JP6245065B2 - Battery pack - Google Patents

Description

  The present invention relates to a battery pack that cools a plurality of battery cells housed inside a case.

  The battery pack described in Patent Document 1 includes an air supply unit that introduces external air into a case that accommodates a plurality of stacked battery cells, and an exhaust unit that discharges air after flowing between the battery cells to the outside. With. That is, the air exchanged with the battery cell is not discharged to the outside and returned to the inside of the case again, and new air is taken into the case for battery cooling. This air supply and exhaust air flow is always formed. The battery pack of Patent Document 1 secures battery cooling performance by discharging air inside the case that has risen in temperature by absorbing the self-heating of the battery and replacing it with external air that is supplied.

JP 2007-329047 A

  However, as in Patent Document 1, if both the air supply opening through which the air enters and exits the pack case and the exhaust opening are always open, the operating sound of the fluid drive means such as a blower is generated. It becomes easy to leak outside. In addition, if both the air supply / exhaust openings are always open, dust and moisture can easily flow into the case, which may cause deterioration in the quality of the battery pack.

  Accordingly, the present invention has been made in view of the above-described problems, and a battery pack that prevents both the air supply passage and the exhaust passage from being always opened and that can ensure battery cooling performance. The purpose is to provide.

In order to achieve the above object, the present invention employs the following technical means. That is, one of the inventions related to the disclosed battery pack includes a plurality of batteries (2), a blower means (6) for blowing air for cooling the plurality of batteries, and a housing for housing the plurality of batteries and the blower means ( 3) and an air circulation path formed inside the housing, and after the air blown out by the blowing means exchanges heat with a plurality of batteries, the circulation forms a series of air flow paths sucked into the blowing means The passage (7), the air introduction passage (75) provided so as to communicate the circulation passage and the outside of the housing, and means operable according to the pressure of air generated by the suction force of the blowing means, The air introduction passage is opened when operating under the action of air pressure, and the air introduction passage is closed when not operating, allowing the introduction of air into the housing through the air introduction passage. And air introduction permission or disapproval (4; 104; 204) and a passage that communicates between the outside and the inside of the housing, and the air outside the housing is introduced into the housing through the air introduction passage. An air discharge passage (76) through which a part of the circulating air that circulates is discharged to the outside of the housing ,
When opening the air introduction passage, a part of the circulating air is formed by forming a circulation air flow in which air circulates through the circulation passage in the housing and introducing air outside the housing into the housing through the air introduction passage. was carried out when open mode for discharging to the outside of the housing, when closed to close the air inlet passage, a circulation passage in the housing that you implement closure at mode for forming only the circulating air stream which air circulates Features.

  According to the present invention, the air introduction passage is opened and closed by the air introduction permission / rejection means according to the pressure of the air, so that air is introduced into the housing only at the time of opening. As a result, air supply and exhaust are performed while securing a circulating air flow at the time of opening, and both the air supply passage and the exhaust passage are not opened at the time of closing. It is only formed. Accordingly, it is possible to reduce the leakage of the operation sound of the blowing means and the intrusion of moisture and dust into the housing. Moreover, the fall of the heat retention inside a housing | casing can be reduced.

  Further, the pressure of the air that can operate the air introduction permission / refusal means is generated by the suction force of the blower means. Only the air flow can be controlled.

  As described above, according to the present invention, it is possible to obtain a battery pack that can prevent both the supply air passage and the exhaust passage from being always opened and ensure battery cooling performance.

  Furthermore, according to the present invention, since the air introduction permission / inhibition means operable according to the air pressure is provided, the components necessary for battery cooling according to the battery pack have a simple structure and the cost is suppressed. It can be realized with what is possible.

  In addition, the code | symbol in the parenthesis as described in a claim and the said means thru | or description is an example which shows clearly the correspondence with the specific means as described in embodiment mentioned later, and does not limit the content of invention. Absent.

It is the schematic which showed the inside of the battery pack from the side wall side in order to demonstrate the structure and fluid flow in a pack case about the battery pack of 1st Embodiment. It is the fragmentary sectional view which showed the state which closes and the state which opens an air introduction channel | path about the switchgear which the battery pack of 1st Embodiment has. It is a perspective view for demonstrating the switchgear of a 1st embodiment. It is the fragmentary sectional view which showed the state which closes and the state which opens an air introduction channel | path about the opening / closing apparatus of 2nd Embodiment. It is the fragmentary sectional view which showed the state which closes and the state which opens an air introduction channel | path about the opening / closing apparatus of 3rd Embodiment.

  A plurality of modes for carrying out the present invention will be described below with reference to the drawings. In each embodiment, parts corresponding to the matters described in the preceding embodiment may be denoted by the same reference numerals, and redundant description may be omitted. When only a part of the configuration is described in each mode, the other modes described above can be applied to the other parts of the configuration. Not only combinations of parts that clearly indicate that the combination is possible in each embodiment, but also the embodiments are partially combined even if they are not clearly specified unless there is a problem with the combination. It is also possible.

(First embodiment)
The battery pack 1 of 1st Embodiment which is an example of this invention is demonstrated referring FIGS. 1-3. The battery pack 1 is used, for example, in a hybrid vehicle that uses a traveling drive source by combining an internal combustion engine and a motor driven by electric power charged in the battery, an electric vehicle that uses a motor as a travel drive source, and the like. The plurality of battery cells 2 included in the battery pack 1 are, for example, a nickel metal hydride secondary battery, a lithium ion secondary battery, or an organic radical battery.

  The battery pack 1 includes an assembled battery composed of a plurality of battery cells 2 connected to be energized, a pack case 3 that forms a predetermined internal space, and a blower that circulates air in the pack case 3. The pack case 3 is a housing that houses a plurality of battery cells 2 and a blower 6 that is an example of a blower.

  The battery cell 2 includes a positive electrode terminal and a negative electrode terminal that protrude outward from the outer case. The electrode terminals exposed from the outer case, and the terminals of different polarities in the adjacent battery cells 2 are electrically connected by a conductive member such as a bus bar. The connection between the bus bar and the electrode terminal is performed, for example, by screwing or welding. Therefore, the total terminal portions arranged at both ends of the plurality of battery cells 2 electrically connected by a bus bar or the like are supplied with electric power from the outside or discharged toward other electric devices.

  The battery pack 1 includes a battery management unit. The battery management unit is a device that manages at least the amount of electricity stored in the battery cell 2, and is an example of a battery control unit that performs control related to the battery cell 2. In addition, the battery management unit may be a device that monitors current, voltage, and temperature related to the battery cell 2 and manages an abnormal state, electric leakage, and the like of the battery cell 2.

  In addition, a signal related to the current value detected by the current sensor is input to the battery management unit. Similar to the vehicle ECU, the battery management unit includes an input circuit, a microcomputer, and an output circuit. Battery information is stored as data in the storage means of the microcomputer. The stored battery information data includes, for example, the battery voltage, the charging current, the discharging current, and the battery temperature in the battery pack 1. Further, the battery management unit can function as a device that controls the operation of the motor 60 of the blower 6. The battery management unit is configured to be able to communicate with various electronic control devices mounted on the vehicle.

  Inside the pack case 3, a circulation passage 7 is formed that forms a circulation path of a fluid that is forced to flow by the blower 6. The circulation passage 7 is a passage formed inside the pack case 3 and through which the fluid circulates. The circulation passage 7 forms a main flow path of a series of fluids sucked into the blower 6 after the air blown by the blower 6 exchanges heat with each battery cell 2. That is, in the pack case 3, there is one place where the fluid flows out from the blower 6, and there is also one place where the fluid flows into the blower 6. Therefore, the fluid inside the pack case 3 always circulates through the circulation passage 7 via the blower 6.

  As shown in FIG. 1, the circulation passage 7 is constituted by a series of circulation paths connecting at least the suction passage 74, the blowout passage 70, the top wall side passage 71, the battery passage 72 and the collecting passage 73. The blow-out passage 70 constitutes a fluid discharge passage through which the fluid discharged by the blower 6 passes. The suction passage 74 and the collecting passage 73 constitute a passage through which the fluid discharged from the blow-out passage 70 circulates after being cooled by exchanging heat with the plurality of battery cells 2.

  The pack case 3 has a box shape composed of a plurality of walls surrounding the internal space, and is formed of, for example, a molded product of an aluminum plate or an iron plate. The pack case 3 is a case having, for example, six surfaces (for example, including the side walls 34 and 35, the top wall 30, and the bottom wall 33). There are two sets of opposing side walls, and each set of side walls is orthogonal to the other set of side walls. The top wall 30 and the bottom wall 33 form opposing surfaces and are orthogonal to the two sets of side walls.

  Moreover, the pack case 3 can be produced by forming a box-like space inside by joining and assembling a plurality of case bodies. Moreover, you may make it form a some convex part or a recessed part in the surface of a predetermined wall among the several walls of the pack case 3, in order to enlarge a thermal radiation area.

  The plurality of battery cells 2 constitutes a plurality of cell stacks in the internal space of the pack case 3. The plurality of battery cells 2 constituting the plurality of cell stacks are respectively installed at predetermined intervals, and a battery passage 72 that is a gap through which a fluid can flow is formed between adjacent battery cells 2. The battery passage 72 is formed by a spacer member provided between the cells. The spacer member is supported by being sandwiched between cells, thereby forming a passage through which fluid flows vertically between the cells. That is, each battery passage 72 is closed between the cells, the side wall side is closed, the top wall 30 side is opened toward the top wall side passage 71, and the bottom wall 33 side is connected to the collecting duct 83 and leads to the collecting passage 73. Thus, each battery passage 72 includes a fluid inlet portion on the top wall 30 side and a fluid outlet portion that collects in the collecting passage 73 on the bottom wall 33 side.

  The collective duct 83 is a duct connecting the downstream end (lower end) of each battery cell 2 and the suction passage 74 in the suction duct 82. The collecting duct 83 forms a collecting passage 73 in which the fluid flowing out of each battery passage 72 can be thermally connected to the bottom wall 33. In other words, the heat of the fluid flowing through the collecting passage 73 can move to the bottom wall 33.

  The collecting passage 73 is a passage extending in parallel with the bottom wall 33 from the outlet portion of each battery passage 72 to the suction passage 74, and is connected to the suction portion 61 of the blower 6 via the suction duct 82 and the duct connection member 80. Communicate. The ceiling wall side passage 71 is a passage extending in parallel with the ceiling wall 30 formed between the ceiling wall 30 and the plurality of battery cells 2.

  The blower 6 is an example of a blowing unit that circulates the fluid in the pack case 3 through the circulation passage 7. The blower 6 includes a motor 60, a sirocco fan that is rotated by the motor 60, and a fan casing that houses the sirocco fan. This fan casing forms an air suction portion 61 that communicates with the suction port of the sirocco fan. The suction portion 61 and the suction passage 74 in the suction duct 82 are connected by a duct connecting member 80 to communicate with each other. The duct connecting member 80 is an attachment that connects the fan casing and the suction duct 82. Since the duct connecting member 80 has a rectangular parallelepiped chamber inside, the duct connecting member 80 also contributes to reducing the circulation resistance of the circulating fluid.

  The blower 6 is installed so that the rotation axis of the fan is arranged in the direction along the top wall 30 and the bottom wall 33, the fluid is sucked in the direction along the rotation axis, and blown out in the centrifugal direction. The blower 6 is installed on the side wall 34 of the pack case 3 so that the motor 60 side, that is, the back side (the motor 60 side) opposite to the suction portion 61 faces.

  A blowout duct 81 that forms a blowout passage 70 that is one passage of the circulation passage 7 is connected to the blowout portion of the fan casing. The blow-out passage 70 of the blower 6 extends in the centrifugal direction of the fan and along the wall near the top wall 30. Therefore, the air blown out through the blowing passage 70 by the blower 6 travels along the top wall side passage 71 along the top wall 30 and further flows from the top wall side passage 71 toward each battery passage 72. The air flows into the battery passages 72 by the fluid suction force of the blower 6 and flows downward, and flows into the collecting passage 73 from the lower end of each battery passage 72. Further, the air flows into the suction passages 74, It always returns to the blower 6 through the suction part 61.

  The air flowing through the circulation passage 7 absorbs heat from each battery cell 2 or heats each battery cell 2 when flowing through each battery passage 72. Air that has cooled or heated each battery cell 2 is collected in the collecting passage 73 and sucked into the blower 6 through the suction passage 74 and the suction portion 61. Further, when the air circulates in the pack case 3, the air contacts the electrode terminal of the battery cell 2 including the positive electrode terminal and the negative electrode terminal and the bus bar that electrically connects the different electrode terminals. A bus bar can also constitute one of the heat transfer means.

  The battery pack 1 includes an air introduction passage 75 that introduces air outside the pack case 3 sucked by the suction force of the blower 6 into the pack case 3. The battery pack 1 is provided with an air discharge passage 76 that is a passage that penetrates a wall that forms the pack case 3 and that discharges part of the air discharged from the blower 6 from the inside of the pack case 3 to the outside.

  The air discharge passage 76 is a passage that communicates the inside and the outside of the pack case 3. The air discharge passage 76 is a passage provided on the wall of the pack case 3 that contacts the air discharged from the blow-out passage 70 before reaching the air suction passage (the suction passage 74 and the collecting passage 73). When circulating air flows through each battery passage 72, the pressure of the air is reduced by pressure loss. For this reason, in the battery pack 1, high-pressure air is discharged from the air discharge passage 76 that penetrates the wall of the pack case 3 before the discharged air having a high pressure is depressurized by heat exchange with the battery cell 2. Discharge.

  In the first embodiment, the air discharge passage 76 is a passage that penetrates the upper portion of the side wall 35. As shown in FIG. 1, the air discharge passage 76 is provided on the side wall 35 at a position higher than the outer case of the battery cell 2, that is, at a height close to the top wall 30. The air discharge passage 76 is preferably provided on the side wall 35 so as to be located in the middle of the width extending in parallel with the top wall 30. According to this, air can be discharged from the air discharge passage 76 with a balanced air volume so as not to be biased toward one side wall in the internal space of the pack case 3. As described above, the air discharge passage 76 is a passage that penetrates the side wall 35 that is a wall provided so that the plurality of battery cells 2 are located between the blow passage 70 and the walls forming the pack case 3. is there.

  The passages through which the air sucked into the blower 6 passes are an air suction passage (suction passage 74 and collecting passage 73) and an air introduction passage 75. The air introduction passage 75 is a passage through which the outside of the pack case 3 communicates with the blower 6. For example, the air introduction passage 75 is a passage having a smaller passage cross-sectional area than the suction passage 74 and the collecting passage 73. The air introduction passage 75 is a passage formed inside the air supply duct 84 connected to the duct connection member 80. The air introduction passage 75 is connected to a specific portion located downstream of the battery passage 72 and upstream of the suction portion 61 in the blower 6. Therefore, the specific part is set at an arbitrary position within a range including the collecting passage 73, the suction passage 74, and the suction portion 61.

  The battery cell 2 self-heats at the time of output from which current is taken out and at the time of input to be charged. For example, the battery management unit constantly monitors the temperature of the battery cell 2 in the battery pack 1 and controls the operation of the blower 6 based on the temperature of the battery cell 2. The blower 6 can be driven using the electric power stored in the plurality of battery cells 2 of the battery pack 1. The operation of the blower 6 is controlled by the control device 5. Therefore, the control device 5 can be configured by a battery management unit. The control device 5 can control the suction force by the blower 6 and the flow rate of the circulating air by controlling the output of the blower 6 based on the temperature detected by the temperature sensor 51.

  The battery pack 1 includes an opening / closing device 4 that opens and closes the air introduction passage 75 according to the detected temperature. The opening / closing device 4 is an example of an air introduction permission / rejection unit that permits and prohibits the introduction of air into the pack case 3 through the air introduction passage 75.

  The temperature sensor 51 is provided at a position upstream of the circulating air flow with respect to the connection site (the air mixing port portion 750) to which the air introduction passage 75 is connected, and is used as a temperature detection unit of the battery cell 2. Therefore, even when external air flows into the pack case 3 through the air introduction passage 75 when the opening / closing device 4 is in the open state, the external air does not directly hit the temperature sensor 51. The temperature of circulating air is detected in contact with the circulating air. Since the temperature of the circulating air is the temperature of the air after heat exchange with the battery cell 2, it has a correlation with the temperature of the battery cell 2 and can be used as a temperature detection means for the battery cell 2.

  The control device 5 controls the rotational speed of the blower 6 according to a calculation result using a calculation program stored in advance in a built-in calculation unit, storage device, or the like. The control device 5 applies a voltage controlled to a duty ratio of an arbitrary value included in 0% to 100% to the motor 60 of the blower 6 to vary the rotational speed of the fan. In the battery pack 1, by changing the rotational speed of the fan by this duty control, the air volume provided by the blower 6 can be adjusted in multiple steps or in a stepless manner.

  When the temperature detected by the temperature sensor 51 is equal to or higher than the threshold temperature set lower than the above-mentioned specified temperature, the control device 5 causes the output of the blower 6 to be equal to or higher than a predetermined value (for example, higher than a predetermined rotation speed). To control. Thereby, the air blower 6 is controlled to have a suction force of a predetermined level or higher. By this level of suction force, the opening / closing device 4 is controlled to be in an open state in which the door body 40 rotates and stops to the position 40P1 in FIG. 2 against the biasing force of the spring member 42 and opens the air introduction passage 75. Is done. Therefore, the control device 5 controls either the open state or the closed state of the air introduction passage 75 according to the temperature information of the battery cell 2.

  The air supply inlet of the air supply duct 84 is opened outside the pack case 3. The air supply duct 84 passes through the bottom wall 33 of the pack case 3 and connects the lower portion of the duct connection member 80 and the outside of the pack case 3. When the opening / closing device 4 is in the open state, the air sucked into the air supply duct 84 is introduced into the suction portion 61 of the blower 6 through the air introduction passage 75. Further, the air is blown out from the blowing passage 70, thereby flowing through the circulation passage 7 and being taken into the pack case 3.

  As shown in FIGS. 2 and 3, the opening / closing device 4 provides a door body 40 that closes and opens the air introduction passage 75 and a biasing force that urges the door body 40 to close the air introduction passage 75. And a spring member 42. The door main body 40 is angularly displaced about the rotary shaft 41 by the pressure of air acting on the door main body 40.

  The spring member 42 is attached to the rotation shaft portion 41 by being wound around the rotation shaft portion 41. The spring member 42 is a member in which a winding portion 420 wound around the rotating shaft portion 41 and both end portions 421 extending so as to face each other from the winding portion 420 are formed. The spring member 42 is installed such that both end portions 421 extending from the winding portion 420 are in contact with the door body 40 and the both end portions 421 sandwich the door body 40 on both sides of the door body 40. Each of the both end portions 421 of the spring member 42 has a biasing force that applies a force toward the end portion side of the spring member 42 at a position facing each other. Therefore, the spring member 42 is installed in a state in which both end portions 421 have an urging force that sandwiches the door body 40 from both sides, and is drawn at a position where the aeration port 750 is closed, that is, a solid line in FIG. It is stationary at the specified position.

  As shown in FIG. 2, the position 40P1 indicates the position of the door body 40 in the open state, and the position 40P2 indicates the position of the door body 40 in the closed state. When the blower 6 is stopped and the circulating air is not formed, or even if the circulating air is formed, the negative pressure of the air acting on the door body 40 is small when the suction force of the blower 6 is small. The door main body 40 remains at the position where the aeration port 750 is closed. When the suction force of the blower 6 increases to a predetermined level or more, the door body 40 is angularly displaced toward the inside of the pack case 3, and the end portion of the both end portions 421 located closer to the inside of the pack case 3 is the door body. In balance with the force or the like to hold 40, for example, it stops at a position 40P1. By this action, air outside the pack case 3 is taken into the circulation passage 7 through the air introduction passage 75. The external air mixed in the circulation passage 7 circulates in the circulation passage 7 together with the circulation air, and an air amount equivalent to the mixed air amount is exhausted from the air discharge passage 76 to the outside.

  Further, the opening / closing device 4 as air introduction permission / refusal means can open the air introduction passage 75 when the pressure inside the pack case 3 is positive with respect to the external pressure. For example, when the internal pressure of the pack case 3 greatly increases due to the generation of gas from the battery cell 2, the door body 40 is angularly displaced to the outside of the pack case 3, that is, the air supply duct 84 side. And the edge part located near the exterior of the pack case 3 among the both end parts 421 balances with the force etc. which hold | maintain the door main body 40, and stops at the position 40P2, for example. Due to this action, the gas inside the pack case 3 is discharged outside through the air introduction passage 75, so that the fail-safe function of the battery pack 1 is activated.

  According to the above, the opening / closing device 4 is provided inside the pack case 3, and opens and closes the air introduction passage 75 inside the pack case 3. The opening / closing device 4 is a mechanical drive device that switches between an open state in which the air introduction passage 75 is opened and a closed state in which the air introduction passage 75 is closed in accordance with the suction force of the blower 6.

  The opening / closing device 4 is also a device that switches its state by controlling the suction force of the blower 6 depending on whether the temperature of the battery cell 2 is higher or lower than the specified temperature. The specified temperature is a temperature that is set in order to manage the battery cell 2 at a temperature at which the battery cell 2 can exhibit its ability by charging, discharging, or the like. The specified temperature is set to a temperature that is higher by a predetermined temperature than the lower limit value of the temperature at which the battery cell 2 needs to be cooled in order for the battery cell 2 to exhibit its ability. The specified temperature can be set in a temperature range having a predetermined width. This description of the specified temperature can also be applied to the aforementioned threshold temperature related to the air temperature detected by the temperature sensor 51. Further, when the temperature detected by the temperature sensor 51 is equal to or higher than the threshold temperature, the opening / closing device 4 switches to an open state in which the air pressure is dominant over the biasing force of the spring member 42 and is lower than the threshold temperature. In this case, the urging force becomes dominant and switches to a closed state.

  The temperature sensor 51 is installed so as not to exist in the air introduction passage 75 but to be positioned in the circulation passage 7. Accordingly, the temperature sensor 51 detects not the temperature of the external air but the temperature of the circulating air flowing through the circulation passage 7. The temperature sensor 51 is provided at a position upstream of the circulating air flow from the connection site (the air mixing port 750) to which the air introduction passage 75 is connected. Therefore, even when external air flows into the pack case 3 in the open state, it is avoided that the external air directly hits the temperature sensor 51, and the temperature sensor 51 is related to the temperature of the battery cell 2. The temperature of the circulating air is detected in contact with high circulating air. Furthermore, it can be avoided that the temperature sensor 51 detects external low-temperature air when it is in an open state. Thereby, the situation where the opening / closing apparatus 4 switches to an open state and a closed state frequently can be prevented. Therefore, the battery pack 1 which can suppress the unnecessary switching of the switchgear 4 and can appropriately control the open state and the closed state is obtained.

  The battery pack 1 is installed in a pack accommodation space such as a trunk room of a vehicle and a back area of the trunk room provided below the trunk room. The pack storage space of the vehicle can also store spare tires, tools, and the like, for example. The battery pack 1 is installed in the pack accommodation space with the bottom wall 33 and the collecting passage 73 facing downward. For example, the air introduction passage 75 communicates with the vehicle interior of the vehicle. The air supply duct 84 extends so that the air suction portion is located in the vehicle interior. For example, the air supply duct 84 is provided so as to pass through an interior member in the vehicle interior and communicate with the vehicle interior, or to be provided to a side portion of the vehicle interior. Therefore, the fluid sucked by the blower 6 through the air introduction passage 75 is air in the passenger compartment.

  When an air conditioner that air-conditions the vehicle interior is mounted on the vehicle, the air conditioner takes in air from the outside of the vehicle or the vehicle interior and provides temperature-adjusted air to the vehicle interior. The air conditioner includes a blower unit that takes in air from the outside of the vehicle or the vehicle interior and blows air toward the air conditioning unit, and an air conditioning unit that adjusts the temperature of the air sent by the blower unit and sends the air into the vehicle interior. . The air introduction passage 75 is a passage for introducing outside air or air in the vehicle interior (inside air), which is lower in temperature than the ambient temperature of the pack case 3, into the pack case 3.

  Moreover, you may mount the pack case 3 in a vehicle so that the floor surface provided in the vehicle may be contacted. Thereby, the heat in the pack case 3 is transmitted to the floor surface through the wall of the case. Therefore, the heat in the pack case 3 is transmitted from the air flowing through the collecting passage 73 after heat exchange with the battery cell 2 to the floor of the vehicle through the bottom wall 33. Moreover, you may make it interpose the thermal radiation sheet excellent in thermal conductivity in the contact part of the bottom wall 33 and a floor surface. In this case, the heat in the pack case 3 is transmitted from the bottom wall 33 to the floor surface through the heat dissipation sheet.

  Further, in the process of circulating through the circulation passage 7, the air contacts the side walls, the top wall 30, the bottom wall 33 and the like. The circulating air radiates heat to the outside of the pack case 3 through the side wall and the top wall 30 before heat exchange with the battery cell 2. Further, the circulating air radiates heat to the outside of the pack case 3 through the top wall 30 immediately before heat exchange with the battery cell 2 when flowing through the top wall side passage 71. Accordingly, the entire top wall 30 and the entire side wall orthogonal to the top wall 30 function as a heat radiating surface when the heat of the battery cells 2 in the pack case 3 is released to the outside.

  Next, the effect which the battery pack 1 of 1st Embodiment brings is demonstrated. The battery pack 1 includes a plurality of battery cells 2, a blower 6 that blows air that cools the plurality of battery cells 2, a pack case 3 that houses the plurality of battery cells 2 and the blower 6, and a series of air in the pack case 3. A circulation passage 7 is provided. The battery pack 1 is a passage that connects the inside and outside of the pack case 3, and opens the air introduction passage 75 and the air introduction passage 75 that pass when external air is introduced into the circulation passage 7 by the suction force of the blower 6. Air introduction permission / rejection means (opening / closing device 4) to be closed. The opening / closing device 4 is operable according to the pressure of air generated by the suction force of the blower 6. The opening / closing device 4 opens the air introduction passage 75 when operating under the negative pressure action of air, and closes the air introduction passage 75 when not operating.

  According to this battery pack 1, the air introduction passage 75 is opened and closed by the air introduction permission / rejection means in accordance with the air pressure, so that air is introduced into the pack case 3 only at the time of opening. As a result, the air supply / exhaust is performed at the same time while ensuring a circulating air flow when opened, and both the supply air passage and the exhaust passage are not opened when closed, so that the circulating air flow is contained in the pack case 3. Will only be formed. Therefore, it is possible to reduce the leakage of the operation sound of the blower 6 and the intrusion of moisture and dust into the pack case 3. Moreover, it can reduce that the heat retention inside the pack case 3 falls by this effect | action.

  Furthermore, the pressure of the air that enables the air introduction permission / prohibition means is generated by the suction force of the blower 6. For this reason, by controlling the suction force of the blower 6, air that can improve the cooling capacity can be taken in from the outside or only the circulating air can be formed. Can be controlled.

  As described above, according to the battery pack 1, it is possible to prevent both the supply air passage and the exhaust passage from being always opened, and in addition to this, it is possible to provide a device that can ensure battery cooling performance. In addition, since the open state can be provided by means of air introduction permission / inhibition that can be operated according to the air pressure, the components necessary for battery cooling are realized with a simple structure and low cost. A battery pack 1 is obtained.

  Furthermore, the air introduction passage 75 is connected to the specific portion described above, so that external air can be mixed into the circulating air whose temperature has been increased by heat exchange with the battery cell 2. For this reason, the temperature of the air heat-exchanged with the battery cell 2 next can be reduced after mixing of external air.

  Further, when the suction force of the blower 6 is controlled so as to be equal to or higher than a predetermined level, the opening / closing device 4 operates to open the air introduction passage 75. According to this, it is possible to control the air introduction passage 75 to an open state or a closed state by controlling the suction force of the blower 6, for example, the rotation speed, the applied voltage, the duty ratio, and the like at an appropriate timing. it can. Therefore, the battery pack 1 can be obtained in which the air flow necessary for battery cooling can be formed with a simple configuration and an uncomplicated control method.

  The opening / closing device 4 includes a door main body 40 that closes and opens the air introduction passage 75 and a spring member 42 that provides a biasing force that biases the door main body 40 in a state in which the air introduction passage 75 is closed. When the control device 5 controls the suction force of the blower 6 to be equal to or higher than a predetermined level, the opening / closing device 4 opens the air introduction passage 75 by receiving a negative pressure action of air against the urging force.

  According to this, the battery pack 1 which can implement | achieve the air flow required for battery cooling with a simple structure using a spring force, and can be formed with the uncomplicated control method is obtained.

  Furthermore, the temperature sensor 51 that detects the temperature, which is a condition for raising the suction force of the blower 6 to a predetermined level or more, is not present in the air introduction passage 75 but is positioned in the circulation passage 7. For this reason, the battery pack 1 can introduce the external air into the circulation passage 7 at a timing according to the temperature of the circulating air reflecting the temperature of the battery cell 2 without being affected by the temperature of the external air. The battery pack 1 can introduce external air capable of improving the cooling capacity of the battery cell 2 into the circulating air at an appropriate timing.

  As described above, the battery pack 1 permits the air circulation by opening the air introduction passage 75 by the opening / closing device 4 only when the external air introduction condition is satisfied. Thereby, the battery cell 2 can be cooled by the circulation of air in the circulation passage 7 while taking in fresh air to such an extent that the circulation flow of air can be continuously formed in the pack case 3. As a result, noise propagation to the outside of the pack case 3 can be suppressed and sufficient absorption from the battery cell 2 can be achieved as compared with the conventional method in which a large amount of air is constantly taken in and out for cooling to cool the battery cell 2. A circulation flow rate for obtaining a heat quantity can be secured. Moreover, according to this battery pack 1, both suppression of noise and effective air cooling of the battery cell 2 can be achieved without requiring a large-scale device for cooling the battery.

  Further, when the temperature of the battery cell 2 is low, by prohibiting air flow due to the closed state in which the switchgear 4 is not operated, the transmission of noise to the outside is suppressed and the amount of heat released to the outside is suppressed to reduce the amount of heat to the outside. 3 can be kept warm. In this case, the temperature rise of the battery can be accelerated, and the output from the battery can be implemented early.

  The opening / closing device 4 is a mechanical drive device that switches between an open state in which the air introduction passage 75 is opened and a closed state in which the air introduction passage 75 is closed in accordance with the air pressure. According to this, it is possible to provide the opening / closing device 4 that can open and close the air introduction passage 75 by a mechanical structure that operates according to pressure without requiring electric power. Therefore, the opening / closing device 4 can eliminate the need for a control device for controlling its operation and various components related to electric drive, and can reduce the number of components, electronic components, cost, and the like.

  Further, the battery pack 1 has an air discharge passage 76 provided on the side wall 35 at a position higher than the outer case of the battery cell 2, that is, at a height close to the top wall 30. According to this configuration, the air discharged from the blow-out passage 70 radiates heat to the outside via the top wall 30 in the process of flowing along the top wall side passage 71 toward the side wall 35 along the top wall 30, and below Toward each battery passage 72. A part of the air flows to the side wall 35 while maintaining a high pressure due to discharge, and is smoothly discharged outside the pack case 3 from the air discharge passage 76 provided at a high position. Therefore, since the vertical movement of the fluid flow can be suppressed from the top wall side passage 71 to the air discharge passage 76, the air resistance can be reduced and the air can be discharged while maintaining a high pressure. Due to this air discharge effect, it is easy to ensure the flow rate of external air taken in through the air introduction passage 75 in the open state.

  The air introduction passage 75 is preferably provided so as to communicate with the vehicle interior of the vehicle. Air in the passenger compartment is drawn into the pack case 3 through the air introduction passage 75. According to this battery pack 1, air-conditioned vehicle interior air can be introduced into the pack case 3 through the air introduction passage 75, so that the temperature difference from the air discharged from the air discharge passage 76 can be increased. it can. Therefore, since the amount of heat radiation to the outside can be increased by increasing the temperature difference in this way, the cooling performance of the battery pack 1 can be further improved.

(Second Embodiment)
2nd Embodiment demonstrates the other form which concerns on an air introduction permission means with reference to FIG. In FIG. 4, components having the same configuration as in the first embodiment are denoted by the same reference numerals, and exhibit similar operations and effects. The configuration, operation, and effects not particularly described in the second embodiment are the same as those in the first embodiment. Only differences from the first embodiment will be described below. Moreover, what has the structure similar to 1st Embodiment in 2nd Embodiment shall show | play the same effect | action and effect demonstrated in 1st Embodiment.

  As shown in FIG. 4, the air introduction permission means of the second embodiment is different from the first embodiment in that the valve body itself has the flexibility to be elastically deformed by the pressure of air. The opening / closing device 104 has flexibility, a flexible valve body 140 that closes the aeration port 750 in a state where it is not bent, and a fixing that fixes one end side of the flexible valve body 140 to the bottom wall 33. 141. The flexible valve body 140 can be composed of, for example, various rubbers, elastomers, various resins having high flexibility, and the like.

  As shown in FIG. 4, the position 140P1 indicates the position of the flexible valve body 140 in the open state, and the position drawn with a solid line indicates the position of the flexible valve body 140 in the closed state. When the blower 6 is stopped and no circulating air is formed, or even when the circulating air is formed, if the suction force of the blower 6 is small, the negative pressure of the air acting on the flexible valve body 140 is reduced. Since it is small, the flexible valve body 140 stays at a position where the aeration port 750 is closed. When the suction force of the blower 6 increases to a predetermined level or more, the flexible valve body 140 is placed on the other side of the pack case 3 opposite to the fixture 141 due to the negative pressure acting on the flexible valve body 140. It is deformed so as to be located on the inner side, and for example, operates up to a position 140P1. As the valve body bends in this way, air outside the pack case 3 is taken into the circulation passage 7 through the air introduction passage 75. The external air mixed in the circulation passage 7 circulates in the circulation passage 7 together with the circulation air, and an air amount equivalent to the mixed air amount is exhausted from the air discharge passage 76 to the outside.

  According to the above, the opening / closing device 104 is provided inside the pack case 3 and opens and closes the air introduction passage 75 inside the pack case 3. The opening / closing device 104 is a mechanical drive type device that switches between an open state in which the air introduction passage 75 is opened and a closed state in which the air introduction passage 75 is closed in accordance with the suction force of the blower 6.

  According to the second embodiment, the air introduction permission / refusal means has flexibility, opens the air introduction passage 75 in a bent state, and closes the air introduction passage 75 in a not bent state. The body 140 is configured. When the control device 5 controls the suction force of the blower 6 to be equal to or higher than a predetermined level, the flexible valve body 140 opens the air introduction passage 75 by bending due to the air pressure. According to this, the battery pack 1 which can implement | achieve the air flow required for battery cooling with the simple structure using the flexibility of valve body itself, and can be formed by the uncomplicated control method is obtained.

(Third embodiment)
In the third embodiment, another embodiment of the air introduction permission unit will be described with reference to FIG. In FIG. 5, components having the same configuration as in the first embodiment are denoted by the same reference numerals, and exhibit similar operations and effects. The configurations, operations, and effects not particularly described in the third embodiment are the same as those in the first embodiment and the second embodiment. Hereinafter, only differences from the first embodiment and the second embodiment will be described. Moreover, what has the structure similar to 1st Embodiment and 2nd Embodiment in 3rd Embodiment shall have the same effect | action and effect demonstrated in 1st Embodiment.

  The air introduction permission means of the third embodiment corresponds to both the case where the pressure in the pack case 3 is a positive pressure and a negative pressure relative to the pressure in the air introduction passage 75 or the external pressure. The point which the flexible valve body 240 deform | transforms into a different direction differs from 2nd Embodiment. The opening / closing device 204 of the third embodiment has flexibility, a flexible valve body 240 that closes the aeration port 750 in an unbent state, and one end side of the flexible valve body 240 at the bottom wall. And a fixing tool 241 for fixing to 33. The flexible valve body 240 can be composed of, for example, various rubbers, elastomers, various resins having high flexibility, and the like.

  As shown in FIG. 5, the position drawn with a solid line indicates the position of the flexible valve body 240 in the closed state. The position 240P1 indicates the position of the flexible valve body 240 in the open state when the inside of the pack case 3 is negative pressure. A position 240P2 indicates the position of the flexible valve body 240 in the open state when the inside of the pack case 3 is at a positive pressure.

  When the blower 6 is stopped and circulating air is not formed, or even when the circulating air is formed, if the suction force of the blower 6 is small, the negative pressure of the air acting on the flexible valve body 240 is reduced. Since it is small, the flexible valve body 240 stays at the position where the aeration port 750 is closed. When the suction force of the blower 6 increases to a predetermined level or more, the flexible valve body 240 is located on the other side of the pack case 3 opposite to the fixture 241 due to the negative pressure acting on the flexible valve body 240. It is deformed so as to be located on the inner side, and for example, operates up to a position 240P1.

  As the valve body is bent in this manner, the air outside the pack case 3 is taken into the circulation passage 7 through the air introduction passage 75. The external air mixed in the circulation passage 7 circulates in the circulation passage 7 together with the circulation air, and an air amount equivalent to the mixed air amount in the circulation air is exhausted to the outside from the air discharge passage 76.

  Further, the opening / closing device 204 as air introduction permission / refusal means can open the air introduction passage 75 when the pressure inside the pack case 3 is positive with respect to the external pressure. For example, when the internal pressure of the pack case 3 greatly increases due to the generation of gas from the battery cell 2, the flexible valve body 240 is deformed to the outside of the pack case 3, that is, the air supply duct 84 side, For example, it operates up to the position 240P2. Due to this action, the gas inside the pack case 3 is discharged to the outside through the air introduction passage 75, so that the fail-safe function of the battery pack 1 is activated.

  As described above, the opening / closing device 204 is provided inside the pack case 3, and opens and closes the air introduction passage 75 inside the pack case 3. The opening / closing device 204 is a mechanical drive device that switches between an open state in which the air introduction passage 75 is opened and a closed state in which the air introduction passage 75 is closed in accordance with the suction force of the blower 6.

(Other embodiments)
In the above-described embodiment, the preferred embodiment of the present invention has been described. However, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention. It is. The structure of the above-described embodiment is merely an example, and the scope of the present invention is not limited to the scope of these descriptions. The scope of the present invention is indicated by the description of the scope of claims, and further includes meanings equivalent to the description of the scope of claims and all modifications within the scope.

  The battery pack according to the above-described embodiment may be provided with an opening / closing device that opens and closes the air discharge passage 76 in conjunction with an opening / closing device that opens and closes the air introduction passage 75. In this case, when the air introduction passage 75 is in an open state, the state of each switching device is controlled so that the air discharge passage 76 is also in an open state.

  The air discharge passage 76 described above can be provided at any part of the entire side wall 35.

  In the above-described embodiment, the number of the air discharge passages 76 that penetrate the wall that forms the pack case 3 is not limited to the number disclosed in the drawings. For example, a plurality of air discharge passages 76 may be provided on each wall that passes therethrough.

  In the above-described embodiment, the collective passage 73 is formed by the collective duct 83, but the collective passage 73 may be configured as a passage surrounded by the bottom wall 33 and the side wall, for example, instead of a passage partitioned by the duct. Good.

  Further, the battery pack of the above-described embodiment forms a circulation flow using the circulation passage 7 as a main flow path by using one blower 6, but forms a circulation flow by suction and blow-out by a plurality of blowers. You may comprise as follows.

  Further, as the fan built in the blower 6 provided inside the pack case 3, an airflow unit may be configured by using an axial fan, a turbo fan, or the like in addition to the sirocco fan described in the above embodiment. .

DESCRIPTION OF SYMBOLS 1 ... Battery pack 2 ... Battery cell (battery)
3 ... Pack case
4. Opening / closing device (air introduction permission / refusal means)
6 ... Blower (blower means)
7 ... circulation passage 40 ... machine drive part (temperature sensing part)
75 ... Air introduction passage 76 ... Air discharge passage 104, 204 ... Flexible valve element (air introduction permission / rejection means)

Claims (5)

A plurality of batteries (2);
A blowing means (6) for blowing air for cooling the plurality of batteries;
A housing (3) for housing the plurality of batteries and the blowing means;
A circulation path of air formed inside the housing, wherein the air blown out by the blowing unit exchanges heat with the plurality of batteries, and then forms a series of air circulation paths sucked into the blowing unit Passage (7),
An air introduction passage (75) provided to allow communication between the circulation passage and the outside of the housing;
It is a means operable according to the pressure of the air generated by the suction force of the air blowing means. The air introduction passage is opened when operated by the pressure of the air, and the air introduction when not operated. Air introduction permission / rejection means (4; 104; 204) for permitting and prohibiting introduction of air into the housing through the air introduction passage by closing the passage;
A passage that communicates between the outside and the inside of the housing, and circulating air that circulates through the circulation passage as air outside the housing is introduced into the housing through the air introduction passage An air discharge passage (76) through which a part of the air is discharged to the outside of the housing;
Equipped with a,
When opening the air introduction passage, a circulation air flow is formed in which air circulates through the circulation passage in the housing, and air outside the housing is introduced into the housing through the air introduction passage. And an open mode in which a part of the circulating air is discharged to the outside of the housing,
Wherein when closed to close the air inlet passage, the battery pack of the circulation passage in the enclosure air, characterized that you implement closure at mode for forming only the circulating air flow circulation. A control device (5) for controlling the suction force of the blowing means;
2. The air introduction permission / rejection unit operates to open the air introduction passage when the control device controls the suction force of the blowing unit to be equal to or higher than a predetermined level. Battery pack. The air introduction permission / refusal means has a flexible valve body (104; 204) that has flexibility and opens the air introduction passage when bent and closes the air introduction passage when not bent. Configured,
When the control device controls the suction force of the air blowing means to be a predetermined level or more, the flexible valve body opens the air introduction passage by being bent by the action of air pressure. The battery pack according to claim 2, characterized in that: The air introduction permission / rejection means includes a door body (40) for closing and opening the air introduction passage, and a spring member (42) for providing a biasing force for urging the door body in a state of closing the air introduction passage. Comprising a switching device (4) comprising:
When the control device controls the suction force of the air blowing means to be equal to or higher than a predetermined level, the opening / closing device opens the air introduction passage by the action of air pressure against the biasing force. The battery pack according to claim 2.   5. The air introduction permission / refusal means (4; 204) opens the air introduction passage when the pressure inside the casing is positive with respect to the external pressure. The battery pack according to any one of the above.

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