JP6531607B2 - Battery pack - Google Patents

Description

  The present invention relates to a battery pack having a plurality of battery cells housed in a case.

  As a conventional battery pack, for example, the one described in Patent Document 1 is known. The battery pack described in Patent Document 1 is provided with a plurality of batteries and a fan device in a case. In the case, a gap (space) is provided between the plurality of batteries, and further between the plurality of batteries and the wall of the case, and the gap is a circulation passage (convection) through which the air in the case is circulated. Flow path). Then, the air inside the case flows (convects) in the circulation passage by operating the fan device. Therefore, the heat of the plurality of cells is transferred to the circulating air, and further released to the outside through the wall of the case, whereby the plurality of cells are cooled.

Patent No. 5130955 gazette

  However, the circulation paths in the case of Patent Document 1 have different lengths from the fan device to the respective batteries. Depending on the length of the circulation passage, the shape of the circulation passage, the air volume (air velocity) of the fan device, and the like, the air flow resistance to each battery may be different, which may cause variation in the wind velocity to each battery. Thus, temperature variations occur among the plurality of batteries. If temperature variations among the plurality of batteries occur, differences in the lifetimes of the respective batteries occur, which results in the deterioration of the overall quality of the battery pack.

  Patent Document 1 describes that it is preferable to provide a duct, a straightening vane, and the like in order to evenly distribute the flow of air in the case, but in fact, it is intended to make the flow of air uniform. While requiring trial and error confirmation, it causes an increase in the number of parts.

  The present invention has been made in view of the above problems, and in a case where a plurality of battery cells and a blower are accommodated in a housing, a duct and a straightening plate are unnecessary, and temperature variations among the plurality of battery cells are suppressed. The purpose is to provide a battery pack that can be used.

  The present invention adopts the following technical means to achieve the above object.

In the present invention, in the battery pack,
With multiple batteries (121),
A housing (110) for accommodating a plurality of batteries;
A circulation passage (130) which is formed in the housing and in which the heat exchange fluid flows so as to contact the plurality of batteries and the inner wall surface of the housing;
A blower (140) housed in the housing and circulating fluid through the circulation passage;
A detector (160) for detecting a temperature of a predetermined battery among the plurality of batteries;
A control unit (170) for controlling the number of rotations of the blower according to the temperature of the battery detected by the detector;
The control unit is configured to execute increase / decrease control to increase / decrease the target rotation number at a predetermined cycle (T) with respect to the target rotation number (St) set according to the temperature of the battery .
The detector (160) is adapted to detect the temperature of at least two cells,
The control unit is
When the temperature difference between at least two batteries is larger than a predetermined value, the increase / decrease control is performed, and
When it is determined that the temperature difference between the batteries is larger than a second predetermined value provided on the side larger than the first predetermined value when the predetermined value is a first predetermined value,
Compare the temperature of the battery located far from the blower relative to the battery located near the blower,
If the temperature of the far side battery is higher, the time ratio for increasing the target number of revolutions within a predetermined cycle is increased,
When the temperature of the battery on the near side is higher, it is characterized in that the time ratio for decreasing the target rotational speed within a predetermined cycle is increased .

  According to the present invention, the target rotational speed (St) is increased or decreased at a predetermined cycle (T), whereby the flow velocity of the fluid circulating in the circulation passage (130) is strong or weak for the plurality of batteries (121). Repetitions can be added. That is, as compared with the case where the fluid is continuously circulated at a constant flow velocity by fixing the target rotational speed, in the plurality of batteries, alternately with respect to the relatively far side and the near side from the blower (140) It can have an auxiliary function of supplying fluid. Therefore, it becomes possible to circulate fluid more uniformly to the whole of a plurality of batteries, and it becomes possible to control temperature variation of a plurality of batteries. In the present invention, the temperature variation of the plurality of batteries is suppressed by controlling the number of rotations of the blower, and it is not necessary to provide a dedicated duct, a straightening vane, or the like in the fluid circulation passage.

  In addition, the flow of fluid can be made turbulent by giving strength to the flow velocity of the fluid. Thus, the turbulent flow effect of the fluid can increase the heat transfer coefficient between the plurality of cells and the fluid to enhance the heat exchange performance.

  The reference numerals in parentheses in the claims are intended to limit the contents of the invention, for the purpose of restricting the contents of the invention, for the purpose of facilitating the understanding of the contents of the description and for illustrating the corresponding configuration in the embodiments described later. Absent.

It is a top view which shows the structure of the battery pack in 1st Embodiment. It is the side view seen from the II direction in FIG. It is a flowchart which shows the control content of the air blower in 1st Embodiment. It is a characteristic view for determining the target number of rotations to battery temperature. It is a characteristic view for setting the instruction number of rotations in a 1st embodiment. It is explanatory drawing which shows the flow of the fluid at the time of making target rotation speed increase. It is explanatory drawing which shows the flow of the fluid at the time of reducing target rotation speed. It is a flowchart which shows the control content of the air blower in 2nd Embodiment. It is a top view which shows the structure of the battery pack in 3rd Embodiment. It is a flowchart which shows the control content of the air blower in 3rd Embodiment. It is a basic characteristic view for setting the instruction number of rotations in a 3rd embodiment. It is a characteristic view for setting up the time ratio at the time of making a target number of rotations increase. FIG. 6 is a characteristic diagram for setting a time ratio at the time of reducing a target rotation speed. It is explanatory drawing which shows the flow of the fluid at the time of enlarging the time ratio of target rotation speed increase. It is explanatory drawing which shows the flow of the fluid at the time of enlarging the time ratio of target rotation speed reduction. It is a top view which shows the structure of the battery pack in 4th Embodiment. It is a characteristic view for setting the instruction number of rotations of the 1st fan and the 2nd fan. It is explanatory drawing which shows the flow of the fluid at the time of making target rotation speed increase in 4th Embodiment. It is explanatory drawing which shows the flow of the fluid at the time of reducing target rotation speed in 4th Embodiment. It is a flowchart which shows the control content of the air blower in 5th Embodiment. It is a characteristic view for setting the instruction number of rotations of the 1st fan and the 2nd fan. It is an explanatory view showing the flow of fluid when the target number of rotations by the side of the 1st fan is increased, and the target number of rotations by the side of the 2nd fan is decreased. It is an explanatory view showing the flow of fluid when the target number of rotations by the side of the 1st fan is reduced, and the target number of rotations by the side of the 2nd fan is increased.

  Hereinafter, a plurality of modes for carrying out the present invention will be described with reference to the drawings. The same referential mark may be attached | subjected to the part corresponding to the matter demonstrated by the form preceded in each form, and the overlapping description may be abbreviate | omitted. When only a part of the configuration is described in each form, the other forms described above can be applied to other parts of the configuration. Not only combinations of parts which clearly indicate that combinations are possible in each embodiment, but also combinations of embodiments even if not explicitly specified, unless any problem occurs in the combinations. It is also possible.

First Embodiment
A battery pack 100A according to a first embodiment, which is an example of the present invention, will be described with reference to FIGS. The battery pack 100A is used, for example, in a hybrid vehicle that uses a motor driven by electric power charged in a battery and an internal combustion engine as a traveling drive source, or in an electric vehicle that uses a motor as a traveling drive source. The plurality of battery cells 121 included in the battery pack 100A are, for example, a nickel hydrogen secondary battery, a lithium ion secondary battery, an organic radical battery, and the like.

  Battery pack 100A is installed in a pack storage space such as a trunk room of a vehicle or a trunk room back area provided below the trunk room. The pack accommodation space can also accommodate, for example, a spare tire, a tool, and the like. The battery pack 100A is installed in the pack storage space with the bottom wall 112 and the bottom wall-side passage 135 described below facing downward.

  Also, the battery pack 100A may be installed below the front seat or below the rear seat in the vehicle compartment of the vehicle. In this case, the battery pack 100A is installed below the front seat, the rear seat, etc., with the bottom wall 112 and the bottom wall side passage 135 facing downward. In addition, the space where the battery pack 100A is installed below the rear seat may be in communication with the rear trunk room area below the trunk room. The installation space can also be configured to communicate with the outside of the vehicle.

  As shown in FIGS. 1 and 2, the battery pack 100A includes a case 110, a battery assembly 120 (cell laminate 120A) including a plurality of battery cells 121, a circulation passage 130, a blower 140, internal fins 150, and a detector 160. And a battery management unit 170 and the like.

  In the present embodiment, in FIG. 1, Fr indicates the front side of the vehicle, Rr indicates the rear side of the vehicle, LH indicates the left side of the vehicle, and RH indicates the right side of the vehicle. When indicating the direction in the battery pack 100A, the direction of Fr-Rr is referred to as the front-rear direction, and the direction of LH-RH is referred to as the left-right direction. Also, the direction of action of gravity is referred to as the vertical direction.

  The case 110 is a housing that forms a sealed internal space isolated from the outside, and internally accommodates the battery assembly 120 and the blower 140, and further, the internal fin 150, the detector 160, the battery management unit 170, etc. ing. The case 110 is in the form of a box made of a plurality of walls surrounding an internal space, and is formed of a molded product of an aluminum plate or an iron plate. The case 110 is, for example, a flat rectangular parallelepiped in the vertical direction, and has six sides, that is, a top wall 111, a bottom wall 112, a side wall 113, a side wall 114, a side wall 115, and a side wall 116. The case 110 also has a reinforcing beam 117 at the bottom wall 112.

  The top wall 111 is a wall that forms the upper surface of the case 110, and is a rectangular wall having a long side in the front-rear direction. The bottom wall 112 is a wall that forms the lower surface of the case 110, and has the same shape as the top wall 111.

  The side walls 113 and 114 are walls forming the left and right sides of the case 110, and are long and thin rectangular walls having long sides in the front-rear direction. The side walls 113 and 114 are in a positional relationship facing each other. Further, the side walls 115 and 116 are walls forming the front and rear sides of the case 110, and are long and thin rectangular walls having long sides in the left-right direction. Sidewalls 115 and 116 are in a positional relationship facing each other. Further, the side walls 115 and 116 are walls orthogonal to the side walls 113 and 114.

  The case 110 may be manufactured by forming a box-like space inside by joining and assembling a plurality of case bodies instead of using the walls 111 to 116 described above. Further, among the plurality of walls of the case 110, a plurality of projections or recesses may be formed on the surface of a predetermined wall in order to increase the heat dissipation area.

  In the battery pack 100A, the direction along the long sides of the side walls 113 and 114 corresponds to the front-rear direction, and the direction along the long sides of the side walls 115 and 116 corresponds to the left-right direction.

  The beams 117 are reinforcing members for improving the strength of the case 110, and a plurality of beams 117 are provided in parallel to the upper surface of the bottom wall 112 (the surface to be the inside of the case 110). The beams 117 are formed in a slender rod shape, and are provided on the bottom wall 112 so that the longitudinal direction is oriented in the front-rear direction with respect to the case 110, and arranged at equal intervals in the left-right direction.

  The beam 117 is separately formed with respect to the case 110, and is, for example, a hollow prism member having a square cross section. More specifically, the beam 117 has a U-shaped cross section, and the U-shaped opening side is fixed to the bottom wall 112. The beam 117 is made of, for example, an aluminum material or an iron material.

  Between the side wall 115 and the plurality of battery cells 121 (the battery pack 120), a plate-like closed wall 118a connected to the side wall 113 from the side wall 113 is provided on the top surface of the plurality of beams 117. The upper side of the space between the beams 117 is closed by the closed wall 118a.

  Similarly, a plate-like closed wall 118 b connected to the side wall 113 from the side wall 113 is provided on the top surface of the plurality of beams 117 between the side wall 116 and the plurality of battery cells 121 (the assembled battery 120). The upper side of the space between the beams 117 is closed by the closed wall 118 b.

  The structure on the bottom wall 112 side of the case 110 is, for example, a plate-like member raised upward from the bottom wall 112 by a predetermined dimension instead of the beam 117 as described above, and a battery passage 134 described later It may be a wall surface or the like having a communication hole communicating with the

  The battery assembly 120 is formed by providing one or a plurality of cell stacks 120A in which a plurality of battery cells 121 are stacked. In the present embodiment, for example, a plurality of (six) battery cells 121 form one cell stack 120A, and one cell stack 120A is used to form a battery pack 120 (FIG. 1). ).

  The battery cell 121 is in the form of a flat rectangular parallelepiped in the front-rear direction, and includes a positive electrode terminal and a negative electrode terminal protruding outward from the outer case. The battery cell 121 corresponds to the battery of the present invention.

  A plurality of battery cells 121 are stacked in the cell stack 120A, and the stacked battery cells 121 are formed in a battery case. That is, the plurality of battery cells 121 are stacked such that the surfaces orthogonal to the flat direction face each other. The battery case has a case in which the upper surface side and the lower surface side of each battery cell 121 are opened and the periphery of each battery cell 121 is covered.

  In the cell stack 120A, terminals of different polarities in adjacent battery cells 121 are electrically connected by a conductive member such as a bus bar. The connection between the bus bar and the electrode terminal is performed by, for example, screwing or welding. Therefore, the total terminal portions disposed at both ends of the plurality of battery cells 121 electrically connected by the bus bar or the like are supplied with electric power from the outside or discharged toward other electric devices. There is.

  In addition, in the cell stack 120A, a predetermined gap is formed between the plurality of battery cells 121 to be stacked. The gap is formed by a spacer member or the like provided between the battery cells 121. The spacer member can be formed, for example, by providing a partition wall between the battery cells 121 in the battery case and providing unevenness or the like on the partition wall.

  The cell stack 120A (each battery cell 121) is fixed (arranged) on the top surface of the plurality of beams 117, as shown in FIG.

  A circulation passage 130 is formed in the case 110, and is a fluid for heat exchange so as to be in contact with the inner wall surfaces of the battery cells 121 and the case 110 (here mainly the side wall 113, the top wall 111, and the bottom wall 112). Is a passage through which The circulation passage 130 is mainly formed by a series of flow passages connecting the side wall side passage 131, the top wall side passage 133, the battery passage 134, the bottom wall side passage 135, and the blower 140.

  The side wall side passage 131 is orthogonal to both the top wall 111 and the bottom wall 112, extends parallel to the side wall 113, and is a path formed between the plurality of battery cells 121 (the assembled battery 120) and the side wall 113. It is.

  The top wall side passage 133 is a path that is formed between the top wall 111 and the plurality of battery cells 121 (the battery pack 120) and extends parallel to the top wall 111. The side wall side passage 131 and the top wall side passage 133 are connected at the boundary between the top wall 111 and the side wall 113.

  The battery passage 134 is a passage formed by the gap between the adjacent battery cells 121 in the cell stack 120A.

  The bottom wall side passage 135 is a passage formed as a space surrounded by the bottom wall 112, the lower end surfaces of the plurality of battery cells 121, and the beams 117. In addition, the bottom wall side passage 135 includes a space surrounded by the bottom wall 112, the closed walls 118a and 118b, and the beam 117. The bottom wall side passage 135 is a passage formed between the adjacent beams 117 below each battery cell 121.

  The upper side of the battery passage 134 is connected to the top wall side passage 133, and the lower side of the battery passage 134 is connected to the bottom wall side passage 135. Furthermore, the bottom wall side passage 135 is in communication with the suction port of the blower 140.

  The blower 140 is a fluid driving means which is accommodated in the case 110 and forces the fluid for heat exchange to circulate (circulate) in the circulation passage 130. The blower 140 is disposed on the top surface of the closed wall 118 a between the side wall 115 and the battery assembly 120 (battery cell 121). The blower 140 has a motor, a sirocco fan, a fan casing 141, and the like. As a fluid to be circulated in the circulation passage 130 by the blower 140, for example, air, various gases, water, a refrigerant, and the like can be used.

  The motor is an electrical device that rotationally drives the sirocco fan, and is provided above the sirocco fan. The sirocco fan is a centrifugal fan that sucks in fluid in the rotational axis direction and blows out the fluid in the centrifugal direction, and is disposed so that the rotational axis is directed in the vertical direction.

  The fan casing 141 is formed so as to cover the sirocco fan, and serves as a wind guide member that sets the suction direction and the blowing direction of the fluid by the sirocco fan. The fan casing 141 has a suction port that opens on the lower side of the sirocco fan, a blowoff duct 142 that guides the flow of the blown fluid, and a blowoff port 143 that opens at the tip of the blowout duct 142.

  The suction port of the blower 140 is arranged to be connected to the region on the side wall 115 side in the bottom wall side passage 135 through the communication hole provided in the closed wall 118 a. Further, the blowing duct 142 of the blower 140 extends from the side surface of the sirocco fan so as to face the side wall 113 of the case 110.

  As shown in FIG. 1, the internal fin 150 is a fin for promoting heat exchange provided inside the case 110, and is formed of an aluminum material, an iron material or the like which is excellent in thermal conductivity. The internal fin 150 is provided on the side wall 113.

  Here, as the internal fin 150, for example, a straight fin capable of setting a relatively small flow resistance to fluid is adopted. In the straight fins, many thin plate-like fin portions protruding vertically from the thin plate-like substrate portion are arranged in parallel to form a fin in which a passage for fluid is formed between the fin portions. The internal fin 150 is not limited to the straight fin but may be another corrugated fin (with or without a louver), an offset fin or the like.

  The fin portion of the internal fin 150 vertically protrudes from the substrate portion toward the plurality of battery cells 121, and the protruding tip portion has a plurality of battery portions so that more fluid can flow inside the fin portion. It extends to a position close to the side of the cell 121. Further, the plate surface of the fin portion is set to be inclined from the side wall 115 to the side wall 116 from the lower side to the upper side in the vertical direction, and is blown out from the blower 140 and flows into the side wall side passage 131 Fluid is guided to the ceiling wall side passage 133 (FIG. 2).

  The detector 160 is a device that detects the temperature of a predetermined battery cell 121 among the plurality of battery cells 121. The predetermined battery cell 121 can be at least one place as a portion where a representative temperature can be obtained among the plurality of battery cells 121.

  Here, in order to increase the reliability of temperature detection, the detector 160 is, for example, two battery cells 121 at both end positions of the battery cells 121 in the stacking direction, and one battery cell at an intermediate position in the stacking direction. It is located at 121 (3 places in total). The detector 160 can be configured by a temperature sensor, a temperature detection line for signal output, and the like. The temperature signal (battery temperature) of the battery cell 121 detected by the detector 160 is output to a battery management unit 170 described later. The detector 160 is not limited to the temperature sensor, and may be a current sensor that indirectly detects the temperature of the battery cell 121.

  A battery management unit (Battery Management Unit) 170 is configured to be communicable with various electronic control devices mounted on a vehicle. The battery management unit 170 is a device that manages at least the storage amount of the battery cell 121, and is an example of a battery control unit that performs control related to the battery cell 121. Further, the battery management unit 170 monitors the current, voltage, temperature and the like related to the battery cell 121, and manages an abnormal state, a leak and the like of the battery cell 121.

  Further, the battery management unit 170 receives a signal related to the current value detected by the current sensor. Similar to the vehicle ECU, the battery management unit 170 includes an input circuit, a microcomputer, an output circuit, and the like. Battery information is stored as data in the storage means of the microcomputer. The data of the stored battery information is, for example, the battery voltage, the charging current, the discharging current, and the battery temperature in the battery pack 100A.

  In addition, the battery management unit 170 also functions as a control unit that controls the operation (rotational speed) of the blower 140. The battery management unit 170 controls the temperature of the battery cell 121 by controlling the rotational speed of the blower 140 in accordance with the battery temperature detected by the detector 160. Details of control contents of the battery management unit 170 will be described later.

  The operation of the battery pack 100A configured as described above will be described with reference to FIGS.

  The battery cell 121 generates heat at the time of output from which current is taken out and at the time of input to be charged. In addition, the battery cell 121 is affected by the temperature outside the case 110 according to the season, the air conditioning condition of the vehicle interior, and the like. The battery management unit 170 constantly monitors the battery temperature of the battery cell 121 by the detector 160, and controls the operation of the blower 140 based on the battery temperature. First, the basic operation contents (fluid circulation) of the battery pack 100A when the blower 140 is operated will be briefly described with reference to FIGS.

  When the blower 140 is operated, fluid in the case 110 circulates in the circulation passage 130. That is, the fluid sucked from the suction port of the blower 140 and blown out from the blowout port 143 through the blowout duct 142 first flows into the side wall side passage 131.

  Then, the fluid that has flowed into the side wall side passage 131 smoothly flows from the lower side (bottom wall 112 side) to the upper side (top wall 111 side) along the inclined fin portion of the internal fin 150. In the side wall side passage 131, the heat of the fluid accompanied with the flow velocity is transferred to the inner fin 150 and further released to the outside through the side wall 113.

  Next, the fluid flows into the top wall side passage 133 from the internal fins 150. The fluid that has flowed into the ceiling wall side passage 133 spreads in the ceiling wall side passage 133. The heat of the fluid flowing into the top wall side passage 133 is transferred to the top wall 111 and released to the outside.

  Next, the fluid that has flowed into the top wall side passage 133 passes through the battery passage 134 formed between the battery cells 121 and reaches the bottom wall side passage 135. Here, the side wall side passage 131 and the top wall side passage 133 become a positive pressure space by blowing out the blower 140, and the bottom wall side passage 135 becomes a negative pressure space by suction of the blower 140. Therefore, movement of fluid from the top wall side passage 133 side to the bottom wall side passage 135 side is continuously performed by the pressure difference between the two. Then, when the fluid passes through the battery passage 134, the heat of each battery cell 121 is transferred to the fluid.

  Next, the fluid that has flowed into the bottom wall side passage 135 moves along the longitudinal direction of each beam 117 and reaches the suction port of the blower 140. Then, the heat of the fluid flowing into the bottom wall side passage 135 is transmitted to the bottom wall 112 and released to the outside.

  As described above, by circulating the fluid through the circulation passage 130 in the case 110, the heat of the fluid, that is, the heat of the battery cell 121 is mainly released from the wide area top wall 111 and the bottom wall 112 to the outside. Ru. At this time, heat exchange (heat dissipation from the side wall 113) is promoted by the internal fins 150. Thus, each battery cell 121 is effectively cooled and adjusted to an appropriate temperature.

  In the battery pack 100A that operates in this manner, in the present embodiment, the battery management unit 170 controls the operation (number of rotations) of the blower 140 based on the control flow shown in FIG. 3.

  First, in step S <b> 100, the battery management unit 170 determines the battery temperature of the battery cell 121 from the temperature signals obtained from the plurality of detectors 160. Here, among the plurality of temperature signals obtained from the plurality of detectors 160, the maximum temperature signal is adopted and acquired as the battery temperature.

  Next, in step S110, the battery management unit 170 sets a target rotational speed St of the blower 140. The target rotation number St is set, for example, from the characteristic graph of the target rotation number shown in FIG. The characteristic diagram of the target rotational speed is a relation between the battery temperature and the target rotational speed St of the blower to be set in advance. In the region where the battery temperature is relatively low, the characteristic diagram of the target rotation number is provided such that the target rotation number St is constant, and the target rotation number St is set higher as the battery temperature becomes higher. The battery management unit 170 sets the number of rotations corresponding to the battery temperature acquired in step S100 as the target number of rotations St.

  Next, in step S120, battery management unit 170 determines commanded rotation number Si based on target rotation number St. As shown in FIG. 5, the commanded rotational speed Si is such that the target rotational speed St increases or decreases with a predetermined amplitude (one-sided amplitude) A during a predetermined period T. The predetermined cycle T is a predetermined value, and can be set, for example, according to the heat capacity of the battery cell 121. As the heat capacity is larger and the temperature change is slower, the cycle T may be set larger. Further, the predetermined amplitude A is a value determined in advance similarly to the above-described cycle T, and can be set, for example, according to the dimension in the stacking direction of the battery cell 121. The larger the dimension in the stacking direction, the larger the amplitude should be set.

In the present embodiment, the commanded rotational speed Si is, for example, a sine waveform, and when an elapsed time is t,
Commanded rotational speed Si = Target rotational speed St + sin (t / T)
It is calculated as

  Then, in step S130, battery management unit 170 executes increase / decrease control to increase / decrease target rotational speed St. That is, the rotation speed of the blower 140 is controlled so that the command rotation speed Si obtained in step S120 is obtained.

  According to the present embodiment, as described above, by increasing or decreasing the target rotational speed St at a predetermined cycle T, as shown in FIGS. 6 and 7, the circulation passage 130 can be formed for the plurality of battery cells 121. Strong and weak repetitions can be added to the flow velocity of the circulating fluid. That is, as compared with the case where the fluid is continuously circulated at a constant flow velocity by fixing the target rotation speed St, the plurality of battery cells 121 alternately alternate with respect to the side relatively far from and close to the blower 140. Can have an auxiliary function of supplying fluid. Therefore, the fluid can be more uniformly circulated in the entire plurality of battery cells 121, and temperature variation of the plurality of battery cells 121 can be suppressed. In the present embodiment, the temperature variation of the plurality of battery cells 121 is suppressed by controlling the number of rotations of the blower 140, and it is not necessary to provide a dedicated duct, a straightening vane, or the like in the fluid circulation passage 130.

  In addition, the flow of fluid can be made turbulent by giving strength to the flow velocity of the fluid. Therefore, it is possible to enhance the heat transfer performance by enhancing the heat transfer coefficient between the plurality of battery cells 121 and the fluid by the turbulent flow effect of the fluid.

Second Embodiment
A second embodiment (flow chart) is shown in FIG. In the second embodiment, although the configuration of the battery pack 100A is basically the same as that of the first embodiment, the control content is changed. The flowchart of the second embodiment is obtained by adding step S115 to the flowchart described in FIG.

  In FIG. 8, after step S100 and step S110, the battery management unit 170 determines in step S115 whether or not the temperature variation (temperature difference) between at least two battery cells 121 is larger than a predetermined value. Determine if In step S115, for example, among the temperature signals detected by the three detectors 160, the difference between the maximum value and the minimum value is acquired as the temperature variation.

  Then, when the temperature variation in step S115 exceeds the predetermined value, the process proceeds to step S120 and step S130 to execute increase / decrease control of the target rotation number St. If it is determined in step S115 that the result is negative, the present control is ended.

  Thus, the increase / decrease control may be executed when the temperature variation (temperature difference) between the battery cells 121 is larger than the predetermined value, so that the temperature variations of the plurality of battery cells 121 can be effectively suppressed. .

Third Embodiment
A battery pack 100A of a third embodiment is shown in FIGS. The configuration of the battery pack 100A according to the third embodiment is basically the same as the first and second embodiments, but the control content is changed (FIG. 10).

  In the present embodiment, as shown in FIG. 9, among the plurality of battery cells 121, the battery cell 121 on the side far from the blower 140 is referred to as a battery cell 121A, and is relative to the blower 140. The battery cell 121 on the near side is referred to as a battery cell 121B. Each battery cell 121A, 121B is provided with a detector 160.

  Further, the flowchart (FIG. 10) of the present embodiment is obtained by adding step S125, step S140, step S151, and step S152 to the flowchart (FIG. 8) of the second embodiment. The predetermined value of the determination threshold in step S115 is a first predetermined value, and the determination threshold in step S125 is a second predetermined value provided on the side larger than the first predetermined value. (Second predetermined value> first predetermined value).

  In FIG. 10, after performing step S100 and step S110, battery management unit 170 determines in step S115 whether or not the temperature variation of a plurality of (here, three) battery cells 121 is larger than a first predetermined value. If the determination is affirmative, the process proceeds to step S120. If it is determined in step S115 that the result is negative, the present control is ended.

  After the determination process of the command rotational speed Si in step S120, the battery management unit 170 further determines in step S125 whether or not the temperature variation of the plurality of battery cells 121 is larger than a second predetermined value.

  If NO in step S125, that is, if there is a temperature variation between the plurality of battery cells 121 between the first predetermined value and the second predetermined value, the battery management unit 170 performs the target in step S130. The increase / decrease control to increase / decrease the rotational speed St is executed. Here, in the present embodiment, in order to determine the command rotational speed Si with respect to the target rotational speed St, for example, one that draws a rectangular waveform is used as shown in FIG.

  On the other hand, if an affirmative determination is made in step S125, that is, if the temperature variation among the plurality of battery cells 121 exceeds the second predetermined value, the battery management unit 170 proceeds to step S140, step S151, and step S152. Then, the battery management unit 170 compares the temperatures of the battery cells 121A and 121B on the relatively far side or the relatively near side with respect to the blower 140, and the target for the increase / decrease control of the target rotational speed St. The increase / decrease control is performed in consideration of the time ratio of the two when increasing or decreasing the rotational speed St.

  That is, in step S140, the battery management unit 170 compares the temperature of the battery cell 121A relatively far to the blower 140 with the temperature of the battery cell 121B relatively close. That is, when it is determined that the temperature of the battery cell 121A is higher than the temperature of the battery cell 121B, the process proceeds to step S151. In step S151, as shown in FIG. 12, the battery management unit 170 causes the time for increasing the target rotation speed St to be longer than the time for decreasing the target rotation speed St at the command rotation speed Si.

  In this case, as shown in FIG. 14, the fluid flow rate toward the battery cell 121A side is larger than the fluid flow rate toward the battery cell 121B side.

  In step S140, when battery management unit 170 determines that the temperature of battery cell 121B is higher than the temperature of battery cell 121A, the process proceeds to step S152. In step S152, as shown in FIG. 13, the battery management unit 170 makes the time for decreasing the target rotation speed St longer than the time for increasing the target rotation speed St at the command rotation speed Si.

  In this case, as shown in FIG. 15, the fluid flow rate toward the battery cell 121B side is larger than the fluid flow rate toward the battery cell 121A side during the increase / decrease control.

  Thereby, when the temperature difference between the plurality of battery cells 121 is larger than the second predetermined value, the time ratio for increasing or decreasing the target rotation speed St according to the position on the high temperature side between the battery cells 121. By making the size of the battery cell larger, it is possible to supply more fluid to the battery cell 121A (121B) on the high temperature side. Therefore, temperature variations of the plurality of battery cells 121 can be further effectively suppressed.

  Also, since the characteristic diagram for determining the commanded rotational speed Si is a rectangular waveform, a sine waveform is drawn as in the first and second embodiments described above, and the commanded rotational speed Si is continuously changed. Control is easier than in the case of

Fourth Embodiment
A battery pack 100B of the fourth embodiment is shown in FIGS. In the battery pack 100B of the fourth embodiment, a plurality of combinations of cell stacks and blowers are set in the case 110 with respect to the battery packs 100A of the first to third embodiments, and two pairs are set here. It has become a thing.

  As shown in FIG. 16, among the plurality (two sets) of the cell stack and the fan, the first combination is a combination of the first cell stack 120A and the first fan 140A, The second combination is a combination of the second cell stack 120B and the second fan 140B. The first and second combination bodies are arranged, for example, symmetrically in the case 110. A battery assembly 120 is formed by the first cell stack 120A and the second cell stack 120B.

  A sidewall passage 132 is formed between the second cell stack 120B and the sidewall 114. Further, the outlet 143 of the second fan 140B faces the side wall 114 side. The first blower 140A mainly serves as a blower that circulates a fluid through the circulation passage 130 corresponding to the region of the cell stack 120A on the side wall 113 side. Further, the second fan 140B is mainly a fan that circulates the fluid in the circulation passage 130 corresponding to the region of the cell stack 120B on the side wall 114 side.

  In the boundary area (between) of the first combination (first cell stack 120A) and the second combination (second cell stack 120B), there is no setting of a partition wall or the like for dividing the two, and the case In the circulation passage 130 in 110, the fluid can be mixed flow between the two combinations. That is, the fluid flowing through the area of the first combination can also flow through the area of the second combination, and conversely, the fluid flowing through the area of the second combination also flows into the area of the first combination It is possible to distribute.

  The side fins 114 are provided with internal fins 151 similar to the internal fins 150 of the side walls 113. Further, the battery management unit 170 is disposed, for example, between the first fan 140A and the second fan 140B.

  In the present embodiment, the increase / decrease control of the target rotation speed St is executed in the same manner as the first embodiment (FIG. 3) or the second embodiment (FIG. 8). That is, as shown in FIG. 17, the same command rotational speed Si is determined for the target rotational speed St for each of the blowers 140A and 140B.

  If the target rotation speed St is increased, as shown in FIG. 18, the fluid is easily supplied to the battery cell 121 on the side relatively distant from the blowers 140A and 140B. Further, as shown in FIG. 19, when the target rotation speed St is reduced, the fluid is easily supplied to the battery cell 121 on the side relatively close from the blowers 140A and 140B. And, such fluid supply is alternately repeated.

  Therefore, even in the case where a plurality of combinations are provided in the case 110, the same effects as those of the first and second embodiments can be obtained.

Fifth Embodiment
The battery pack 100B of the fifth embodiment is shown in FIGS. The configuration of a battery pack 100B according to the fifth embodiment is the same as the fourth embodiment, except that the control content is changed (FIG. 20).

  The flowchart (FIG. 20) of this embodiment is obtained by changing step S130 to steps S160 and S170, as compared with the flowchart (FIG. 8) of the second embodiment.

  After determining the command rotational speed Si in steps S100 to S120, the battery control unit 170 sets the phase of the rotational speed increase / decrease in each of the first fan 140A and the second fan 140B in step S160.

  Specifically, battery control unit 170 determines the phase of command rotational speed Si in first fan 140A and the phase of command rotational speed Si in second fan 140B based on a predetermined characteristic diagram shown in FIG. Set to shift. The phase shift is, for example, antiphase.

  Then, in step S170, the battery management unit 170 executes increase / decrease control of the target rotation speed St with respect to each of the blowers 140A and 140B in a phase-shifted state.

  As described in the fourth embodiment, fluid can be mixed between the first cell stack 120A and the second cell stack 120B. And in this embodiment, the phase of increase / decrease in the rotation speed of each air blower 140A, 140B in each combination is shifted.

  For example, as shown in FIG. 22, when the rotational speed of the first fan 140A is increased, the fluid is easily supplied to the battery cells 121 of the cell stacks 120A and 120B on the side far from the first fan 140A. In addition, when the rotational speed of the second fan 140B is decreased with respect to the first fan 140A, the fluid is easily supplied to the battery cells 121 of the cell stacks 120A and 120B closer to the second fan 140B.

  On the other hand, as shown in FIG. 23, when the rotational speed of the first fan 140A is decreased, the fluid is easily supplied to the battery cells 121 of the cell stacks 120A and 120B on the far side closer to the first fan 140A. In addition, when the rotational speed of the second fan 140B is increased with respect to the first fan 140A, the fluid is easily supplied to the battery cells 121 of the cell stacks 120A and 120B on the side far from the second fan 140B.

  And the operation state of FIG. 22, FIG. 23 will be repeatedly performed alternately. Therefore, in the case where a plurality of combinations of cell stacks (120A, 120B) and blowers (140A, 140B) are provided in case 110, the entire plurality of battery cells 121 in the plurality of cell stacks 120A, 120B. Fluid can flow more uniformly. Therefore, the temperature variation of the plurality of battery cells 121 can be effectively suppressed.

  In addition, the shift of the phase of the command rotational speed Si by both the blowers 140A and 140B is not limited to the case of the opposite phase as described above, and can be appropriately set to be a predetermined shift.

(Other embodiments)
Although the preferred embodiments of the present invention have been described in the above embodiments, the present invention is not limited to the above embodiments and can be variously modified and implemented without departing from the spirit of the present invention. It is. The structures of the aforementioned embodiments are merely illustrative, and the scope of the present invention is not limited to the scope of these descriptions. The scope of the present invention is defined by the description of the claims, and further includes all modifications within the meaning and scope equivalent to the descriptions of the claims.

  The essential configuration of the present invention is the case 110, the battery pack 120, the circulation passage 130, the blower 140, the detector 160, and the battery management unit (control unit) 170, and the internal fins 150 are set as needed. It is also good.

  Further, the fluid in the case 110 of each of the embodiments described above passes through the circulation passage 130, the blower 140 (140A, 140B), the side wall side passages 131 (132), the top wall side passage 133, the battery passage 134 and the bottom wall side The circulation is made in the order of the passage 135, but it may be reversed.

  Moreover, although the battery pack 100A, 100B of each said embodiment was made to circulate a fluid through the circulation passage 130 using one fan 140 or two fans 140A, 140B, three or more fans can be used. The fluid may be circulated in the circulation passage 130.

  In addition to the sirocco fan described in each of the above-described embodiments, an axial fan, a turbofan, or the like can be used as the fan incorporated in the blower 140 (140A, 140B) provided inside the case 110.

  Further, in setting the internal fins 150, the fins may be integrally formed on the side walls 113 and 114.

  In each of the above embodiments, the case (casing) 110 forms a hexahedron or a rectangular parallelepiped, but the casing included in the invention is not limited to this shape. For example, the case 110 may be a polyhedron having six or more faces, or at least one face may be a face including a curved surface. In the case 110, the top wall 111 may be formed in a dome shape including a curved surface, or the vertical cross-sectional shape of the case 110 may have a trapezoidal shape. Further, in the case 110, the top wall 111 is a wall in a positional relationship facing the bottom wall 112, and the shape thereof may include any shape of a flat surface and a curved surface. In the case 110, the side walls 113 to 116 may be walls extending from the bottom wall 112 in a direction intersecting with the bottom wall 112, or walls extending from the top wall 111 in a direction intersecting with the top wall 111. It may be The boundary between the top wall 111 and the side walls 113 to 116 in the case 110 may form a corner or may form a curved surface. The boundary between the bottom wall 112 and the side walls 113 to 116 in the case 110 may form a corner or may form a curved surface.

  In each of the above embodiments, the number of cell stacks 120A (120B) included in the battery packs 100A and 100B is one or two, but the number is not limited to this. That is, when only one cell stack 120A (120B) included in battery pack 100A, 100B is housed inside case 110, when a plurality of cell stacks 120A (120B) are installed side by side in one direction, they cross the one direction. This also includes the case where a plurality of units are installed side by side in other directions.

100A, 100B battery pack 110 case (housing)
121 battery cells
130 circulation passage 140 blower 160 detector 170 battery management unit (control unit)

Claims (3)

With multiple batteries (121),
A housing (110) for housing a plurality of the batteries;
A circulation passage (130) formed in the housing and passing through a plurality of batteries and a heat exchange fluid in contact with the inner wall surface of the housing;
A fan (140) housed in the housing and circulating the fluid in the circulation passage;
A detector (160) for detecting a temperature of a predetermined one of the plurality of batteries;
A control unit (170) configured to control the number of rotations of the blower according to the temperature of the battery detected by the detector;
The control unit is configured to execute increase / decrease control to increase / decrease the target rotational speed at a predetermined cycle (T) with respect to the target rotational speed (St) set according to the temperature of the battery .
The detector (160) is adapted to detect the temperature of at least two of the cells;
The control unit
Executing the increase / decrease control when the temperature difference between at least two of the batteries is larger than a predetermined value,
When it is determined that the temperature difference between the batteries is larger than a second predetermined value provided on the side larger than the first predetermined value when the predetermined value is a first predetermined value,
Comparing the temperature of the battery located far from the blower relative to the battery located closer to the fan;
If the temperature of the battery on the far side is higher, the time ratio for increasing the target rotational speed within the predetermined cycle is increased;
When the temperature of the near side battery is higher, the time ratio for decreasing the target rotational speed within the predetermined cycle is increased . A plurality of combinations of the plurality of batteries and the blower are provided in the housing,
The flow of the fluid can be mixed between the plurality of sets,
2. The battery pack according to claim 1 , wherein the control unit shifts the phase of increase / decrease in rotational speed of each of the blowers in the plurality of sets when executing the increase / decrease control. The battery pack according to claim 2 , wherein the control unit sets the phase opposite to each other when shifting the phase.

Images