 20m , The connection surface 20m is also referred to as a first surface or a front surface. The area on the side opposite the area on which the positive terminal 20p the battery unit 20 is provided, is a second surface. The second surface is referred to as a back surface. The direction that is between the pad 20m and the second surface is also referred to as a connection direction TMD of the battery unit 20 designated. According to the present embodiment, the connection direction TMD is the depth direction DD.

The four remaining areas of the battery pack 20 are side surfaces. Based on two surfaces of the battery unit 20 in the thickness direction TH, a first virtual plane VP1 and a second virtual plane VP2 may be assumed, which include the two surfaces. In other words, the two surfaces of the battery pack write 20 farthest from the thickness direction TH, the first virtual plane VP1 and the second virtual plane VP2 having the two faces. One of the side surfaces of the battery unit 20 is a third area in the thickness direction TH. The third surface is referred to as an upper surface. The first virtual plane VP1, which has the third area, can be assumed. One of the side surfaces of the battery unit 20 is a fourth area in the thickness direction TH. The fourth surface is referred to as a bottom surface. The second virtual plane VP2, which has the fourth area, can be assumed.

The third surface and the fourth surface are two surfaces perpendicular to the thickness direction TH of the flat battery device 10 are. The thickness of the battery device 10 is designed based on the space between the third surface and the fourth surface. In other words, the thickness of the battery device 10 depends on the space between the third surface and the fourth surface. The direction extending between the third surface and the fourth surface is also referred to as a major surface direction parallel to the main surface of the battery cell 21 is. According to the present embodiment, the major surface direction is the thickness direction TH.

The two remaining areas of the battery pack 20 are a fifth surface and a sixth surface in the width direction WD. The fifth surface and the sixth surface are respectively a right surface and a left surface. The direction extending between the fifth surface and the sixth surface is also referred to as the laminating direction in which the plurality of battery cells 21 is laminated. According to the present embodiment, the laminating direction is the width direction WD.

The switching component 53 is arranged between the first virtual level VP1 and the second virtual level VP2. The switching component 53 is near the positive connection 20p the battery unit 20 arranged. The switching component 53 is thermal with the heat dissipation wall 35 connected. The heat dissipation wall 35 is arranged between the first virtual level VP1 and the second virtual level VP2. As a result, the heat dissipation wall 35 the heat from the switching component 53 derive at a short distance.

The connection component 80 is between the battery unit 20 and the electrical circuit 50 arranged. The connection component 80 extends from the pad 20m the battery unit 20 to the electrical circuit 50 outwards. A third virtual plane VP3 and a fourth virtual plane VP4 may be assumed to be an area of extension of the connection part 80 prescribe. The third virtual plane VP3 and the fourth virtual plane VP4 are parallel to the pad 20m of the battery pack 20 and the second surface. The connection component 80 is between the third virtual plane VP3 and the fourth virtual plane VP4. The third virtual plane VP3 and the fourth virtual plane VP4 write two maximum protrusion portions of the connection member 80 in the connecting direction TMD before, ie, the depth direction DD. In the example in 10 is the third virtual plane VP3 at the position of the connection device 80 next to the second surface in the direction of connection TMD. The fourth virtual plane VP4 is at the position of the connection part 80 farthest from the battery unit 20 in the connection direction TMD.

11 shows a positional relationship between the battery unit 20 and the substrate 51 in the battery device 10 , The battery unit 20 may be a rectangular parallelepiped, a cube or a stepped polygon as disclosed in Japanese Patent Laid-Open No. 5942644. The battery unit 20 is arranged such that the connection surface 20m the width direction WD or the depth direction DD faces. The substrate 51 has a flat surface which is at a right angle to the thickness direction TH. The substrate 51 has a flat surface that expands in the TMD connection direction. The substrate 51 has a planar surface that propagates in the width direction WD and the depth direction DD.

In the battery device 10 make up the cover 11 and the base 30 the housing. The housing has the battery section 10a for harboring the battery unit 20 , The housing also has the circuit section 10b for accommodating the electrical circuit 50 , The circuit section 10b is adjacent to the battery section 10a , According to the present embodiment, the substrate has 51 an L shape. The substrate 51 runs along the connection surface of the battery unit 20 and the sixth area. In other words, the substrate 51 with the battery unit 20 aligned in the width direction WD and the depth direction DD. Therefore, the circuit section 10b adjacent at least two surfaces of the battery section 10a ,

The battery section 10a has a thickness TH10a in the thickness direction TH. The circuit section 10b has a thickness TH10b in the thickness direction TH. The thickness TH20 between the first virtual plane VP1 and the second virtual plane VP2 is in 11 shown. The thickness TH20 is also the thickness of the battery unit 20 ,

The battery section 10a has a cavity for the battery unit 20 in addition to the thicknesses of the cover 11 and the base 30 , Therefore, the thickness TH10a is larger than the thickness TH20 (TH20 <TH10a). The thickness TH10b is less than the thickness TH10a (TH10b <TH10a). The circuit section 10b may be formed to be thinner than the battery section 10a to be. As a result, the battery device 10 be arranged in the gap in the vehicle.

12 shows the battery unit 20 , the electrical circuit 50 and the connection component 80 , The connection component 80 is shown schematically as a rectangular parallelepiped. The connection component 80 is provided by a bus bar or an electric wire having a single bent portion or more. The connection component 80 may also be shown in the following drawings in a similar manner.

The electrical circuit 50 is positioned between the first virtual level VP1 and the second virtual level VP2. The substrate 51 is positioned between the first virtual level VP1 and the second virtual level VP2. The switching component 53 is positioned between the first virtual level VP1 and the second virtual level VP2. The connection component 80 is positioned between the first virtual level VP1 and the second virtual level VP2. The entire electrical circuit 50 and the entire connection member 80 are disposed between the first virtual plane VP1 and the second virtual plane VP2. This configuration contributes to suppressing the thickness of the battery device 10 at.

A lead area PRJ20 can be accepted. The projection area PRJ20 is through the interface 20m the battery unit 20 prescribed along the connection direction TMD in the direction away from the pad 20m projects. At least a portion or part of the electrical circuit 50 is positioned within the protrusion area PRJ20. At least one section or part of the switching component 53 (One or a plurality among the plurality of switching elements 53 or part of a single switching component 53 ) is positioned within the protrusion area PRJ20. The connection component 80 is positioned within the protrusion area PRJ20. At least a portion of the connection component 80 may be positioned within the protrusion area PRJ20. At least a portion or part of the electrical circuit 50 and at least a portion or part of the connection component 80 are disposed within the protrusion area PRJ20. An arrangement such as this allows size reduction of the battery device 10 ,

Since the current that flows is relatively large, the switching component 53 and the connection component 80 preferably near the pad 20m arranged on the positive terminal or positive pole 20p the battery unit 20 is arranged. As a result of the substrate 51 that in front of the connection area 20m is positioned, there will be a short connection between the positive terminal 20p the battery unit 20 and the substrate 51 realized. The switching component 53 is on the substrate 51 arranged. Therefore, a short connection between the positive terminal 20p the battery unit 20 and the switching component 53 realized. This arrangement allows size reduction of components through which a relatively large current flows. For example, the arrangement contributes to a shortening of the connecting member 80 at. In addition, z. B. a wiring on the substrate 51 be shortened, through which flows a relatively large current.

13 shows the battery unit 20 , the electrical circuit 50 and the connection component 80 , Both ends of the connecting component 80 in the connection direction TMD, the third virtual plane VP3, which is at a right angle to the connection direction TMD, and the fourth virtual plane VP4, which is at a right angle to the connection direction TMD, write. That is why the connection component 80 is arranged between the third virtual level VP3 and the fourth virtual level VP4. At least a portion or part of the electrical circuit 50 is disposed between the third virtual plane VP3 and the fourth virtual plane VP4. At least part of the substrate 51 is disposed between the third virtual plane VP3 and the fourth virtual plane VP4.

Further, a first virtual area VS1, which is a thin rectangular parallelepiped between the third virtual plane VP3 and the fourth virtual plane VP4, may be on the outer side of the pad 20m in the connection direction TMD. In the first virtual area VS1 is the pad 20m the floor area. The height of the first virtual area VS1 is the distance between the third virtual plane VP3 and the fourth virtual plane VP4. At least part of the electrical circuit 50 is within the first virtual area VS1. At least part of the substrate 51 is within the first virtual area VS1.

Further, a second virtual area VS2 extending from the first virtual area VS1 to both sides in the width direction WD may be adopted. The second virtual area VS2 is between the first virtual plane VP1 and the second virtual plane VP2. At least part of the electrical circuit 50 is within the second virtual area VS2. At least part of the substrate 51 is within the second virtual area VS2.

14 shows the position of the substrate 51 with respect to the battery unit 20 , The battery unit 20 has the positive terminal 20p and the negative terminal 20n on the interface 20m , In this case, the substrate is 51 preferably arranged on the front of the pad 20m. That is, the substrate 51 is preferably on the outer side in the connection direction TMD on the pad 20m arranged. This position may be referred to as a front position FR with respect to the battery unit 20. The switching component 53 is also preferably arranged in the front position FR. However, the substrate can 51 also be arranged in a right position SD1 or a left position SD2, the side positions in the width direction WD of the battery unit 20 are. A short connection of the positive connection 20p the battery unit 20 can be realized equally from these side positions. In addition, the substrate can 51 also be arranged in a rear position RR.

15 shows the position of the substrate 51 with respect to the battery unit 20 , The substrate 51 may be arranged between the first virtual level VP1 and the second virtual level VP2. The substrate 51 is preferably arranged in an intermediate position or an intermediate position MD of the battery unit 20 in the thickness direction TH. However, the substrate can 51 also in a lower section position LW or an upper section position HG of the battery unit 20 be arranged. The substrate 51 can near the positive connection 20p the battery unit 20 be arranged in any one of the positions.

16 shows an orientation of the substrate 51 with respect to the battery unit 20. The substrate 51 shown in earlier drawings has a plane shape that expands in the width direction WD and the depth direction DD. The substrate 51 may have a flat surface that also expands in the thickness direction TH.

As in 16 The substrate can be shown 51 parallel to one or both of the surfaces of the battery pack 20 which faces the width direction WD and the surface of the battery unit 20 be provided, which faces the depth direction DD. Regarding the orientation, the in 16 can also be the section that shows the battery unit 20 harbors, be trained to be skinny. Further, a portion that is even thinner than a portion may be the battery unit 20 accommodates, in addition to the portion formed by the battery unit 20 houses.

17 shows a position of the substrate 51 with respect to the battery unit 20 in the battery device 10 , The battery device 10 has a thickness direction TH that intersects the direction of gravity. In the battery device 10 the thickness direction TH is a lateral direction. In the battery device 10 the width direction WD is the height direction or vertical direction HD.

The first virtual plane VP1 and the second virtual plane VP2 may be based on two areas in the thickness direction TH of the battery unit 20 be accepted. The battery unit 20 , the electrical circuit 50 and the connection component 80 are between the first virtual level VP1 and the second virtual level VP2. The substrate 51 has a flat surface which is at a right angle to the thickness direction TH. The substrate 51 has a flat surface that expands in the TMD connection direction. The substrate 51 has a flat surface that expands in the width direction WD and the depth direction DD.

The battery device 10 has the battery section 10a and the circuit section 10b , In addition, the circuit section 10b be formed to be thinner than the battery section 10a to be. In an arrangement like this, the thin battery device can also be used 10 be offered. In addition, the battery device 10 are offered, the circuit section 10b has that thinner than the battery section 20 is.

18 shows an orientation of the plurality of battery cells 21 in the battery unit 20 , The battery cells 21 that are shown in the earlier drawings are vertical on the pad 20m arranged. The variety of battery cells 21 can be lateral to the pad 20m be arranged.

Also in this case is the positive connection 20p the battery unit 20 on the interface 20m arranged. The positive connection 20p and the negative connection 20n the battery unit 20 can in any positions on the interface 20m be arranged.

19 shows an orientation of the battery unit 20 in the battery device 10. The connection direction TMD of the battery cells 21 shown in the earlier drawings is coincident with the depth direction DD. In other words, the thickness direction TH is perpendicular to the connection direction TMD. Instead, the thickness direction TH may coincide with the connection direction TMD. In 19 are the electrical circuit 50 and the connection component 80 shown. The substrate 51 may be a flat surface that is parallel to an area of the battery pack 20 expands.

In the battery unit 20 is the interface 20m the upper surface. The connection surface 20m prescribes the first virtual plane VP1. The bottom surface opposite to the pad 20m prescribes the second virtual level VP2. The battery unit 20 is arranged such that the pad 20 m faces the thickness direction TH.

Both ends of the connecting component 80 in the connection direction TMD, the virtual plane VP3, which is at a right angle to the connection direction TMD, and the fourth virtual plane VP4, which is at a right angle to the connection direction TMD, write. The connection component 80 is shaped to from above the pad 20m around to a side surface facing the width direction WD or the depth direction DD. The connection component 80 extends from the pad 20m over an edge portion or corner portion near the positive terminal 20p the battery unit 20 to one of the side surfaces. The positive connection 20p the battery unit 20 is in an edge portion or corner portion of the pad 20m arranged. That's why the interface is 20m adjacent to other two side surfaces on two sides near the positive terminal 20p the battery unit 20 , The switching component 53 is arranged over these two side surfaces. Therefore, the switching component 53 over the two side surfaces in the width direction WD or the depth direction DD adjacent to the land 20m on the sides adjacent to the positive terminal 20p the battery unit 20 arranged. The switching component 53 is near the positive connection 20p the battery unit 20 arranged. The connection member 80 extends between the first virtual plane VP1 and the second virtual plane VP2 from the outer side of the first virtual plane VP1 and the second virtual plane VP2.

In the example that is in 19 is shown, is the third virtual plane VP3 between the top surface, which is the pad 20m is, and the bottom surface. In other words, the third virtual plane VP3 is between two surfaces which are opposite to each other in the thickness direction TH. In other words, the third virtual plane VP3 is between the first virtual plane VP1 and the second virtual plane VP2. The fourth virtual plane VP <b> 4 is a flat surface at a maximum protruding portion of the connection member 80 from the terminal surface 20m projects. Therefore, the fourth virtual plane VP4 is farther toward the outer side than the pad 20m positioned.

The electrical circuit 50 is arranged between the first virtual level VP1 and the second virtual level VP2. The substrate 51 is arranged between the first virtual level VP1 and the second virtual level VP2. The substrate 51 has a flat surface which is at a right angle to the thickness direction TH. However, the substrate has 51 a flat surface which is at a right angle to the connecting direction TMD. The switching component 53 is arranged between the first virtual level VP1 and the second virtual level VP2. At least part of the substrate 51 is disposed between the third virtual plane VP3 and the fourth virtual plane VP4. At least part or a portion of the switching component 53 is disposed between the third virtual plane VP3 and the fourth virtual plane VP4. Preferably, an entirety of the switching component 53 between the virtual plane VP3 and the fourth virtual plane VP4.

As described above, according to the present embodiment, the thin battery device 10 intended. The battery unit 20 and the switching component 53 are arranged so as not to overlap in the thickness direction TH. The battery unit 20 and the switching component 53 are arranged to be aligned in one or both of the width direction WD and the depth direction DD. As a result, the switching component 53 be housed within the thickness, which is to accommodate the battery unit 20 is provided.

In addition, the battery section 10a for accommodating the battery unit 20 and the circuit portion 10b for accommodating the switching component 53 be formed. The circuit section 10b is thinner than the battery section 10a , A shape like this allows the battery device 10 to be arranged in the gap in the vehicle.

Further, when the electrical circuit 50 that is a substrate 51 comprising, on which the plurality of electrical components 52 in addition to the component 53 is mounted, provided are the battery unit 20 and the electrical circuit 50 arranged so as not to overlap in the thickness direction. The battery unit 20 and the electrical circuit 50 are arranged to be aligned in the width direction WD or the depth direction DD. As a result, the thin battery device becomes 10 intended.

In addition, the electrical circuit 50 and the connection component 80 disposed between the first virtual level VP1 and the second virtual level VP2. As a result, the electrical circuit 50 and the connection component 80 be housed within the thickness, which is the battery unit 20 allows to be accommodated. In addition, the circuit section 10b for accommodating the electrical circuit 50 thinner than the battery section 10a for harboring the battery unit 20 , Therefore, the battery device 10 that has a thin section thinner than the battery pack 20 is to be provided. As a result, mounting in various columns becomes possible.

Second Embodiment

A second embodiment is a modification example based on the foregoing embodiment. According to the embodiment described above, the electric circuit 50 in an intermediate position or an intermediate position of the battery unit 20 arranged in the thickness direction TH. Instead, the electrical circuit 50 in a lower portion position of the battery unit 20 arranged in the thickness direction TH.

As in 20 is shown, the seat ST1 has a large projection portion projecting downward. As a result of the electrical circuit 50 Located in the lower section position, the battery device 10 can be arranged in the gap between the seat ST1 and the floor ST2. The electrical circuit 50 is arranged between the first virtual level VP1 and the second virtual level VP2. The connection component 80 has a busbar 281 and a busbar 282 , At least part of the connection component 80 is arranged between the first virtual level VP1 and the second virtual level VP2. As a result of this Configuration, the battery device can 10 be arranged in the gap in the vehicle.

Third Embodiment

A third embodiment is a modification example based on the foregoing embodiment. According to the third embodiment, the electric circuit 50 in an upper portion position and a position of an upper portion of the battery unit, respectively 20 arranged in the thickness direction TH.

As in 21 is shown, the bottom ST2 has a large projecting portion and a portion projecting largely. As a result of the electrical circuit 50 placed in the upper section position, the battery device 10 be arranged in the gap between the seat ST1 and the floor ST2. The electrical circuit 50 is arranged between the first virtual level VP1 and the second virtual level VP2. The connection component 80 has a busbar 381 and a busbar 382 , The entire connection component 80 is arranged between the first virtual level VP1 and the second virtual level VP2. As a result of this configuration, the battery device 10 be arranged in the gap in the vehicle. A relatively large cavity is under the heat dissipation wall 35 educated. Therefore, heat dissipation is promoted by the electric circuit 50. In addition, the electrical circuit 50 protected from moisture.

Fourth Embodiment

A fourth embodiment is a modification example based on the foregoing embodiment. According to the preceding embodiment, the positive terminal or the positive pole 20p the battery unit 20 arranged in the corner portion in the lower portion of the battery unit. Instead, the positive connection can be 20p the battery unit 20 in the upper portion of the battery pack 20 be arranged.

As in 22 shown has the battery unit 20 the positive connection 20p in the upper section. The positioning of the positive connection 20p is through the battery unit 20 realized, which is turned. The connection component 80 has a busbar 481 and a busbar 482 , The entire connection component 80 is arranged between the first virtual level VP1 and the second virtual level VP2. The electrical circuit 50 is in a position near the positive terminal 20p the battery unit 20 in the thickness direction TH of the battery unit 20 arranged. As a result, a short connection component 80 can be used even when the electric circuit 50 is disposed in the upper section position.

Fifth Embodiment

A fifth embodiment is a modification example based on the foregoing embodiment. According to the foregoing embodiment, at least part of the electric circuit is 50 disposed in the protruding area PRJ20 of the battery unit. Instead, the electrical circuit 50 be arranged outside the projecting portion PRJ20.

23 shows a planar arrangement of the components in the battery device 10th 24 is a cross-sectional view taken along a line F24 - F24 in FIG 23 taken. 24 shows a schematic cross-sectional view to show the arrangement of the components.

As in 23 and 24 is shown is the electrical circuit 50 to the side of the battery unit 20 arranged. The connection component 80 has a single busbar 581 , The busbar 581 has a plate shape. The busbar 581 has a section that with the positive connection 20p the battery unit 20 and a portion connected to the substrate 51.

The electrical circuit 50 and the connection component 80 are between the first virtual level VP1 and the second virtual level VP2. The connection component 80 prescribes the third virtual plane VP3 and the fourth virtual plane VP4. At least a portion of the substrate 51 is disposed between the third virtual plane VP3 and the fourth virtual plane VP4. In other words, the substrate protrudes 51 forward to the front in front of the pad 20m , Consequently, the plate-shaped busbar 581 be used. According to the present embodiment, a thin battery device 10 intended. According to the present embodiment, the battery device is 10 provided a section for accomodating the battery unit 20 and a section thinner than the section for housing the battery unit 20 is.

[Sixth Embodiment]

A sixth embodiment is a modification example based on the foregoing embodiment. According to the preceding embodiment, the connecting member protrudes 80 from the connection surface 20m in front. Instead, the connection component 80 from the connection surface 20m run around to the side surface.

25 shows a planar arrangement of the components in the battery device 10th 26 FIG. 15 is a cross-sectional view taken along a line F26-F26 in FIG 25 taken. 26 shows a schematic cross-sectional view to show the arrangement of the components.

As in 25 and 26 is shown is the electrical circuit 50 to the side of the battery unit 20 arranged. The connection component 80 has a busbar 681 and a busbar 682 , The busbars 681 and 682 have a single curved section or more.

The electrical circuit 50 is arranged between the first virtual level VP1 and the second virtual level VP2. The connection component 80 prescribes the third virtual plane VP3 and the fourth virtual plane VP4. At least part of the substrate 51 is disposed between the third virtual plane VP3 and the fourth virtual plane VP4. According to the present embodiment, the thin battery device becomes 10 intended. According to the present embodiment, the battery device 10 be provided, which has a section for accommodating the battery unit 20 and has a section thinner than the section for accomodating the battery unit 20 is.

Seventh Embodiment

A seventh embodiment is a modification example based on the foregoing embodiment. According to the present embodiment, the positive terminal becomes 20p the battery unit 20 in an upper portion of the battery unit 20 arranged.

27 shows a planar arrangement of the components in the battery device 10th 28 is a cross-sectional view taken along a line F28-F28 in FIG 27 taken. 28 shows a schematic cross-sectional view to show the arrangement of the components.

As in 27 and 28 shown is the positive connection 20p the battery unit 20 in the upper portion of the battery pack 20 arranged. The electrical circuit 50 is in the upper portion in the battery device 10 arranged. The connection component 80 has a busbar 781 and a busbar 782 ,

The electrical circuit 50 is arranged between the first virtual level VP1 and the second virtual level VP2. At least a part of the substrate 51 is arranged between the third virtual plane VP3 and the fourth virtual plane VP4. According to the present embodiment, the circuit portion 10b be provided, which is thin depending on the mounting location. The circuit section 10b is disposed in the upper portion in the height direction HD. Therefore, the electrical circuit 50 protected from moisture. In addition, as a result of the cavity under the circuit section 10b is provided, a heat dissipation from the electrical circuit 50 be encouraged.

[Eighth Embodiment]

An eighth embodiment is a modification example based on the foregoing embodiment. According to the preceding embodiment, the substrate 51 a flat surface that expands in the width direction WD and the depth direction DD. Instead, the substrate can be 51 parallel to any of the surfaces of the battery pack 20 be.

29 shows a planar arrangement of the components in the battery device 10 , 30 is a cross-sectional view taken along a line F30 - F30 in FIG 29 taken. 30 shows a schematic cross-sectional view to show the arrangement of the components.

As in 29 and 30 is shown is the substrate 51 parallel to the pad 20m the battery unit 20 arranged. The connection component 80 has a busbar 881 and a busbar 882 , The bus bars 881 and 882 have a single bent portion or more.

The electrical circuit 50 is arranged between the first virtual level VP1 and the second virtual level VP2. The connection component 80 prescribes the third virtual plane VP3 and the fourth virtual plane VP4. At least part of the electrical circuit 50 is disposed between the third virtual plane VP3 and the fourth virtual plane VP4. The substrate 51 is disposed between the third virtual plane VP3 and the fourth virtual plane VP4. At least part of the switching component 53 is disposed between the third virtual plane VP3 and the fourth virtual plane VP4. According to the present embodiment, the thin battery device becomes 10 intended.

Ninth Embodiment

A ninth embodiment is a modification example based on the foregoing embodiment. According to the foregoing embodiment, the pad is 20m the battery unit 20 oriented in the width direction WD or the depth direction DD. Instead, the battery unit 20 be arranged such that the terminal area 20m is oriented in the thickness direction TH. In other words, the positive terminal or the positive pole 20p the battery unit 20 on the surface of the battery unit 20 arranged facing the thickness direction TH.

31 shows a planar arrangement of the components in the battery device 10th 32 is a cross section taken along a line F32 - F32 in FIG 31 taken. 32 shows a schematic cross-sectional view to show the arrangement of the components.

As in 31 and 32 is shown in the battery unit 20 the connection surface 20m oriented in the thickness direction TH. The connection surface 20m is oriented in the upward direction in the direction of gravity. The connection surface 20m may also be oriented in the downward or downward direction. The connection component 80 has a bus bar 981 and a bus bar 982 , The busbars 981 and 982 have a single bent section or several. The connection component 80 runs approximately from the connection surface 20m to the side of the battery unit 20 ,

The electrical circuit 50 is arranged between the first virtual level VP1 and the second virtual level VP2. The connection component 80 prescribes the third virtual plane VP3 and the fourth virtual plane VP4. The electrical circuit 50 is disposed between the third virtual plane VP3 and the fourth virtual plane VP4. According to the present embodiment, the battery device is 10 provided a section for accomodating the battery unit 20 and has a section thinner than the section for accomodating the battery unit 20 is. The thin section may be used to connect the electrical circuit 50 to accommodate.

[Tenth Embodiment]

A tenth embodiment is a modification example based on the foregoing embodiment. According to the present embodiment, the substrate 51 parallel to a side surface of the battery unit 20 intended.

33 shows a planar arrangement of the components in the battery device 10th 34 is a cross-sectional view taken along a line F34-F34 in FIG 33 taken. 34 shows a schematic cross-sectional view to show the arrangement of the components.

As in 33 and 34 is shown has the connecting member 80 a busbar A81. The busbar A81 has a single bent portion or more. The connection component 90 extends from the land 20m through a corner portion near the positive terminal 20p the battery unit 20 to the side of the battery unit 20 out. According to the present embodiment, the thin battery device is 10 intended.

[Eleventh Embodiment]

An eleventh embodiment is a modification example based on the foregoing embodiment. According to the above-described embodiments, the connecting member is 80 provided by busbars. Instead, the connection component 80 be provided by various electrical connection components. According to the present embodiment, an electric wire B81 is formed in a portion of the connection member 80 used.

35 is a schematic cross-sectional view of the battery device 10 , 35 shows a schematic cross-sectional view to show the arrangement of the components. The connection component 80 has the lead wire and the electric wire B81, respectively. For example, the electric wire B81 is provided by a multi-strand wire capable of conducting a large current. A welded terminal or a crimped terminal suitable for connection to a terminal may be provided at each end of the electric wire B81. For example, the positive connection 20p the battery unit 20 and the electric wire B81 is connected by welding. The electrical connection is made by a variety of connection structures, such. B. a weld and a fixture provided. The connection component 80 has busbar B82 attached to the substrate 51 is fixed, and a fastening member B83. The busbar B82 is also a nut member made of metal. In this way, several or more components may be referred to as a busbar. The bus bar B82 and the fixing member B83 are used to form the electric wire and the electric wire B81 and the substrate, respectively 51 connect to.

Also according to the present embodiment, the electric circuit is 50 disposed between the first virtual level VP1 and the second virtual level VP2. In addition, the electrical circuit 50 is arranged between the third virtual level VP3 and the fourth virtual level VP4. At least part of the connection component 80 is arranged between the first virtual level VP1 and the second virtual level VP2. Also according to the present embodiment For example, effects similar to those according to the foregoing embodiment can be achieved.

Twelfth Embodiment

A twelfth embodiment is a modification example based on the foregoing embodiment. According to the embodiments described above, the switching component 53 on or on the substrate 51 assembled. Instead, the switching component 53 separately from the substrate 51 be.

36 is a schematic cross-sectional view of the battery device 10 , A part of the electrical circuit or the electrical circuit 50 is on the substrate 51 assembled. For example, the substrate 51 at the monitoring terminal or monitoring connection 27 connected or connected. In this case, a monitoring circuit that is at least the voltages of the plurality of battery cells 21 monitors, on the substrate 51 assembled. A control circuit or a control circuit, which is the switching component 53 controls, can be on the substrate 51 be mounted.

The switching component 53 is provided by an element acting as a switching module 54 referred to as. The switching module 54 houses the switching component 53. The switching module 54 has at least two electrical power terminals or two current terminals to conduct the current which is connected and disconnected by the switching component 53. The power terminals extend to the battery unit 20 out. The power terminals are connected to the bus bar C81, which serves as the connection component 80 serves. In addition, the switching module has 54 a control terminal or a control terminal for controlling the switching component 53 , The control connection extends from the switching module 54 to the substrate 51 out. The control terminal is connected to the substrate 51. The control terminal is connected to the control circuit.

The switching component 53 that generates a relatively large amount of heat is from the substrate 51 separated and is therefore thermally advantageous to the electrical circuit 50 , In addition, a large current becomes easier by using the switching module 54 controlled. Further, the switching component 53 by an electrical component, such as. As a relay, be provided instead of the semiconductor switching element. According to the present embodiment, the thin battery device is 10 provided while thermal effects are suppressed by the switching component 53 caused.

Thirteenth Embodiment

A thirteenth embodiment is a modification example based on the foregoing embodiment. According to the embodiment described above, the L-shaped substrate becomes 51 used. Instead, the substrate can be 51 be provided by a plurality of substrates D54 and D55.

37 is a perspective view of the battery device 10 , The battery device 10 has the electrical circuit 50 , The electrical circuit 50 has a circuit for a large current, which is the switching component 53 and a control circuit for the switching component 53 having. The electrical circuit 50 has the first substrate D54 and the second substrate D55. The switching component 53 is mounted on the first substrate D54. The first substrate D54 has a circuit through which the current of the battery unit 20 flows. For example, a current of several hundred amperes may be sent relative to a voltage of 12 volts used in vehicles. The control circuit or the control circuit for the switching component 53 is mounted on the second substrate D55. For example, a current of several milliamps may be sent relative to a voltage of 5 volts for a semiconductor control circuit. A plurality of lead wires D56 are provided between the first substrate D54 and the second substrate D55. A connection between the plurality of lead wires D56 and the first substrate D54 and the plurality of lead wires D56 and the second substrate D55 can be achieved by soldering or by using terminals.

According to the present embodiment, the substrate on which the switching component 53 is mounted, near the pad 20m the battery unit 20 to be ordered. Therefore, the path can be shortened over which a relatively large current flows. In addition, since the switching component 53 and the like generate a large amount of heat, components that generate a large amount of heat may be concentrated on the first substrate D54.

Fourteenth Embodiment

A fourteenth embodiment is a modification example based on the foregoing embodiment. According to the embodiment described above, the electric circuit 50 disposed within the battery device 10. Instead, an electric circuit 90 used outside the battery device 10 is provided.

38 is a perspective view of the battery device 10 , The battery device 10 has the electrical circuit 50 , The electrical circuit 50 has the substrate 51 on, on which the switching component 53 is mounted. In addition, a battery system according to the present embodiment has a separate electric circuit E90. The electrical circuit E90 is in a separate housing from the battery device 10 houses. For example, the electrical circuit E90 is an electrical control unit. The electrical circuit 50 and the electric circuit E90 are connected by a plurality of lead wires E91. The connection between the plurality of lead wires E91 and the substrate 51 and the plurality of lead wires E91 and the electric circuit E90 can be achieved by soldering or by use of plugs.

According to the present embodiment, at least the switching component 53 is in the electrical circuit 50 contain. The switching component 53 is on the substrate 51 assembled. The electrical circuit E90 has at least the control circuit or the control circuit for the switching component 53 on. According to the preceding embodiment, the substrate on which the switching component 53 is mounted, near the pad 20m the battery unit 20 to be ordered. Therefore, the path can be shortened over which a relatively large current flows. In addition, since the control circuit is designed as the separate electric circuit E90, various arrangements in the vehicle become possible. Furthermore, maintenance is simplified, such. B. an exchange of the electrical circuit E90.

Other Embodiments

The disclosure of the present specification is not limited to the embodiments given as examples. The disclosure includes the embodiments given by way of example and variations made by those skilled in the art based on the embodiments. For example, the disclosure is not limited to the combinations of one or both of components and elements described in accordance with the embodiments. Various combinations may be used to carry out the embodiments given as examples. The disclosure may include additional portions added to the embodiments. The disclosure includes one or both of components and elements that have been omitted. The disclosure includes substitutions and combinations of one or both of components and elements between a single embodiment and another embodiment. The technical scope of protection disclosed are not limited to the descriptions according to the embodiments. Some of the technical scope of protection disclosed are set forth in the claims and should be interpreted as including further meanings that are equivalent to the terms in the claims and all modifications of the claims.

According to the embodiments described above, the switching component 53 provided by a semiconductor switching element. In these cases, a semiconductor switch connects the flow of input and output currents of the battery pack 20 and separate them. Instead, as described in accordance with some embodiments, an electromagnetic relay may be used. In this case, the flow of input and output currents of the battery unit becomes 20 connected and disconnected by the electromagnetic relay.

According to the embodiment described above, the electrical circuit 50 a variety of switching components 53 on. Instead, the electrical circuit 50 a single switching component 53 exhibit. In addition, the electrical circuit 50 a switch array in which a plurality of switching components 53 is housed in a collective circuit. The switch panel can be on the substrate 51 be mounted or separate from the substrate 51 being held.

A battery device houses a battery unit and an electrical circuit. The battery unit and the electrical circuit are connected by a connecting member. Two surfaces of the battery unit in a thickness direction prescribe a first virtual plane and a second virtual plane. The electrical circuit is arranged between the first virtual level and the second virtual level. The electric circuit is arranged to the battery unit side in a width direction and a depth direction. Both ends of the connection member prescribe a third virtual plane and a fourth virtual plane with respect to a connection direction of the battery unit. At least part of the electrical circuit is arranged between the third virtual level and the fourth virtual level. A thickness of a battery section housing the battery unit is held down. A circuit portion housing the electrical circuit is thinner than the battery portion.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 5942644 [0002, 0003]

Claims (16)

Battery device comprising a battery unit (20) in which a terminal of a battery cell (21) is disposed on a pad (21m); and a switching component (53) that connects and disconnects a current supplied from the terminal, wherein the battery unit and the switching component are arranged so as not to overlap in a thickness direction (TH) and to be aligned in one or both of a width direction (WD) and a depth direction (DD). Battery device after Claim 1 , further comprising: a housing (11, 30) housing the battery unit, the switching component, and a connection member (80) for electrically connecting the terminal and the switching component, the housing comprising: a battery section (10a) housing the battery unit and a circuit portion (10b) housing the switching component, and the circuit portion being thinner than the battery portion in the thickness direction. Battery device after Claim 2 electric circuit (50) comprising the switching component and a substrate (51) on which a plurality of electrical components (52) are mounted, the circuit portion housing the substrate. Battery device after Claim 3 wherein: the substrate is an L-shaped type aligned with the battery unit in the width direction and the depth direction. Battery device after Claim 3 or 4 wherein: the substrate has a flat surface that is at right angles to the thickness direction. Battery device after Claim 5 wherein: the substrate has a flat surface that expands in a connecting direction (TMD), wherein the connecting direction is a direction in which the terminal is disposed in the battery unit. Battery device after Claim 5 wherein: the substrate has a flat surface that is at right angles to the connection direction (TMD), wherein the connection direction is a direction in which the terminal is disposed in the battery unit. Battery device according to one of Claims 1 to 7 wherein: the switching component is located near the terminal. Battery device according to one of Claims 1 to 8th wherein: the battery unit is arranged such that the pad faces the width direction or the depth direction. Battery device according to one of Claims 1 to 8th wherein: the battery unit is arranged such that the pad faces the thickness direction. Battery device according to one of Claims 1 to 10 wherein: the battery unit is a polyhedron in which two surfaces of the battery unit farthest in the thickness direction prescribe a first virtual plane (VP1) and a second virtual plane (VP2) having the two surfaces; and the switching component is disposed between the first virtual level and the second virtual level. Battery device after Claim 11 wherein: a connecting member (80) for electrically connecting the terminal and the switching component is disposed between the first virtual level and the second virtual level. Battery device after Claim 11 or 12 , further comprising: a heat dissipation wall (35) thermally connected to the switching component and disposed between the first virtual level and the second virtual level. Battery device according to one of Claims 1 to 13 wherein: both ends of a connection member (80) for electrically connecting the terminal and the switching component prescribe a third virtual plane (VP3) and a fourth virtual plane (VP4) which are at right angles to the connection direction (TMD) the connection direction is a direction in which the terminal is provided in the battery unit; and the switching component is disposed between the third virtual level and the fourth virtual level. Battery device after Claim 14 wherein: at least a part of the switching component is disposed within a protrusion area (PRJ20) prescribed by the land protruding in the connecting direction. Battery device after Claim 15 , in which: the switching component is disposed over two areas in the width direction or the depth direction adjacent to the pad on a side adjacent to the terminal.

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