JP2020042918A - Battery pack - Google Patents

Abstract

To provide a battery pack which prevents the entry of dust into a housing space.SOLUTION: A battery 10, a control part, and a connector 27 are each housed in a housing space formed by a housing 91 and a cover 92. The cover has an upper wall 60 and a lateral wall 61 erected from the upper wall 60 to the housing side. The lateral wall has an opening window 63 penetrating an internal face 92a and an external face 92b. The connector can be connected to an external connector 28 via the opening window. The opening window is defined by an annular edge 68. The edge has: an upper edge part 68a and a lower edge part 68b located at a distance from each other in a facing direction of the upper wall and the housing; and a coupling edge part for coupling the upper edge part and the lower edge part. A lower external face 71a located between the lower edge part on the external face and a tip part on the housing side of the lateral wall extends in the facing direction and an opening direction of the opening window in such a manner as to be spaced away from the housing space.SELECTED DRAWING: Figure 6

Description

  The disclosure described herein relates to a battery pack.

  As disclosed in Patent Document 1, there is known a power supply device in which a battery module and a substrate are housed in a housing space formed by an upper case and a lower case.

JP 2018-95125 A

  A connector is mounted on a substrate of a power supply device disclosed in Patent Document 1. A notch for exposing the connector to the outside is formed in the upper cover. This notch is non-annular. For this reason, there is a possibility that dust may enter the storage space (storage space) through the notch.

  Therefore, an object of the disclosure described in this specification is to provide a battery pack in which dust is suppressed from entering a storage space.

One of the disclosures includes a battery (10);
A control unit (22) for controlling battery input / output;
A connector (27) electrically connected to the control unit;
A housing (91) and a cover (92) that form a storage space for storing the battery, the control unit, and the connector by being connected to each other;
The cover has an upper wall (60) opposed to the housing, and a side wall (61) rising from the upper wall toward the housing.
The side wall has an inner surface (92a) defining a part of the storage space, an outer surface (92b) exposed to an external atmosphere, and an open window (63) penetrating the inner surface and the outer surface.
The connector can be connected to the external connector (28) through the opening window,
The opening window is defined by an annular edge (68),
The edge includes an upper edge (68a) located on the upper wall side and a lower edge (68b) located on the housing side in an opposing direction of the upper wall and the housing, and an upper edge and a lower edge. Connecting edges (68c, 68d) connecting the portions,
A lower outer surface (71a) between the lower edge of the outer surface and the front end of the side wall on the casing side extends in a direction away from the storage space in a direction opposite to the opening direction orthogonal to the opening of the opening window.

  Thus, in the present disclosure, the opening window (63) defined by the annular edge (68) is formed in the cover (92). According to this, the intrusion of dust into the storage space through the opening window (63) is suppressed as compared with the configuration in which the opening window is defined by the non-circular edge simply by cutting out a part of the cover. Is done.

  Furthermore, in the present disclosure, the opening direction is such that the lower outer surface (71a) between the lower edge (68b) of the outer surface (92b) of the side wall (61) and the tip of the side wall (61) is separated from the storage space. And in the opposite direction. Therefore, as compared with a configuration in which the lower outer surface simply extends in the opposite direction, the length between the lower edge (68b) and the distal end of the lower outer surface (71a) is longer. Thereby, the resistance force acting on the dust flowing from the front end side toward the opening window (63) along the lower outer surface (71a) increases. As a result, the intrusion of dust flowing along the lower outer surface (71a) from the distal end toward the opening window (63) into the storage space through the opening window (63) is suppressed.

  It should be noted that the reference numbers in parentheses described above merely indicate the correspondence with the configurations described in the embodiments described below, and do not limit the technical scope at all.

It is a block diagram showing a power supply system. FIG. 3 is an exploded perspective view of the front side of the battery pack. FIG. 3 is an exploded perspective view of the back side of the battery pack. It is a perspective view of the back side of a battery pack. It is a rear view of a battery pack. FIG. 6 is a sectional view taken along the line VI-VI in FIG. 5. It is a chart showing a modification of a cover. 4 is a chart for explaining a definition part. 6 is a diagram for explaining how to attach the cover to the housing.

  Hereinafter, embodiments will be described with reference to the drawings.

(1st Embodiment)
A battery pack 100 according to the present embodiment and a power supply system 200 including the same will be described with reference to FIGS.

<Overview of power supply system>
The power supply system 200 is mounted on a vehicle. The power supply system 200 includes a plurality of in-vehicle devices mounted on a vehicle and the battery pack 100. A lead storage battery 110 is one of the in-vehicle devices. The battery pack 100 has an assembled battery 10. The power supply system 200 configures a two-power supply system with the lead storage battery 110 and the assembled battery 10.

  An engine 140 is another on-vehicle device. The vehicle equipped with the power supply system 200 has an idle stop function that stops the engine 140 when a predetermined stop condition is satisfied and restarts the engine 140 when a predetermined start condition is satisfied.

  As shown in FIG. 1, the power supply system 200 includes a starter motor 120, a rotating electric machine 130, an electric load 150, a host ECU 160, and an MGECU 170 in addition to the lead storage battery 110 and the engine 140 described above. Each of the lead storage battery 110, the starter motor 120, and the electric load 150 is electrically connected to the battery pack 100 via the first wire harness 210. The rotating electric machine 130 is electrically connected to the battery pack 100 via the second wire harness 220.

  Upper ECU 160 and MGECU 170 are electrically connected to lead storage battery 110 and battery pack 100, respectively. Similarly, other various ECUs mounted on the vehicle are electrically connected to the lead storage battery 110 and the battery pack 100, respectively. These ECUs are electrically connected to a lead storage battery 110 via a battery pack 100.

  As described above, the power supply system 200 constructs a two-power supply system using two power sources, the lead storage battery 110 and the battery pack 100 (assembled battery 10).

<Components of power supply system>
The lead storage battery 110 generates an electromotive voltage by a chemical reaction. The lead storage battery 110 has a larger storage capacity than the battery pack 10.

  Starter motor 120 starts engine 140. Starter motor 120 is mechanically connected to engine 140 when engine 140 is started. The rotation of the starter motor 120 causes the crankshaft of the engine 140 to rotate. When the rotation speed of the crankshaft exceeds a predetermined rotation speed, atomized fuel is injected from the fuel injection valve into the combustion chamber. At this time, a spark is generated by the spark plug. As a result, the fuel explodes, and the engine 140 starts to rotate autonomously. The propulsion of the vehicle is obtained by the power of the engine 140. When the engine 140 starts to autonomously rotate, the mechanical connection between the starter motor 120 and the engine 140 is released.

  The rotating electric machine 130 performs power running and power generation. A power converter (not shown) is connected to the rotating electric machine 130. This power converter is electrically connected to the second wire harness 220.

  The power converter converts a DC voltage supplied from at least one of the lead storage battery 110 and the battery pack 10 of the battery pack 100 to an AC voltage. This AC voltage is supplied to rotating electric machine 130. Thus, the rotating electric machine 130 runs power.

  The rotating electric machine 130 is connected to the engine 140. The rotating electric machine 130 and the engine 140 can mutually transmit rotational energy via a belt or the like. Rotational energy generated by the power running of the rotating electric machine 130 is transmitted to the engine 140. Thereby, rotation of engine 140 is promoted. As a result, vehicle running is assisted. As described above, the vehicle equipped with the power supply system 200 has an idle stop function. The rotating electric machine 130 not only assists in running the vehicle, but also functions to rotate the crankshaft when the engine 140 is restarted.

  The rotary electric machine 130 also has a function of generating power by at least one of the rotational energy of the engine 140 and the rotational energy of the wheels of the vehicle. The rotating electric machine 130 generates an AC voltage by power generation. This AC voltage is converted into a DC voltage by the power converter. This DC voltage is supplied to each of the battery pack 100, the lead storage battery 110, and the electric load 150.

  Engine 140 generates propulsion of the vehicle by burning and driving fuel. As described above, when the engine 140 is started, the crankshaft is rotated by the starter motor 120. However, when the engine 140 is once stopped by the idle stop and then restarted, the rotating electric machine 130 rotates the crankshaft when the above-described predetermined starting condition is satisfied.

  The electric load 150 has a general load 151 and a protection load 152. The general load 151 includes in-vehicle devices, such as a seat heater, a blower fan, an electric compressor, a room light, and a headlight, for which supply power may not be constant. The protection load 152 includes an electric shift position, an electric power steering (EPS), a brake (ABS), a door lock, a navigation system, and an on-vehicle device that requires a constant supply power such as an audio. The protection load 152 exemplified here has a property of switching from the on state to the off state when the supply voltage falls below the reset threshold. The protection load 152 includes in-vehicle devices that are more relevant to vehicle running than the general load 151.

  The configuration in which the above-described various in-vehicle devices are included in the general load 151 and the protection load 152 is merely an example. Various in-vehicle devices can be appropriately allocated to the general load 151 and the protection load 152 according to a change in the in-vehicle system. For example, a configuration in which the general load 151 includes EPS or ABS can be adopted.

  The host ECU 160 and the MGECU 170 are one of various ECUs mounted on the vehicle. These various ECUs are electrically connected to each other via a bus wiring 161 to form a vehicle-mounted network. The various ECUs perform the cooperative control to control the combustion of the engine 140, the power running and the power generation of the rotary electric machine 130, and the like. The host ECU 160 controls the battery pack 100. MGECU 170 controls rotating electric machine 130.

  Although not shown, the power supply system 200 includes, in addition to the above-described on-vehicle devices, sensors for measuring physical quantities such as various voltages and currents and vehicle information such as an accelerator pedal depression amount and a throttle valve opening. Have. Detection signals detected by these various sensors are input to various ECUs.

  ECU is an abbreviation of electronic control unit. The ECU has at least one arithmetic processing unit (CPU) and at least one memory device (MMR) as a storage medium for storing programs and data. The ECU is provided by a microcomputer having a computer-readable storage medium. The storage medium is a non-transitional substantial storage medium that temporarily stores a computer-readable program. The storage medium can be provided by a semiconductor memory or a magnetic disk or the like.

<Overview of Battery Pack>
As shown in FIG. 1, the battery pack 100 includes a battery pack 10, a circuit board 20, a switch 30, a sensor unit 40, and a power supply bus bar 50. As shown in FIG. 2, the battery pack 100 has a pack case 90. In FIG. 2, the illustration of the sensor unit 40 and the power supply bus bar 50 is omitted.

  The battery pack 10 is smaller in size and lighter in weight than the lead storage battery 110. The battery pack 10 has a higher energy density than the lead storage battery 110.

  The circuit board 20 has a wiring board 21 and a BMU 22. A part of the switch 30 and the BMU 22 are mounted on the wiring board 21. The rest of the switch 30 and the battery pack 10 are electrically connected to the wiring board 21 via the power supply bus bar 50. Thus, an electric circuit of the battery pack 100 is configured. The sensor unit 40 is electrically connected to this electric circuit via an insulated wire or the like.

  The electric circuit of the battery pack 100 is electrically connected to an external connection terminal indicated by a double circle in FIG. The external connection terminals include a first external connection terminal 100a, a second external connection terminal 100b, a third external connection terminal 100c, a fourth external connection terminal 100d, and a fifth external connection terminal 100e.

  The first external connection terminal 100a, the fourth external connection terminal 100d, and the fifth external connection terminal 100e are electrically connected to the lead storage battery 110, the starter motor 120, and the electric load 150 via the first wire harness 210, respectively. Have been. The second external connection terminal 100b is electrically connected to the rotating electric machine 130 via the second wire harness 220. The third external connection terminal 100c is connected to a vehicle body via a bolt or a wire harness. As a result, the battery pack 100 is grounded to the body.

  As shown in FIG. 1, the first wire harness 210 is divided into one for connecting the lead storage battery 110, the starter motor 120 and the general load 151, and one for connecting the protection load 152. The end of the first wire harness 210 that connects the lead storage battery 110, the starter motor 120, and the general load 151 is bifurcated. One of the forked ends is connected to the first external connection terminal 100a, and the other is connected to the fifth external connection terminal 100e. An end of the first wire harness 210 for connecting the protection load 152 is connected to the fourth external connection terminal 100d.

  The pack case 90 has a housing 91 and a cover 92. The housing 91 and the cover 92 form a storage space. In this storage space, the battery pack 10, the circuit board 20, the switch 30, the sensor unit 40, and the power supply bus bar 50 are stored.

<Components of battery pack>
Next, components of the battery pack 100 will be described individually. In doing so, the three directions that are orthogonal to each other will be referred to as the x direction, the y direction, and the z direction. The x direction is along the left-right direction of the vehicle. The z direction is along the vertical direction of the vehicle. When the vehicle is stopped on a horizontal plane, the z direction is along the vertical direction. The x direction and the y direction are along the horizontal direction. The x direction corresponds to the cross direction. The y direction corresponds to the opening direction. The z direction corresponds to the facing direction.

  The battery pack 10 includes a plurality of battery cells connected in series and a battery case 11 for housing the plurality of battery cells. These plurality of battery cells are specifically lithium ion secondary batteries. Lithium ion secondary batteries generate an electromotive voltage by a chemical reaction. A current flows through the battery cell due to the generation of the electromotive voltage. As a result, the battery cells generate heat and generate gas. Therefore, the battery cell expands. The battery cell is not limited to the above example. For example, as the battery cell, a secondary battery such as a nickel hydride secondary battery or an organic radical battery can be employed.

  The battery cell has a rectangular parallelepiped shape. The battery cell has two main surfaces facing in the z direction. These two main surfaces are larger in area than the other four surfaces. The length (thickness) between the two main surfaces is reduced. As described above, the battery cell has a flat shape with a small thickness in the z direction.

  The battery pack 10 of the present embodiment has five battery cells. Three of these five battery cells are stacked and arranged in the z direction to form a first battery stack. The remaining two battery cells are stacked and arranged in the z direction to form a second battery stack. These two battery stacks are arranged in the x direction. The arrangement of these five battery cells is held by the battery case 11.

  The battery case 11 has a main body made of resin and connection terminals provided on the main body. As the connection terminal, there is a series connection terminal for connecting five battery cells in series. These series connection ends are brought into contact with the corresponding electrode terminals of the battery cells, and the two are welded together in the contact state. Thereby, five battery cells are connected in series.

  As the connection terminals, in addition to the series connection terminals, the output terminal 12 connected to the positive terminal of the battery cell located at the highest potential among the five series-connected battery cells, and the output terminal 12 located at the lowest potential And a ground terminal 13 connected to the negative terminal of the battery cell. This output terminal 12 is welded to the positive terminal of the battery cell having the highest potential. The ground terminal 13 is welded to the negative electrode terminal of the lowest potential battery cell.

  The battery case 11 has a hole 11a for passing a bolt. A bolt hole 91 a for fastening a bolt is formed in the housing 91 of the pack case 90. A bolt is passed through the hole 11a and the bolt hole 91a, and the bolt is fastened to the bolt hole 91a. Thus, the battery case 11 is fixed to the housing 91.

  The battery case 11 is also fixed to the housing 91 by a restraining plate 96 shown in FIG. The restraint plate 96 faces the housing 91 via the battery pack 10 in the z direction. A notch for passing a bolt is formed in the restraining plate 96. A bolt hole 91b for fastening a bolt is formed in the housing 91. A bolt is passed through the notch and the bolt hole 91b, and the bolt is fastened to the bolt hole 91b. Thus, the constraint plate 96 is fixed to the housing 91. The expansion of the battery case 11 due to the expansion of the battery cells is suppressed by the restraint plate 96.

  As described above, the circuit board 20 includes the wiring board 21 and the BMU 22. The wiring board 21 is a printed board in which a wiring pattern made of a conductive material is formed on an insulating substrate. A first power supply line 23, a second power supply line 24, and a third power supply line 25 are formed as wiring patterns on at least one of the surface and the inside of the insulating substrate.

  A conductive plate (not shown) is fixed to the wiring board 21. Bolt holes are formed in the conductive plate. A bolt is passed through the bolt hole of the conductive plate. This bolt is fixed to the housing 91. Thus, the wiring board 21 is mechanically and electrically connected to the housing 91.

  The housing 91 is connected to the ground potential. Therefore, the conductive plate of the wiring board 21 is connected to the ground potential. The BMU 22 mounted on the wiring board 21 uses the potential of the conductive plate as a reference potential.

  The wiring board 21 (circuit board 20) is provided between the battery case 11 and the cover 92 in the z direction. The wiring board 21 is provided alongside the battery cell having the highest potential in the x direction. That is, the wiring board 21 is provided in the x direction along with the battery cell positioned closest to the cover 92 of the first battery stack.

  Terminals that are electrically connected to the wiring pattern are formed on the wiring board 21. The terminals include a first internal terminal 26a, a second internal terminal 26b, a third internal terminal 26c, and a fourth internal terminal 26d. The wiring board 21 is provided with a connector 27 shown in FIG. The connector 27 includes the fifth external connection terminal 100e. The fifth external connection terminal 100e is also electrically connected to the wiring pattern. The electrical connection between these wiring patterns and the internal terminals and the fifth external connection terminals 100e will be described later in the description of the circuit configuration of the battery pack 100.

  The connector 27 also has a function of connecting the BMU 22 and the bus wiring 161 shown in FIG. The connector 27 has a function of inputting and outputting a later-described command signal, determination signal, and the like. An external connector 28 shown in FIG. The insertion / removal direction of the external connector 28 is along the y direction.

  The switch 30 includes a first switch 31, a second switch 32, a third switch 33, a fourth switch 34, a fifth switch 35, and a sixth switch 36. The first switch 31 and the second switch 32 are mounted on the housing 91. Each of the third switch 33 and the fourth switch 34 and the fifth switch 35 and the sixth switch 36 are mounted on the wiring board 21.

  Each of the first switch 31 to the fourth switch 34 has a semiconductor switch. This semiconductor switch is specifically an N-channel MOSFET. Therefore, each of the first switch 31 to the fourth switch 34 is closed by the input of the high-level control signal. Each of the first switch 31 to the fourth switch 34 is opened when a low-level control signal is input.

  An IGBT or the like can be used as a semiconductor switch of the first switch 31 to the fourth switch 34. In this case, a diode is connected to the IGBT in parallel.

  Each of the fifth switch 35 and the sixth switch 36 is a mechanical relay. More specifically, each of the fifth switch 35 and the sixth switch 36 is a normally closed electromagnetic relay. Therefore, each of the fifth switch 35 and the sixth switch 36 is opened by the input of the high-level control signal. Each of the fifth switch 35 and the sixth switch 36 is closed by inputting a low-level control signal. In other words, each of the fifth switch 35 and the sixth switch 36 is closed when the input of the high-level control signal is interrupted.

  Each of the first switch 31 to the fourth switch 34 has at least one opening / closing unit in which two MOSFETs are connected in series. These two MOSFETs have their source electrodes connected to each other. The gate electrodes of the two MOSFETs are electrically independent. The MOSFET has a parasitic diode. The anodes of the parasitic diodes of the two MOSFETs are connected to each other. The gate electrode is electrically connected to the circuit board 20.

  The first switch 31 and the second switch 32 have a plurality of open / close units. The plurality of opening / closing sections are connected in parallel.

  The third switch 33 has one opening / closing unit. The fourth switch 34 has a plurality of open / close units. The plurality of open / close sections of the fourth switch 34 are connected in series. Note that a configuration in which at least one of the third switch 33 and the fourth switch 34 has a plurality of open / close sections, and the plurality of open / close sections are connected in parallel may be adopted.

  FIG. 1 shows two open / close sections of the first switch 31 and the second switch 32 which are connected in parallel. Two open / close sections of the fourth switch 34 connected in series are shown. The number and connection form of these open / close sections can be appropriately determined according to the amount of current, redundancy, and the like.

  A larger amount of current flows through the first switch 31 and the second switch 32 than the third switch 33 to the sixth switch 36 on a time average basis. Therefore, as described above, the first switch 31 and the second switch 32 have a configuration in which a plurality of open / close units are connected in parallel.

  As described above, the sensor unit 40 is electrically connected to the electric circuit. The sensor unit 40 has a sensor element that detects the state of each of the battery pack 10 and the switch 30. The sensor unit 40 has a temperature sensor, a current sensor, and a voltage sensor as sensor elements.

  The sensor unit 40 detects the temperature, the current, and the voltage of the battery pack 10. The sensor unit 40 outputs it to the BMU 22 as a state signal of the battery pack 10. The sensor unit 40 detects the temperature, the current, and the voltage of the switch 30. The sensor unit 40 outputs this to the BMU 22 as a state signal of the switch 30.

  Note that the sensor unit 40 has a submergence sensor in addition to the various sensors described above. This submerged sensor has two counter electrodes. If there is water between the two opposing electrodes, the two opposing electrodes conduct electricity. Thereby, the resistance value between the two opposing electrodes changes. This change in the resistance value is input to the BMU 22 as a state signal. The BMU 22 detects submersion of the battery pack 100 based on whether or not the change in the resistance value continues for a predetermined time.

  The BMU 22 controls the switch 30 based on at least one of a state signal of the sensor unit 40 and a command signal from the host ECU 160. BMU is an abbreviation for battery management unit. The BMU 22 corresponds to a control unit.

  As described above, each of the first switch 31 to the fourth switch 34 has a plurality of semiconductor switches. For example, when controlling the opening and closing of the first switch 31, the BMU 22 controls all the semiconductor switches of the first switch 31 to be simultaneously closed or open. That is, the BMU 22 simultaneously outputs a high-level control signal or a low-level control signal to the gate electrodes of all the semiconductor switches included in the first switch 31.

  The BMU 22 may adjust the closing time of the semiconductor switch by intermittently outputting a high-level control signal during the period in which the semiconductor switch is closed. Briefly, the BMU 22 may control the pulse width of the semiconductor switch.

  The BMU 22 determines the state of charge (SOC) of the battery pack 10 and the abnormality of the switch 30 based on the state signal of the sensor unit 40. SOC is an abbreviation for state of charge. The BMU 22 outputs a signal (determination information) for determining the SOC and the abnormality to the host ECU 160.

  The host ECU 160 determines the control of the switch 30 based on the determination information input from the BMU 22 and the vehicle information input from other various ECUs. Then, host ECU 160 outputs a command signal including the determined control of switch 30 to BMU 22.

  The BMU 22 controls the switch 30 based on a command signal from the host ECU 160. However, when the BMU 22 determines that the battery pack 100 is submerged by the status signal of the submergence sensor, the BMU 22 arbitrarily stops outputting the control signal to the switch 30. Thus, the electrical connection of the battery pack 10 is cut off.

  When the BMU 22 determines that the temperature of the switch 30 has risen to about the operation guarantee temperature, the BMU 22 limits the driving of the switch 30. For example, when the pulse width control of the semiconductor switch of the switch 30 is performed, the BMU 22 lowers its on-duty ratio. This shortens the energization time of the semiconductor switch. As a result, heat generation of the semiconductor switch is suppressed.

  The power supply bus bar 50 is made of a conductive material such as aluminum or copper. The power supply bus bar 50 can be manufactured, for example, by the methods listed below. The power supply bus bar 50 can be manufactured by bending a single flat plate. The power supply bus bar 50 can be manufactured by integrally connecting a plurality of flat plates. The power supply bus bar 50 can be manufactured by welding a plurality of flat plates. The power supply bus bar 50 can be manufactured by pouring a molten conductive material into a mold. The power supply bus bar 50 can be manufactured by a manufacturing method different from the manufacturing methods listed above. The method for manufacturing the power supply bus bar 50 is not particularly limited. Furthermore, for example, an insulated wire may be used as the power supply bus bar 50.

  The battery pack 100 has a first power supply bus bar 51, a second power supply bus bar 52, a third power supply bus bar 53, and a fourth power supply bus bar 54 as the power supply bus bar 50. The circuit board 20 and the battery pack 10 and the circuit board 20 and the external connection terminals are electrically connected by the plurality of power supply bus bars. In FIG. 1, each of the power supply bus bars is shown thicker than the power supply lines of the wiring board 21.

  Although not shown, the first power supply bus bar 51 to the third power supply bus bar 53 are housed in a bus bar case made of an insulating resin material. This busbar case is fixed to the housing 91 by bolts or the like.

  As described above, the pack case 90 has the housing 91 and the cover 92. The housing 91 can be manufactured by aluminum die casting. The housing 91 can also be manufactured by pressing iron or stainless steel. The housing 91 has higher heat transfer performance than the wiring board 21. Therefore, the heat dissipation of the housing 91 is higher than that of the wiring board 21.

  The housing 91 has a bottom wall 93 and a side wall 94 that stands in an annular shape from the inner bottom surface 93a of the bottom wall 93. An opening is formed by the annular side wall 94. This opening is covered by the cover 92. This forms a storage space. The cover 92 is made of resin or metal. The cover 92 will be described later in detail.

  A hole corresponding to the third external connection terminal 100c is formed in the bottom wall 93. Further, a flange 95 for connecting to the body of the vehicle is connected to the bottom wall 93. The flange 95 and the body of the vehicle are mechanically and thermally connected via bolts. Thereby, battery pack 100 is fixed to the vehicle.

  As shown in FIG. 2, a first heat radiating portion 97 and a second heat radiating portion 98 which are locally protruded toward the cover 92 in the z direction are formed on the bottom wall 93. The first switch 31 is fixed to the first heat radiating section 97. The second switch 32 is fixed to the second heat radiating section 98.

  The pack case 90 (battery pack 100) of the present embodiment is provided below a seat of a vehicle. However, the arrangement of the battery pack 100 is not limited to this. Battery pack 100 can also be arranged in, for example, a space between a rear seat and a trunk room, a space between a driver's seat and a passenger seat, and the like.

<Circuit configuration of battery pack>
Next, the circuit configuration of the battery pack 100 will be described. The connection between each power supply bus bar and each switch described below is performed by TIG welding. The connection between each power supply bus bar and the external connection terminal is performed by bolting. The connection between each power supply bus bar and the circuit board 20 is performed by brazing. Each power supply bus bar and each switch may be connected by laser welding.

  As shown in FIG. 1, the first external connection terminal 100a and one end of the first switch 31 are electrically connected via a first power supply bus bar 51. A part is branched from the first power supply bus bar 51. The branch portion 51a of the first power supply bus bar 51 is electrically connected to the first internal terminal 26a of the wiring board 21.

  The other end of the first switch 31 and the second external connection terminal 100b are electrically connected via the second power supply bus bar 52. A part is branched from the second power supply bus bar 52. The branch portion 52a of the second power supply bus bar 52 is electrically connected to one end of the second switch 32.

  In addition, a part of the second power supply bus bar 52 is branched from a portion between the other end of the first switch 31 and a connection portion with the branch portion 52a. The branch portion 52b is electrically connected to the fourth internal terminal 26d of the wiring board 21.

  The other end of the second switch 32 and the positive electrode of the battery pack 10 are electrically connected via a third power supply bus bar 53. A part is branched from the third power supply bus bar 53. The branch portion 53a of the third power supply bus bar 53 is electrically connected to the second internal terminal 26b of the wiring board 21. The negative electrode of the battery pack 10 is electrically connected to the third external connection terminal 100c.

  The first internal terminal 26 a and the second internal terminal 26 b of the wiring board 21 are electrically connected via the first power supply line 23. A third switch 33 and a fourth switch 34 are connected in series to the first power supply line 23 in order from the first internal terminal 26a to the second internal terminal 26b.

  The third internal terminal 26 c and the fourth internal terminal 26 d of the wiring board 21 are electrically connected via the second power supply line 24. The third internal terminal 26c is electrically connected to the fourth external connection terminal 100d via the fourth power supply bus bar 54.

  A sixth switch 36 is provided on the second power supply line 24. The midpoint between the third internal terminal 26c and the sixth switch 36 in the second power supply line 24 is connected to the midpoint between the third switch 33 and the fourth switch 34 in the first power supply line 23. I have. Thus, the sixth switch 36 is connected in parallel with the third switch 33.

  A midpoint between the fourth internal terminal 26 d and the sixth switch 36 in the second power supply line 24 is electrically connected to the fifth external connection terminal 100 e via the third power supply line 25. A fifth switch 35 is provided on the third power supply line 25. Thus, the fifth switch 35 is connected in parallel with the first switch 31.

  As described above, the first switch 31, the second switch 32, the fourth switch 34, and the third switch 33 are sequentially connected in a ring shape. The midpoint between the first switch 31 and the second switch 32 is connected to the second external connection terminal 100b. The midpoint between the second switch 32 and the fourth switch 34 is connected to the battery pack 10. The midpoint between the fourth switch 34 and the third switch 33 is connected to the fourth external connection terminal 100d. The midpoint between the third switch 33 and the first switch 31 is connected to the first external connection terminal 100a.

  The midpoint of the first switch 31 and the second switch 32 is connected to the midpoint of the fourth switch 34 and the third switch 33 via the sixth switch 36. The midpoint between the first switch 31 and the second switch 32 is connected to the fifth external connection terminal 100e via the fifth switch 35.

  With the above electrical connection configuration, by controlling the opening and closing of the first switch 31, the electrical connection between the first external connection terminal 100a and the second external connection terminal 100b is controlled. In other words, the electrical connection between the lead storage battery 110 and the rotating electric machine 130 is controlled by controlling the opening and closing of the first switch 31.

  By controlling the opening and closing of the second switch 32, the electrical connection between the second external connection terminal 100b and the battery pack 10 is controlled. In other words, by controlling the opening and closing of the second switch 32, the electrical connection between the rotating electric machine 130 and the battery pack 10 is controlled.

  By controlling the opening and closing of the fourth switch 34, the electrical connection between the second internal terminal 26b and the third internal terminal 26c is controlled. In other words, the electrical connection between the battery pack 10 and the protection load 152 is controlled by controlling the opening and closing of the fourth switch 34.

  By controlling the opening and closing of the third switch 33, the electrical connection between the first internal terminal 26a and the third internal terminal 26c is controlled. In other words, the electrical connection between the lead storage battery 110 and the protective load 152 is controlled by controlling the opening and closing of the third switch 33.

  Further, by controlling the opening and closing of the sixth switch 36, the electrical connection between the fourth internal terminal 26d and the third internal terminal 26c is controlled. In other words, the electrical connection between the rotating electric machine 130 and the protective load 152 is controlled by controlling the opening and closing of the sixth switch 36.

  By controlling the opening and closing of the fifth switch 35, the electrical connection between the fourth internal terminal 26d and the fifth external connection terminal 100e is controlled. In other words, the electrical connection between the rotating electrical machine 130 and the lead storage battery 110 is controlled by controlling the opening and closing of the fifth switch 35.

  Furthermore, by simultaneously opening and closing the fifth switch 35 and the sixth switch 36, the electrical connection between the third internal terminal 26c and the fifth external connection terminal 100e is controlled. In other words, the electrical connection between the protection load 152 and the lead storage battery 110 is controlled by simultaneously opening and closing the fifth switch 35 and the sixth switch 36.

<Cover shape>
Next, the shape of the cover 92 will be described in detail.

  The cover 92 of the present embodiment is formed of an insulating resin material. For this reason, the manufacturing cost of the cover 92 is lower than that of the housing 91 manufactured by aluminum die casting.

  The cover 92 includes an upper wall 60 that is disposed facing the bottom wall 93 of the housing 91 in the z-direction, and an annular wall 61 that rises from an edge of the upper wall 60 on the bottom wall 93 side. Bolt holes that open in the z direction are formed in the annular wall 61 and the side wall 94 of the housing 91. Bolts are fastened to these bolt holes. As a result, the cover 92 is fixed to the housing 91. The storage space is configured by the cover 92 and the housing 91. The annular wall 61 corresponds to the side wall.

  In this storage space, the battery pack 10, the circuit board 20, the restraint plate 96, and the like are stored as described above. The upper wall 60 has a shape uneven in the z direction according to the stored items.

  Each of the battery pack 10 and the circuit board 20 is connected to the first wire harness 210 and the second wire harness 220 via the power supply bus bar 50. A notch 62 for connecting the wire harness and the power supply bus bar 50 is formed in the annular wall 61. Further, an opening window 63 for inserting and removing the external connector 28 from the connector 27 is formed in the annular wall 61.

  The annular wall 61 has a left wall 64 and a right wall 65 facing each other in the x direction, and a front wall 66 and a rear wall 67 facing each other in the y direction. The left wall 64, the front wall 66, the right wall 65, and the rear wall 67 are sequentially connected in the circumferential direction around the z direction. Thereby, the annular wall 61 has an annular shape in the circumferential direction around the z direction.

  As shown in FIG. 2, the notch 62 is formed in the front wall 66. As shown in FIG. 3, the above-mentioned opening window 63 is formed in the rear wall 67. 4 and 5, the connector 27 is provided in the opening window 63.

  As shown in FIG. 6, the opening window 63 penetrates an inner surface 92a defining a part of the storage space in the cover 92 and an outer surface 92b outside the inner surface 92a exposed to an external atmosphere. The opening window 63 is open to each of the inner surface 92a and the outer surface 92b of the rear wall 67.

  The opening window 63 is defined by an annular edge 68. The edge 68 has an upper edge 68a and a lower edge 68b separated in the z direction, and a left edge 68c and a right edge 68d separated and opposed in the x direction. The upper edge 68a, the right edge 68d, the lower edge 68b, and the left edge 68c are sequentially connected in the circumferential direction around the z direction. Thereby, the edge portion 68 forms an annular shape in the circumferential direction around the y direction. The left edge 68c and the right edge 68d correspond to the connection edge.

  The opening window 63 is open in the y direction. The external connector 28 is inserted into the connector 27 provided in the opening window 63 along the y direction as shown by a white arrow in FIG. Thus, the external connector 28 can be connected to the connector 27 through the opening window 63.

  As shown in FIG. 6, in the present embodiment, the upper edge 68a and the lower edge 68b are not opposed in the z direction. The lower edge portion 68b is more distant from the storage space in the y direction than the upper edge portion 68a. Therefore, the upper edge 68a and the separation surface 71b are not opposed in the z direction. This is to prevent the rear wall 67 from coming into contact with the connector 27 when assembling the cover 92 close to the housing 91 in which the stored items are mounted in the z direction.

<Formation of the opening window on the rear wall>
Next, a portion where the opening window 63 is formed on the rear wall 67 will be described in detail. In this regard, the formation site is hereinafter referred to as a connection wall 69.

  As shown in FIG. 6, the connection wall 69 includes an upper connection wall 70 extending from the upper wall 60 to the upper edge 68a via the opening window 63, and a lower side extending from the lower edge 68b toward the distal end. And a connection wall 71.

  The upper connection wall 70 extends from the upper wall 60 toward the upper edge 68a along the z direction. For this purpose, the outer surface 92b of the upper connecting wall 70 extends in the z-direction. The upper edge portion 68a and the connector 27 face each other with a distance in the z direction. Hereinafter, the outer surface 92b of the upper connection wall 70 is referred to as an upper outer surface 70a.

  On the other hand, the lower connection wall 71 does not simply extend in the z direction. The lower connection wall 71 extends from the lower edge 68b in the direction away from the storage space along the y direction, and then extends toward the distal end along the z direction. For this purpose, the outer surface 92b of the lower connection wall 71 extends away from the storage space along the y direction in which the opening window 63 opens from the lower edge 68b, and then extends toward the tip of the rear wall 67. Extending in the direction.

  Hereinafter, the outer surface 92b of the lower connection wall 71 is referred to as a lower outer surface 71a. When expressed in a subdivided manner, the lower outer surface 71a includes a separation surface 71b extending away from the storage space in the y direction from the lower edge portion 68b, an extension surface 71c extending in the z direction toward the tip of the rear wall 67, It has a connection surface 71d that connects the separation surface 71b and the extension surface 71c. The connecting surface 71d extends from the separating surface 71b toward the connecting surface 71d in an inclined direction that is inclined in the y-direction and the z-direction so as to be separated from the storage space.

  In the present embodiment, the lower edge portion 68b and the connector 27 are separated from each other in the z-direction and in the y-direction. The lower edge portion 68b and the connector 27 are not opposed to each other in the z direction. For this reason, the separation surface 71b and the connector 27 are not opposed in the z direction. This is to prevent the rear wall 67 (lower connection wall 71) from coming into contact with the connector 27 when the cover 92 is assembled to the housing 91 in which the stored items are mounted as described above.

<Effects>
The opening window 63 in which the connector 27 is provided is formed in the cover 92 as described above. The opening window 63 is defined by an annular edge 68. According to this, the intrusion of dust into the storage space via the opening window 63 is suppressed as compared with the configuration in which the opening window is defined by the non-annular edge simply by cutting out a part of the cover. .

  The lower outer surface 71a of the lower connection wall 71 extends away from the storage space in the y direction in which the opening window 63 opens from the lower edge portion 68b, and then extends in the z direction toward the tip of the rear wall 67. I have. According to this, the length of the lower outer surface 71a between the lower edge portion 68b and the distal end portion is longer than in a configuration in which the lower outer surface simply extends in the z direction toward the distal end portion. Thereby, the resistance force acting on the dust flowing from the front end side toward the opening window 63 along the lower outer surface 71a increases. Dust flowing along the lower outer surface 71a from the front end toward the opening window 63 is suppressed from entering the storage space through the opening window 63. In FIG. 6, dust flowing from the front end toward the opening window 63 is indicated by solid arrows.

  The lower outer surface 71a has a separation surface 71b extending away from the storage space in the y direction from the lower edge portion 68b. According to this, the direction in which the separation surface 71b extends and the direction in which the external connector 28 is inserted into and removed from the connector 27 match. This makes it easier to connect the external connector 28 to the connector 27.

  As described above, the preferred embodiments of the present disclosure have been described. However, the present disclosure is not limited to the above-described embodiments, and can be implemented with various modifications without departing from the gist of the present disclosure. It is.

(First Modification)
In the present embodiment, an example in which the connecting surface 71d extends in the inclined direction has been described. However, for example, as shown in the column (a) of FIG. 7, the connecting surface 71d extends in the y direction from the extension surface 71c so as to be separated from the storage space, and then extends in the z direction and the y direction toward the separating surface 71b. Can also be adopted.

  According to this, the dust flowing from the front end toward the opening window 63 along the lower outer surface 71a is kept away from the opening window 63 by the connecting surface 71d. Thereby, intrusion of dust into the storage space through the opening window 63 is suppressed. In FIG. 7, dust flowing along the lower outer surface 71a from the tip toward the opening window 63 is indicated by solid arrows.

(Second Modification)
As shown in columns (b) and (c) of FIG. 7, a form in which the separation surface 71b and the extension surface 71c are directly connected can be adopted. In the modified example shown in the column (b) of FIG. 7, a concave surface 71e that is concave in the z direction is formed on the separation surface 71b. According to this, the flow of dust toward the opening window 63 along the separation surface 71b is disturbed. Therefore, intrusion of dust into the storage space through the opening window 63 is suppressed.

(Third Modification)
In the modified example shown in the column (c) of FIG. 7, the separation surface 71b extends from the lower edge 68b toward the extension surface 71c in an inclined direction so as to be separated from the storage space.

  According to this, for example, when a liquid such as water flowing from the upper outer surface 70a of the upper connection wall 70 flows to the separation surface 71b, the water can flow toward the extension surface 71c so as to move away from the opening window 63. it can. This suppresses liquid such as water from entering the storage space through the opening window 63. In FIG. 7, the liquid flowing from the upper outer surface 70a is indicated by a dashed arrow.

(Fourth modification)
In the present embodiment, an example in which the upper edge portion 68a and the lower edge portion 68b are separated from each other in the y direction and do not face each other in the z direction has been described. However, for example, as shown in a section (d) of FIG. 7, a configuration in which the upper edge 68 a and the separation surface 71 b face each other in the z direction by arranging the lower edge 68 b on the storage space side may be adopted. it can. Similarly, although not shown, a configuration in which the upper edge portion 68a and the lower edge portion 68b face each other in the z direction may be adopted.

  According to this, unlike the configuration in which the lower edge portion 68b is located away from the storage space in the y direction than the upper edge portion 68a, the opening window 63 is prevented from opening toward the upper wall 60 in the y direction. Is done. Therefore, for example, when a liquid such as water flows from the upper outer surface 70 a of the upper connection wall 70, the water is suppressed from entering the storage space through the opening window 63.

(Fifth Modification)
When assembling the cover 92 to the housing 91, it is necessary to prevent the lower connection wall 71 from contacting the connector 27. In particular, when the connector 27 is disposed between the upper edge portion 68a and the separation surface 71b as shown in the column (d) of FIG. 7 and the column (a) of FIG. 8, such a problem is likely to occur. For example, as shown in column (a) of FIG. 9, when the cover 92 is simply brought close to the housing 91 in the z direction, the lower connection wall 71 contacts the connector 27. Therefore, when assembling the cover 92 to the housing 91, it is necessary to shift the cover 92 with respect to the housing 91 in the y direction.

  When the cover 92 is displaced in the y direction with respect to the housing 91 in this manner, a new problem occurs in that the cover 92 and the housing 91 are displaced in the y direction. In the present modification, the defining portion 80 for suppressing the occurrence of such dislocation is formed in the battery pack 100.

  The defining portion 80 has a function of defining the relative position of the cover 92 and the housing 91 in the y direction by contact. The defining unit 80 of the present embodiment also has a function of defining the relative position of the cover 92 and the housing 91 in the x direction.

  As shown in FIG. 8, the defining section 80 has a first defining section 81 formed on the housing 91 and a second defining section 82 formed on the cover 92. The first defining portion 81 has a columnar shape rising from the side wall 94 of the housing 91 in the z direction. The second defining portion 82 has a columnar shape standing in the z direction from the inner surface 92 a of the upper wall 60 of the cover 92.

  The first defining portion 81 has cutouts shown in columns (a) and (b) of FIG. This notch opens outside the storage space in the y direction. The notch is open on the upper wall 60 side of the cover 92 in the z direction.

  The notch formed in the first defining portion 81 is defined by a bottom surface 81a facing the z direction and a defining surface 81b extending from the bottom surface 81a in the z direction. The defining surface 81b has a first lateral defining surface 81c and a second lateral defining surface 81d facing each other while being separated in the x direction, and a vertical defining surface 81e connecting the first lateral defining surface 81c and the second lateral defining surface 81d. .

  The second defining portion 82 is arranged in a region surrounded by a first horizontal defining surface 81c, a second horizontal defining surface 81d, and a vertical defining surface 81e that define the notch of the first defining portion 81. Thus, the second defining portion 82 is located between the first lateral defining surface 81c and the second lateral defining surface 81d in the x direction. The second defining portion 82 is located between the opening of the notch and the vertical defining surface 81e in the y direction. Note that a part of the second defining portion 82 may be located outside the opening of the notch in the y direction. The first lateral defining surface 81c and the second lateral defining surface 81d correspond to the second defining surface. The vertical defining surface 81e corresponds to the first defining surface.

<Assembling the cover to the housing>
Next, the assembly of the cover 92 to the housing 91 will be described with reference to FIG. The arrangement of the cover 92 and the housing 91 in the y-direction is shifted so that the rear wall 67 of the cover 92 is separated from the connector 27 in the y-direction, as indicated by a white arrow in the column (b) of FIG. At this time, the rear wall 67 and the connector 27 do not face each other in the z direction.

  Next, the cover 92 is moved closer to the housing 91 in the z direction, as indicated by a white arrow in the column (c) of FIG. As a result, the connector 27 is spaced from the opening of the opening window 63 in the y direction. The vertical defining surface 81e of the first defining portion 81 and the second defining portion 82 are separated from each other in the y direction.

  Next, the cover 92 is moved closer to the housing 91 in the y direction, as indicated by a white arrow in the column (d) of FIG. At this time, the second defining portion 82 is brought into contact with the vertical defining surface 81e of the first defining portion 81. This defines the position in the y direction between the cover 92 and the housing 91. At this time, as shown in the section (b) of FIG. 8, the second defining portion 82 is provided between the first lateral defining surface 81c and the second lateral defining surface 81d of the first defining portion 81. Thus, the position of the second defining portion 82 in the x direction is also defined. That is, the position of the cover 92 in the x direction with respect to the housing 91 is also defined. As described above, the positions of the cover 92 in the x direction and the y direction with respect to the housing 91 are defined. As a result, occurrence of displacement between the cover 92 and the housing 91 is suppressed.

(Other modifications)
In each embodiment, the example in which the battery pack 10 has five battery cells has been described. However, the assembled battery 10 may have a plurality of battery cells, and is not limited to the above example. Also, the number of battery stacks may be one or three or more instead of two. Furthermore, a battery stack may be configured by arranging battery cells in the x direction.

  In each embodiment, the example in which the vehicle equipped with the power supply system 200 has the idle stop function has been described. However, the vehicle on which the power supply system 200 is mounted is not limited to the above example. For example, a hybrid vehicle or an electric vehicle can be adopted. In this case, the starter motor 120 and the rotating electric machine 130 shown in the present embodiment replace the motor generator.

DESCRIPTION OF SYMBOLS 10 ... Battery pack, 20 ... Circuit board, 22 ... BMU, 27 ... Connector, 28 ... External connector, 60 ... Upper wall, 61 ... Annular wall, 63 ... Open window, 68 ... Edge, 68a ... Upper edge, 68b ... lower edge, 68c left edge, 68d right edge, 71a lower outer surface, 71b ... separation surface, 71c ... extension surface, 71d ... connection surface, 71e ... concave surface, 81 ... first prescribed portion, 81c ... first horizontal defining surface, 81d ... second horizontal defining surface, 81e ... vertical defining surface, 82 ... second defining portion, 91 ... housing, 92 ... cover, 92a ... inner surface, 92b ... outer surface, 100 ... battery pack, 200 ... Power supply system

Claims (8)

A battery (10);
A control unit (22) for controlling input / output of the battery;
A connector (27) electrically connected to the control unit;
A housing (91) and a cover (92) forming a storage space for storing the battery, the control unit, and the connector by being connected to each other;
The cover has an upper wall (60) opposed to the housing, and a side wall (61) rising from the upper wall toward the housing.
The side wall has an inner surface (92a) defining a part of the storage space, an outer surface (92b) exposed to an external atmosphere, and an open window (63) penetrating the inner surface and the outer surface,
The connector is connectable to an external connector (28) through the opening window;
The open window is defined by an annular edge (68);
The edge portion includes an upper edge portion (68a) located on the upper wall side and a lower edge portion (68b) located on the housing side in a facing direction in which the upper wall and the housing are opposed to each other. A connecting edge (68c, 68d) connecting the edge and the lower edge,
A lower outer surface (71a) between the lower edge portion of the outer surface and the front end portion of the side wall on the housing side is separated from the storage space, and has an opening direction orthogonal to the opening of the opening window and the opening direction. Battery pack extending in the opposite direction.   The lower outer surface includes a separation surface (71b) extending in the opening direction from the lower edge portion in a mode separated from the storage space, and an extension surface (71c) extending in the facing direction from the tip end. The battery pack according to claim 1, comprising: The lower outer surface has a connection surface (71d) connecting the separation surface and the extension surface, in addition to the separation surface and the extension surface,
3. The battery pack according to claim 2, wherein the connection surface extends from the extension surface toward the separation surface so as to be separated from the storage space. 4.   4. The battery pack according to claim 2, wherein a concave surface (71 e) that is concave in the facing direction is formed on the separation surface. 5.   5. The separation surface extends in the opening direction from the lower edge portion and extends in the facing direction from the opening window toward the distal end portion while being separated from the storage space. 6. The battery pack according to claim 1.   The battery pack according to claim 1, wherein the upper edge portion faces at least one of the lower outer surface and the lower edge portion in the facing direction. A first defining portion (81) is formed in the housing;
The second defining portion (82) that defines a relative position of the housing and the cover in the opening direction by contact with the first defining portion in the opening direction is formed in the cover. 6. The battery pack according to any one of 6.   The first defining portion has a first defining surface (81e) facing the second defining portion in the opening direction, and faces the second defining portion in an intersecting direction intersecting the opening direction and the facing direction. 8. The battery pack according to claim 7, further comprising a second defining surface (81 c, 81 d).

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