JP4790975B2 - Battery cooling system, power supply device including the same, and electric vehicle - Google Patents

Description

  The present invention relates to a battery cooling system, in particular, a system for uniformly cooling a large number of batteries constituting a power supply device for various electric vehicles such as an electric four-wheeled vehicle (electric vehicle) and an electric two-wheeled vehicle (including an electric scooter), and the battery. The present invention relates to a power supply device provided with a cooling system, and an electric vehicle equipped with the power supply device.

  In recent years, research and development of electric vehicles has been actively conducted in both automobiles and motorcycles as a response to environmental problems such as harmful exhaust gas and noise of automobiles driven by gasoline engines. In. The electric vehicle includes a traveling wheel suspended from the vehicle body via a shock absorber, similar to a conventional automobile having a gasoline engine as a driving source, and the traveling wheel is driven by a power transmission device having an electric motor as a driving source. Driven by rotation. The electric motor is supplied with power from a power supply device.

  Such electric vehicles are particularly demanded by the power supply device for high output, high performance, light weight, and compactness. In particular, a high-performance battery such as a nickel-hydrogen battery, a nickel-cadmium battery, or a lithium ion battery is required for a power supply device for an electric motorcycle. In addition, a plurality of cells are connected in series as a battery to form one battery module, and a plurality of the battery modules are connected in series or connected in parallel as a group. The power supply device is housed in a power supply with increased supply power. Hereinafter, a cell or a battery module used in such a power supply device is simply referred to as a battery.

  By the way, such a power supply apparatus has the following defects. Regardless of the type of such power supply device, heat is generated when the battery is discharged (when the power supply is used) or charged. Moreover, even if the calorific value of each of the many batteries constituting the power supply device is equal, a large temperature difference is likely to occur between the batteries during charging and discharging. For example, a battery located in the center of the power supply device is more likely to have heat than a battery located on the outer wall surface side, and similarly, a battery located on the upper surface side of the power supply device is more likely to have heat than a battery located on the lower surface side. . As a result, a considerable temperature difference occurs between the plurality of batteries.

  Such a temperature difference makes the battery discharged or charged unevenly. That is, the temperature difference between the batteries causes a decrease in performance of the power supply device. Therefore, in order to prevent the occurrence of a temperature difference that adversely affects the performance of the power supply device, it is necessary to suppress the temperature rise of each battery constituting the power supply device and to equalize the temperature. Has been developed in various ways. For example, in order to guide the cooling air from the outside air to each battery as evenly as possible, means are provided such as providing a complicated ventilation path and intake / exhaust ports.

  As such a conventional technique, for example, there is a battery temperature adjusting device described in Patent Document 1. It holds an elongated battery module (consisting of a plurality of batteries connected in series) in each battery holding chamber of a honeycomb structure battery holder, and takes in the gap between the inner wall of the battery holding chamber and the battery module to the outside air A main passage for cooling air flowing in from the opening is used, and a gap in the double-structured vertical partition that forms the battery holding chamber is used as a bypass passage to the center in the longitudinal direction. And since the temperature rises as the cooling air passing through the main passage undergoes heat exchange with the battery, the air before heat exchange is supplied to the battery downstream from the central portion through the bypass passage, The temperature difference between the batteries is reduced.

  Further, in Patent Document 2, two batteries are arranged in a hollow battery housing member whose both end openings are closed by side plates with the terminal sides facing each other, and six battery housing members are arranged in parallel. The battery frame is configured by being connected and fixed, and the opening provided in the upper part of the battery frame is closed by a cover having a rib protruding downward, and the rib bisects the battery storage space in the battery frame. Such a battery fixing structure is disclosed. A battery air-conditioning method is also disclosed in which cooling air is efficiently circulated by the air-conditioning unit provided with the blower fan and the heat exchanger in the divided battery storage space to cool the battery. .

  Furthermore, Patent Document 3 discloses an electric motorcycle in which a low floor footboard is provided between a traveling handle and a seat, a battery storage chamber is formed below the footboard, and a battery is mounted in the battery storage chamber. A battery cooling structure is disclosed. An opening for introducing traveling wind into the battery chamber is formed in the upper part of the battery storage chamber on the front wheel movable fender side, and a cooling fan is disposed in an exhaust port provided at the rear of the battery storage chamber. It also describes that when the battery is charged, it is cooled by the cooling fan until the battery reaches a charging start upper limit temperature or lower.

  Furthermore, in Patent Document 4, in a battery device in which a plurality of batteries are housed in a rectangular parallelepiped battery frame, a first cooling fan is provided on the front portion of the battery frame, and a second cooling fan is provided on the rear upper surface. Each of the first and second cooling fans takes air from the front of the vehicle body and sends it into a passage formed between the batteries housed in the battery frame, and the cooling air for cooling the battery is provided on the outer peripheral side surface of the battery frame. It is disclosed that the batteries constituting the battery device (power supply device) are uniformly cooled so that the batteries are discharged to the outside from the air outlet.

Japanese Patent Laid-Open No. 10-252466 Japanese Patent Laid-Open No. 11-67178 JP-A-11-255165 JP 2003-2273 A

  However, in the battery temperature adjusting device described in Patent Document 1, it is necessary to form a main passage and a bypass passage for cooling air in the battery holder, so that the volume of the battery holder is considerably larger than the battery storage volume. There is a problem that the installation space of the battery holder as a power supply device becomes large. In addition, although the temperature difference between the batteries constituting each battery module in the battery holder can be reduced, the difference in cooling effect due to the position in the longitudinal direction of the battery constituting each elongated battery module remains, Not all batteries can be cooled to a uniform temperature.

Moreover, in the apparatus and the battery air conditioning method described in Patent Document 2, the size is increased to form a passage for circulating the cooling air in the battery frame, and the cost is increased because the air conditioning unit is used. Moreover, the temperature of each battery arranged along the circulation path cannot be uniformly cooled only by circulating the cooling air, and a considerable temperature difference occurs between the upstream side and the downstream side of the cooling air. There's a problem.
The battery cooling structure described in Patent Document 3 can be made relatively compact. However, the traveling air in the battery storage chamber or the cooling air sucked in by the cooling fan is introduced into the exhaust side and the exhaust side. However, since the temperature of the cooling air is higher, each battery in the battery housing chamber cannot be cooled uniformly.

  Furthermore, in the apparatus described in Patent Document 4, a cooling fan that takes in air from the front of the vehicle body is installed at two locations on the front and rear of the battery frame, so that installation space is required and layout restrictions are also imposed. growing. In addition, the air flow path in the battery frame by both cooling fans is common, cooling air is sent from opposite directions and discharged to the outside from the exhaust port on the outer peripheral side surface of the battery frame, so the cooling effect is fairly uniform. However, if a part of the cooling air collides in the passage and does not flow smoothly, the cooling efficiency is reduced, and noise due to driving of the two cooling fans is also assumed.

As described above, in the battery cooling device or the cooling method in the conventional electric vehicle or the like, it is difficult to efficiently and uniformly cool a large number of batteries constituting the power supply device, and the cooling mechanism is complicated and becomes large. There was a problem of high costs.
The present invention has been made to solve various problems caused by the battery cooling mechanism or the cooling method in such a conventional power supply apparatus, and in order to maximize the output capability of the battery in the power supply apparatus, An object of the present invention is to efficiently and uniformly cool each battery so as to eliminate a temperature difference between the batteries during charging and discharging, and to simplify the structure, reduce the size, and reduce the price.
Another object of the present invention is to provide such a battery cooling system, a power supply device including the battery cooling system, and an electric vehicle equipped with the power supply device.

In order to achieve the above object, a battery cooling system according to the present invention includes a power supply unit in which a plurality of batteries are accommodated in a case with a space around each adjacent battery, and a vent hole provided in the case of the power supply unit. It is connected, and a cooling fan comprising a cooling fan for a first blowing operation of feeding air into the casing from within the casing and the cooling fan for a second blowing operation of sucking out air.
The case is provided with intake / exhaust holes on a surface different from the surface provided with the vent holes, and a plurality of temperature sensors are disposed at different positions in the case.
Furthermore, based on the information of the temperature detected by the plurality of temperature sensors, the air blowing operation of the cooling fan, blowing operation by the cooling fan for a second blowing operation from the air operation by the cooling fan for the first blowing operation to, or is provided with a said second cooling fan drive control means to automatically switch from the blowing operation by the cooling fan for blowing operation to blow operation by the first cooling fan for blowing operation.

Moreover, the cooling fan drive control means further the blowing operation of the cooling fan, at predetermined time intervals from the blowing operation by the cooling fan for the first blowing operation to blow operation by the second cooling fan for blowing operation , or still better when to have even the second function which automatically switches from the blowing operation by the cooling fan for blowing operation to blow operation by the first cooling fan for blowing operation.

In these battery cooling systems, it is preferable to provide the vent hole in the upper part of one end surface of the case and to provide a plurality of intake / exhaust holes in the lower surface of the case .
A power supply device according to the present invention includes any one of the battery cooling systems described above.
An electric vehicle according to the present invention is equipped with the power supply device.

According to the battery cooling system of the present invention, when each battery constituting the power supply unit is cooled during charging and discharging, air is supplied into the power supply unit based on information from a plurality of temperature sensors arranged at different positions in the case. The air blowing operation by the first air blowing operation cooling fan and the air blowing operation by the second air blowing operation cooling fan that sucks air out of the case are automatically switched to cool each battery efficiently and uniformly. The temperature difference between the batteries can be almost eliminated, and the output capability of the battery can be maximized. In addition, the structure is simple and can be implemented at low cost, and the size and price can be reduced.
And the power supply device with the charging / discharging efficiency provided with the battery cooling system and the electric vehicle with the high power utilization efficiency equipped with the power supply device can be realized.

Hereinafter, the best mode for carrying out the present invention will be specifically described with reference to the drawings.
FIG. 1 is a side view of an electric motorcycle equipped with a power supply device equipped with a battery cooling system showing an embodiment of the present invention, and FIG. 2 is a schematic view of the electric motorcycle viewed from the rear side excluding rear wheels. .
First, the outline of an electric motorcycle embodying the present invention will be described with reference to FIGS.
This electric motorcycle is a kind of electric vehicle, and is equipped with a power supply unit composed of a battery composed of a plurality of cylindrical battery modules each having a nickel-hydrogen battery as a cell, and a power supply device including a cooling system for the battery.

As shown in FIGS. 1 and 2, the electric motorcycle 1 includes a front wheel 4 and a rear wheel 5 suspended on a main frame 3 before and after a vehicle body 2 in the same manner as a motorcycle such as a motorcycle driven by a gasoline engine. There is a seat 7 on which the driver is seated in the middle of the vehicle body 2 at the slightly rear part. The front wheels 4 are steered by a handle 6, and the rear wheels 5 are not driven by an engine but are driven to rotate by a driving electric motor 8 via a power transmission device 9.
Further, the display panel 16 provided at the center portion of the handle 6 is provided with a display meter indicating a running speed, a remaining battery capacity meter, various switches for operating the mounted devices, and the like. 2 is provided with a main switch (key switch) 15 for turning on and off the main power.

A lower part of the seat 7 is provided with a control device 10 centering on a CPU for controlling the operation of the electric motor 8 for traveling mounted on the electric motorcycle 1 and various devices and various sensors.
A power supply device 11 including a power supply unit 20 that houses a plurality of batteries and a plurality of temperature sensors, which will be described later, is mounted on the lower portion of the vehicle body 2 on the main frame 3 in the front-rear direction middle portion. In addition, a cooling unit 12 containing a cooling fan 13 is disposed at the rear part in the traveling direction of the vehicle body 2, and is connected to the power supply unit 20 by an air duct 14.

  The power supply device 11 supplies electric power to the traveling electric motor 8, converts electric energy into mechanical motion by the traveling electric motor 8, and efficiently rotates the rear wheel 5 via the power transmission device 9 having a transmission. To drive. As shown in FIG. 2, a charger 17 and a motor drive circuit 18 are arranged on both sides of the power supply device 11, and a radiator plate 19 is provided below the charger 17 and the motor drive circuit 18. The heat radiating plate 19 releases heat generated when the charger 17 and the motor drive circuit 18 operate.

The power supply device 11 will be described in detail later, but a plurality of batteries are connected in series using a cable that prevents power transmission loss, and the plurality of series-connected batteries are further connected in parallel to provide a power supply unit. The power supply unit 20 is fixed to the bifurcated portion 3a of the main frame 3 of aluminum die casting.
The lower surface of the power supply device 11 is covered with a gap by an under cover 29 attached to the main frame 3.
The control device 10 is stored in the memory of the CPU based on, for example, accelerator opening information obtained by operating an accelerator grip (not shown) provided on the handle 6, detection signals from various sensors arranged in various mounted devices, and the like. The control is performed according to the program, and the temperature of the plurality of batteries in the traveling electric motor 8 and the power supply unit 20 is made uniform.

  3 and 4 are a side view and a plan view of the battery cooling system in which the power supply unit 20 and the cooling unit 12 constituting the power supply device 11 mounted on the above-described electric motorcycle 1 are connected via the air duct 14. FIG. 5 is a cross-sectional view showing an example of the arrangement of a large number of batteries in the power supply unit 20.

  The power supply unit 20 is provided with a partition plate 22 having a large number of air holes 22a in the upper part of the case 21, and a space serving as an air flow passage is formed on the upper side. On the lower side of the partition plate 22, a plurality of (many) batteries 23 are stacked in a plurality of stages in parallel with the traveling direction of the electric motorcycle so that when viewed from the front, a staggered shape is obtained as shown in FIG. The horizontal positions of the batteries 23 in each stage are stored while being shifted alternately. A plurality of elastic rings 24 are attached to the outer periphery of each battery 23 in order to make it easier for the cooling air to pass between the multiple batteries 23 stacked and stored in a zigzag manner. The elastic ring 24 serves as a spacer that provides a space between the batteries, and serves to absorb the vibration of the vehicle body and prevent the batteries from colliding with each other and being damaged.

A plurality of temperature sensors 25 a to 25 e are arranged in the case 21 of the power supply unit 20 in order to detect the temperature of the battery 23. This temperature sensor is ideally installed for each battery cell of each battery 23, or when a battery module in which a plurality of battery cells 23a are connected in series as shown in FIG. In order to make A and B uniform, it is desirable to install at least the front end portion, the intermediate portion, and the rear end portion.
However, in consideration of manufacturing cost, simplification of wiring, and the like, in the example shown in FIG. 5, the upper portion (25a) of the stacked battery 23 is the central portion in the lateral direction of the many batteries 23 housed in the case 21. , The middle part (25b), the lower part (25c), and the two most distant places (25d, 25e) in the lateral direction. The code in parentheses is the code of the temperature sensor installed there. The two temperature sensors 25d and 25e on both sides may be omitted, and only the upper, middle, and lower temperature sensors 25a to 25c may be provided.

In short, the number of temperature sensors to be installed may be determined in accordance with the manufacturing cost and the cooling capacity of the cooling unit 12 to be described later for making the temperature of each battery 23 uniform. As this temperature sensor 25a-25e, what can detect temperature information as an electrical signal, such as a thermistor and a thermocouple, is used.
As shown in FIG. 3, at both ends of the case 21 of the power supply unit 20 in the longitudinal direction, battery end insulating plates 38 made of a resin having good heat conductivity are provided.
Further, as shown in FIGS. 3 and 5, the bottom portion of the case 21 is formed by two gas-liquid separation plates 26 and 27 provided in parallel in the vertical direction with a slight gap therebetween. The two gas-liquid separation plates 26 and 27 are formed with a plurality of (many) intake / exhaust holes 26a and 27a at positions where the positions on the plane are shifted in the front-rear and left-right directions.

The outside air is sucked into the case 21 as cooling air through the intake / exhaust holes 26a and 27a, or the cooling air sent into the case 21 from the air hole 21a shown in FIG.
The intake / exhaust holes 26a and 27a of the gas-liquid separation plates 26 and 27 are displaced in the plane direction and do not overlap each other in the vertical direction. Even if it enters through the air holes 27a, it is prevented from falling into contact with the inner gas-liquid separation plate 26 and entering the housing portion of the battery 23 in the case 21 through the intake / exhaust holes 26a.

  In this embodiment, as shown in FIG. 3, a circuit board 30 constituting cooling fan drive control means for drivingly controlling the cooling fan 13 of the cooling unit 12 on the upper surface of the partition plate 22 in the case 21 of the power supply unit 20. Is installed. Although details of the circuit board 30 will be described later, devices such as a DC / DC converter 31 for generating a circuit driving voltage from the battery voltage are also provided. Since the DC / DC converter 31 and the like are disposed in a space serving as an air flow path in the case 21, the cooling air is forcibly cooled by passing through the heat sink of each element, thereby improving the efficiency of the heat sink. The power supply device 11 is downsized.

  As shown in FIG. 5, a pair of mounting brackets 28 projecting in a substantially horizontal direction are fixed to both side surfaces of the case 21 of the power supply unit 20. A positioning projection 28a is provided on the lower surface of each mounting bracket 28. When the power supply unit 20 is mounted on an electric motorcycle, as shown in FIG. 4, the pair of mounting brackets 28 are attached to an aluminum die casting of the electric motorcycle. Is placed on the U-shaped bifurcated portion 3a of the main frame 3 and is positioned by fitting a projection 28a into a recess (not shown) provided in the bifurcated portion 3a. Fix by etc.

As shown in FIG. 3, the case 21 of the power supply unit 20 is also formed with a vent 21 a at the center upper portion of the rear end surface in the traveling direction of the electric motorcycle, and there is an air duct 14 extending from the cooling unit 12. The tip is connected, and the space above the partition plate 22 is communicated with the cooling unit 12 via the air duct 14. In the middle of the air duct 14, a bellows portion 14 a for absorbing an error in the mounting position and a relative position change between the power supply unit 20 and the cooling unit 12 is provided.
In the cooling unit 12, a cooling fan 13 capable of performing a first air blowing operation for sending air to the case 21 of the power supply unit 20 and a second air blowing operation for sucking air out of the case 21 is incorporated. In this embodiment, the cooling unit 12 is housed in a gasoline engine vehicle using an air cleaner cover.

In this embodiment, as shown in FIGS. 7 and 8, the cooling fan 13 is screwed to the support member 40 with a sending fan 13A that performs a first blowing operation and a suction fan 13B that performs a second blowing operation. It is fixed and configured.
The sending fan 13A and the suction fan 13B are the same fan having the appearance as shown in FIG. 9, and a fan motor and a cylindrical rotating blade (sirocco fan) rotated by the fan motor are provided therein. The airflow port 13a is provided in the tangential direction of the rotor blade, and the circular or ring-shaped air intake port 13b (shown by a broken line in FIG. 8) is provided along the base of the rotary blade on the circular surface that cannot be seen in FIG. Yes.

When the fan motor is energized and driven, the rotor motor rotates the fan motor, sucks outside air in the axial direction from the air inlet 13b, and sends the air in the radial direction from the air outlet 13a.
The sending fan 13A and the suction fan 13B face the surfaces having the air inlets 13b facing each other, and the sending fan 13A has the air blowing port 13a in the direction of the connecting portion of the air duct 14 (left side in FIG. 7). The suction fan 13B is fixed to the support member 40 with the air blowing port 13a facing downward. The support member 40 is formed with an opening 40a (indicated by a broken line in FIGS. 7 and 8) for communicating each intake port 13b of the delivery fan 13A and the suction fan 13B.

Further, a partition wall 41 is provided between the periphery of the support member 40 and the inner surface of the cover 12a of the cooling unit 12, and a sub chamber 42B that is hermetically isolated from the main chamber 42A in the cooling unit 12 is provided. A suction fan 13B is arranged. The sub chamber 42B communicates with the outside through an air port 12b formed in the lower part of the cover 12a of the cooling unit 12.
The wiring 45 of the sending fan 13A and the wiring 46 of the suction fan 13B are gathered together via a connector on the cooling unit 12 side, an external cord and a connector on the power supply unit 20 side (not shown), and the circuit board shown in FIG. 30. The wirings 45 and 46 are both two-wire power supply wiring cords.

In the cooling unit 12 configured in this manner, the air flow during the first blowing operation by the sending fan 13A of the cooling fan 13 is indicated by a white arrow, and the air flow during the second blowing operation by the suction fan 13B. Are indicated by hatched arrows in FIGS. 7 and 8, and each operation will be described.
When the delivery fan 13A of the cooling fan 13 is driven, air is sucked from the intake port 13b, so that the outside air from the air port 12b shown in FIG. Through the air inlet 13b and the opening 40a of the support member 40, the air is sucked into the sending fan 13A, and is sent from the air blowing port 13a into the main chamber 42A. The sent air is sent into the upper space of the case 21 of the power supply unit 20 through the air duct 14 shown in FIGS.
The cooling air flows into the battery accommodating portion through the vent hole 22a of the partition plate 22, spreads through the gaps between the batteries 23 shown in FIG. 5 and flows downward while cooling the batteries 23, thereby separating the gas and liquid. The air is exhausted from the intake and exhaust holes 26a and 27a of the plates 26 and 27 to the outside.

On the other hand, when the suction fan 13B is driven, the air in the main chamber 42A shown in FIG. 7 is sucked from the air inlet 13b, so that the air in the main fan 42A shown in FIG. The air is then sucked into the suction fan 13B from the air inlet 13b through the inside through the air inlet 13b and the opening 40a of the support member 40, and sent out from the air outlet 13a to the sub chamber 42B. Released.
When the air in the main chamber 42A in the cooling unit 12 is sucked in by the suction fan 13B, the air in the case 21 of the power supply unit 20 is sucked out through the air duct 14 shown in FIGS. Thus, since the outside air flows into the case 21 from the intake / exhaust holes 26a, 27a of the gas-liquid separation plates 26, 27 and flows through the gaps between the batteries 23 as cooling air, each battery 23 is cooled.

  A fan that sends or sucks air generally has a fixed pitch of rotating blades, and the air volume varies depending on conditions such as applied voltage to the fan motor and static pressure. Such a fan normally rotates in one direction, and does not have a function of sending and sucking air with a single fan. In this embodiment, the two cooling fans 13 are used as described above, and one of them is combined as a sending fan 13A and the other as a suction fan 13B. Therefore, since a commercially available inexpensive fan can be used, the manufacturing cost can be suppressed.

  The vent hole 21a for communicating the case 21 of the power supply unit 20 with the air duct 14 and the intake / exhaust holes 26a and 27a for communicating with the outside air may be provided on different surfaces of the case 21, but preferably on the opposite surface or It is good to provide it as far away as possible. However, the position is not limited to the illustrated position, and the air hole 21 a may be provided on the upper surface of the case 21, the air hole 21 a is provided at the lower center of the rear end surface of the case 21, and the intake and exhaust holes are provided on the upper surface of the case 21. Also good. Alternatively, a vent hole communicating with the air duct 14 is provided in the upper part or lower part of the front end face or rear end face of the case 21, and the intake / exhaust hole is provided in the lower part or upper part (opposite of the vent hole) of the opposite end face of the case 21. Also good.

  In the illustrated embodiment, the power supply unit 20 and the cooling unit 12 are connected via the air duct 14. However, the power unit 20 and the cooling unit 12 are not necessarily required to be connected via the air duct 14, and may be directly connected to each other depending on the space on the layout of the electric vehicle. You may connect. Further, the cooling unit 12 is not limited to the rear of the power supply unit 20 but may be disposed on the side or front. In short, the power supply unit 20 and the cooling unit 12 may be appropriately arranged and connected based on a layout suitable for the electric vehicle to be mounted.

Here, a configuration example of a portion functioning as a cooling fan drive control unit in the circuit board 30 provided in the power supply unit 20 will be described with reference to FIG.
In FIG. 10, the external cord is not shown, and the connector on the cooling unit 12 side and the connector on the power supply unit 20 side are collectively shown as a connector 37.
In the circuit board 30, a control circuit 32 mainly composed of a microcomputer (hereinafter abbreviated as “CPU”), a timer 33, a switching transistor 34, a relay coil Ly controlled by the transistor 34 and a switching circuit A relay 35 comprising a contact Sy and a diode 36 connected between the emitter and collector of the transistor 34 and absorbing a reverse voltage generated when the relay coil Ly is turned off are provided.

  The temperature detection signals from the five temperature sensors 25a to 25e shown in FIG. 5 are input to the control circuit 32, converted into digital signals by internal A / D converters, and input to the CPU. A signal generated every time a predetermined time elapses by the timer 33 is also input. The timer 33 is provided separately for easy understanding, but may be provided in the control circuit 32. Normally, the CPU can also function as a timer by counting the driving clock pulses.

DC 12V obtained by converting the voltage of the battery 23 by the DC / DC converter 31 shown in FIG. 3 is applied to the movable contact c of the switching contact Sy of the relay 35 and one end of the relay coil Ly, and the relay coil Ly The other end of the transistor is grounded through the collector and emitter of the transistor. The base of the transistor 34 is connected to the output terminal Os of the control circuit 32. When the output signal is at low level “L”, the transistor 34 is off, the relay 35 is not excited, and the switching contact Sy is shown in FIG. It is switched to the fixed contact a side.
Therefore, at this time, the sending fan 13A is energized through the wiring 45 and the fan motor is driven, so that the cooling fan 13 of the cooling unit 12 performs the first blowing operation of sending cooling air into the case 21 of the power supply unit 20. Do.

  When the output signal of the control circuit 32 becomes high level “H”, the transistor 34 is turned on to excite the relay 35, so that the switching contact Sy is switched to the fixed contact b side, and the suction fan 13 B is energized through the wiring 46. Since the fan motor is driven, the cooling fan 13 of the cooling unit 12 performs a second air blowing operation for sucking the air in the case 21 of the power supply unit 20.

  In this embodiment, the circuit board 30 constituting the cooling fan drive control means for controlling the driving of the cooling fan 13 and its operating state at a difference in temperature detected by the temperature sensors 25a to 25e or at a predetermined time interval by the timer 33. Is provided in the case 21 of the power supply unit 20, but the function of the cooling fan drive control means may also be provided in the control device 10 shown in FIG.

Next, a cooling method when the battery 23 accommodated in the power supply unit 20 is discharged (during use) by the battery cooling system according to the present invention described above will be described.
In general, when a battery is discharged, it is ideal that the temperature is in the range of 20 ° C to 30 ° C and that there is no temperature difference between the batteries of the power supply unit consisting of a plurality of batteries, so that the output capacity can be maximized. It is said that. However, the outside air temperature is significantly different between spring, summer, autumn and winter, and even when there is almost no temperature difference between the batteries at the start of discharge (starting), the upper or A thing in a center part tends to have heat, and its output capability tends to vary.

The battery cooling system according to the present invention can minimize the temperature difference between a large number of such stacked batteries, make the output capacity of each battery uniform, and achieve the maximum output of the power supply unit of the power supply unit as a whole. To do.
Hereinafter, specific battery cooling methods will be described as Embodiments 1 to 3.

[Example 1]
First, a first embodiment of the cooling method will be described. FIG. 11 is a flowchart of processing by the control circuit 32 when the first embodiment of the battery cooling method is performed . In FIG. 11 and FIG. 12, which is a flowchart of the second embodiment, each step is abbreviated as “S”.

When the main switch 15 shown in FIG. 2 provided in the vehicle body 2 of the electric motorcycle 1 is turned on, the DC of the circuit board 30 in the power supply unit 20 that houses the battery 23 made of a nickel-hydrogen battery constituting the power supply device 11. The / DC converter 31 is activated and applies a predetermined DC voltage to the control circuit 32 and the relay 35 shown in FIG.
Thereby, the control circuit 32 starts the processing of FIG. Immediately after the power is turned on in step 1, the cooling fan 13 is caused to perform a “suction” operation in step 2.
That is, the control circuit 32 sets the output terminal Os to the high level “H”. Therefore, the transistor 34 is turned on, the relay 35 is excited, and the switching contact Sy is switched to the fixed contact b side, and the suction fan 13B of the cooling fan 13 is energized through the wiring 46 to rotate it.

Thereby, outside air is sucked into the case 21 from the intake / exhaust holes 26a, 27a of the gas-liquid separation plates 26, 27 provided in the lower part of the power supply unit 20 shown in FIGS. It flows into the cooling unit 12 via the space with the circuit board 30 and the air duct 14, and is sucked by the cooling fan 13 (in this case, the second blowing operation is performed by the suction fan 13B) and discharged to the outside. . This operation is called “suction”.
In this manner, high temperature air staying around the plurality of batteries 23 in the power supply unit 20 is discharged, and the outside air that is sucked into the case 21 and sucked into the cooling unit 12 becomes cooling air. When the battery 23 flows through the gaps, the batteries 23 are deprived of heat and cooled.

  As described above, the reason why the cooling fan 13 performs the suction operation at the beginning of the start is that the temperature of the battery 23 generally stacked tends to be higher as it is in the upper part after the discharge starts. Therefore, when the cooling air is sent to the upper part of the power supply unit 20 from the beginning, the cooling air that has flowed in due to the heat of the upper battery 23 that tends to increase in temperature tends to heat up and flow to the lower part, and the temperature of the battery 23 located at the lower part. It is because it is not preferable because it tends to increase the amount.

After starting, in step 3, a temperature difference (battery temperature difference) between the maximum value and the minimum value detected by each of the temperature sensors 25a to 25e shown in FIG. 10 is detected, and this is a predetermined value (3 ° C. in this example). ) Determine whether or not. If the battery temperature difference is not 3 ° C. or more, the process returns to step 2 to continue the “suction” operation.
When the battery temperature difference is 3 ° C. or more, in step 4, the temperature detected by the uppermost temperature sensor and the lowermost temperature sensor, that is, the upper battery temperature and the lower battery temperature are compared. As a result, when the upper battery temperature is higher than the lower battery temperature, the process proceeds to step S5, and the cooling fan 13 is switched to the “delivery” operation. That is, the control circuit 32 sets the output terminal Os to the low level “L”. As a result, the transistor 34 is turned off, the relay 35 is de-energized, and the switching contact Sy is switched to the fixed contact a side. The power supply fan 13A of the cooling fan 13 is energized through the wiring 45 to rotate it. .

Then, the cooling unit 12 shown in FIG. 3 sucks outside air by the cooling fan 13 (in this case, the first blowing operation is performed by the sending fan 13A), and the upper part of the case 21 of the power supply unit 20 through the air duct 14. Cooling air is fed into The cooling air is taken from the upper part to the lower part in the case 21 and cools by taking the heat of each battery while flowing through the gaps between the batteries 23, and the gas-liquid separation plates 26 and 27 provided at the lower part of the case 21 are cooled. It is discharged outside through the intake / exhaust holes 26a, 27a. This operation is called “sending”.
If it is determined in step 4 that the upper battery temperature is not higher (equal or lower) than the lower battery temperature, the process proceeds to step 6 to continue the “suction” operation.

Thereafter, it is checked in step 7 whether or not the power is turned off. If the power is turned off, the process is terminated, and the operation of the cooling unit 12 is also stopped. Is determined to be 3 ° C. or higher, and the above-described operation is repeated.
That is, in the first embodiment, if the battery temperature difference is not 3 ° C. or higher, the suction operation is continued. If the battery temperature difference is 3 ° C. or higher, the “sending” operation is performed depending on whether the upper battery temperature or the lower battery temperature is higher. Select "suction" operation.

The predetermined value of the temperature difference is the case of the power supply unit 20 made of a nickel-hydrogen battery used in this embodiment and is about 3 ° C., but is not limited thereto. Ideally, there should be no temperature difference between the batteries as much as possible, but even if a temperature difference occurs, in order to hold it down to about 5 ° C with the internal temperature difference, considering the battery surface temperature and the internal temperature transmission time, What is necessary is just to make it about 3 degreeC.

  In the first embodiment, the control circuit 32 detects a temperature difference not less than a predetermined value in the power supply unit 20 by the operation of the portion functioning as the cooling fan drive control means shown in FIG. 10 in the circuit board 30 shown in FIG. Then, the direction of the cooling air is switched according to the level relationship between the upper battery temperature and the lower battery temperature, and the battery using the nickel-hydrogen battery is as described above. However, the predetermined value of the temperature difference varies depending on the type and capacity of the battery used, the capacity of the power supply device, the passage of the cooling air, the air volume, and the like, and cannot be defined unconditionally. However, even in the case of nickel cadmium batteries, lithium ion batteries, and lead batteries, the predetermined value is set to about 3 ° C, and the direction of the cooling air is detected when it is detected that the temperature difference is 3 ° C or more. Good results are obtained by switching.

As shown in FIG. 5, the plurality of batteries 23 in the power supply unit 20 are arranged in a staggered manner over a plurality of stages via the elastic ring 24, and the cooling air sent from the air duct 14 passes through the gaps. The battery 23 is cooled by passing, but the control circuit 32 and the DC / DC converter 31 provided on the circuit board 30 are also cooled and forced to the outside through the intake / exhaust holes 26a, 27a of the gas-liquid separation plates 26, 27. Are exhausted.
Meanwhile, the cooling air passing between the plurality of batteries 23 absorbs heat from each battery 23 and transmits a part of the heat to the peripheral wall of the case 21 made of a light alloy having good thermal conductivity such as aluminum. The heat transferred to the peripheral wall of the case 21 is further transferred through a fixed portion with the main frame 3 manufactured by aluminum die casting, and radiated to the outside.

  That is, the case 21 and the main frame 3 of the power supply unit 20 also have a function as a heat dissipation medium for the battery 23. Further, the insulating plates 38 provided at both ends of the battery 23 accommodated in the power supply unit 20 are formed of a resin having good electrical insulation and good thermal conductivity (for example, a silicon resin or a polyurethane resin). Therefore, heat can be transferred from both ends of each battery 23 to the peripheral wall of the case 21 of the power supply unit 20, and heat of a portion that is difficult to be cooled by the cooling air can be radiated.

[Example 2]
Next, Embodiment 2 of the battery cooling method according to the present invention will be described with reference to the flowchart shown in FIG. In the second embodiment, in the power supply device using the battery described in the first embodiment, the timer 33 provided in the portion functioning as the cooling fan drive control means of the circuit board 30 is used, and the cooling fan 13 is installed at predetermined time intervals. A switching operation is automatically performed from one of the first blowing operation and the second blowing operation to the other, and the flow direction of the cooling air in the power supply unit 20 is switched.

When the processing shown in FIG. 12 is started, immediately after the power is turned on in step 11, the cooling fan 13 is caused to perform a “suction” operation in step 12 as in the case of the first embodiment. Thereby, high temperature air staying around the plurality of batteries 23 in the power supply unit 20 is discharged, and the outside air that is sucked into the case 21 and sucked into the cooling unit 12 becomes cooling air, When the battery 23 flows through the gaps, the heat of each battery 23 is taken and cooled.
Thereafter, in step 13, when a predetermined time by the timer 33, for example, 5 minutes elapses, the air flow direction by the cooling fan 13 is switched (initially switched from “suction” operation to “sending” operation), and the process proceeds to step 14.

In step 14, as in the case of the first embodiment, a temperature difference (battery temperature difference) between the maximum value and the minimum value detected by the temperature sensors 25a to 25e shown in FIG. In this example, it is determined whether the temperature is 3 ° C. or higher. If the battery temperature difference is not 3 ° C. or more, the process returns to step 13, and when a predetermined time has elapsed, the air circulation direction by the cooling fan 13 is switched and the determination of step 14 is performed again.
When the battery temperature difference is 3 ° C. or more in step 14, the process proceeds to step 15 where the upper battery temperature and the lower battery temperature are compared as in step 4 of Example 1, and the upper battery temperature is higher than the lower battery temperature. For example, the cooling fan 13 is caused to perform “sending” operation in step 16, and if the upper battery temperature is not higher than the lower battery temperature, the cooling fan 13 is caused to perform “suction” operation in step 17.

  Thereafter, in step 18, it is determined whether or not the difference between the upper battery temperature and the lower battery temperature is within 1 ° C. As a result, if it is not within 1 ° C., the process returns to step 15, and “delivery” and “suction” are selected and the cooling fan 13 is operated depending on the upper and lower battery temperatures. As a result, if the difference between the upper battery temperature and the lower battery temperature is within 1 ° C., the process is terminated if the power is turned off in step 19, but if not, whether or not the “suction” operation is currently being performed in step 20. Judging.

Then, if the “suction” operation is being performed, the operation is switched to the “sending” operation in step 21, and if the “suction” operation is not being performed, the operation is switched to the “suction” operation in step 22. The operation is switched every 5 minutes in the example.
As described above, in this embodiment, not only the temperature difference but also the upper and lower temperature differences are detected, and when they become substantially equal, the air flow direction is switched at predetermined time intervals.
The reason is that if only one of the “suction” or “sending” operation is continued for a long time or only the operation switching due to the temperature difference is performed, the temperature difference between the upper battery and the lower battery eventually increases. This is because the air in the vicinity of the center in the case 21 is difficult to be replaced.

Example 3
This is a modification of the above-described second embodiment, but when the capacity of the battery to be used is relatively small, the power supply unit 20 and the cooling unit 12 are connected without providing a temperature sensor in the power supply unit 20. Based on the instruction of the timer 33 provided in the circuit board 30, the cooling fan 13 is alternately switched between the sending fan 13 </ b> A and the suction fan 13 </ b> B at predetermined time intervals under the control of the control circuit 32. By reversing the direction of the cooling air and alternately performing the “suction” operation and the “delivery” operation, each battery can be cooled substantially uniformly.

In this embodiment, when the number of battery modules of the battery 23 constituting the power supply unit 20 described in the first embodiment is ½, the predetermined time is set to 5 minutes, and the cooling fan 13 is set based on the instruction of the timer 33. By switching and operating every 5 minutes, the temperature difference of the battery 23 in the power supply unit 20 could be adjusted within 3 ° C.

  In the first to third embodiments, the battery cooling method in the case where the vehicle travels by discharging the battery 23 of the power supply unit 20 and driving the traveling electric motor 8 of the electric motorcycle 1 shown in FIGS. 1 and 2 will be described. did. However, when the electric motorcycle 1 is not used, when the charger 17 shown in FIG. 2 is connected to a commercial power source and the battery 23 of the power supply unit 20 is charged by the charger 17, the cooling unit 12 is similarly used. The cooling fan 13 is driven, and the first air blowing operation and the second air blowing operation are automatically switched when the detected temperature difference exceeds a predetermined value or at a predetermined time interval or both, and the power supply unit It is desirable to cool each battery 23 uniformly by reversing the flow direction of the cooling air at 20.

  The embodiment of the present invention described above is a battery cooling system of a power supply device mounted on an electric motorcycle, but the battery cooling system according to the present invention is not limited to an electric motorcycle, but an electric scooter, a four-wheel electric vehicle, an electric tricycle, The present invention can be similarly applied to power supplies for electric carts, electric buses, electric trucks, battery-powered trains, electric wheelchairs, and other various electric vehicles. The present invention can also be applied to other stationary battery power supply devices such as various auxiliary power supply devices, illumination power supply devices, and industrial power supply devices.

Features of the battery cooling system according to the present invention applied to a power supply device for an electric vehicle include the following.
(1) A cooling unit that contains a cooling fan is connected to a power supply device that is mounted on an electric vehicle and contains a plurality of batteries and a plurality of temperature sensors, and the cooling fan is driven when the battery is charged and discharged. Cooling air is circulated in the power supply unit to cool each battery. Then, when the cooling fan drive control means detects that the temperature difference between the batteries is equal to or greater than a predetermined temperature difference based on the detection signals of the plurality of temperature sensors, the cooling fan air delivery operation (first air flow) Operation) and air suction operation (second air blowing operation) are automatically switched to reverse the direction of the cooling air flowing through the power supply unit. Thereby, each battery in the power supply unit can be cooled uniformly and efficiently.

(2) The connection between the power supply device and the cooling unit may be performed depending on the type of the electric vehicle, using an air duct as necessary, so that the cooling unit can be placed in the longitudinal direction of the power supply device depending on the space of the mounted vehicle. It can be arranged at any position such as in the lateral direction of the power supply device.
(3) In the above configuration, when a cylindrical battery module is used as the battery of the power supply device, the longitudinal direction of each battery module is arranged in parallel with the traveling direction of the vehicle, and each battery module is viewed from the axial direction. When the battery is mounted in a staggered manner, the battery mounting volume is minimized, and a gap is formed between the battery modules by an elastic ring or the like, and cooling air is circulated through the gap.

(4) The cooling fan drive control means has a timer function, and automatically switches between the air sending operation (first blowing operation) and the air suction operation (second blowing operation) of the cooling fan at predetermined time intervals. Even if it controls, it is possible to cool each battery in a power supply unit substantially uniformly.
In addition, when it is detected that the difference in temperature detected by each temperature sensor has become equal to or smaller than a second predetermined value which is smaller than the predetermined value, the operation of the cooling fan is switched and the direction of the cooling air is reversed. You may let them.

(6) The cooling fan of the cooling unit can be mounted using an air cleaner case of a gasoline engine vehicle in a small in-vehicle space, thereby increasing the mounting space of the power supply device.
Even when the battery cooling system according to the present invention is applied to a power supply device other than an electric vehicle, most of these features are utilized.

The battery cooling system according to the present invention can be applied to power supply devices for electric motorcycles including electric scooters, electric vehicles, electric carts, electric wheelchairs, and other various electric vehicles. Further, it can be applied to other stationary battery power supply devices such as various auxiliary power supply devices, illumination power supply devices, and industrial power supply devices.
And the direction of the cooling air for cooling the battery which comprises a power supply device at the time of charge or discharge of those power supply devices is automatically reversed, each battery is cooled efficiently and uniformly, and the temperature between batteries The difference can be almost eliminated and the output capability of the battery can be maximized. Moreover, the structure is simple and can be implemented at low cost.
In addition, it is possible to realize a power supply device with good charge / discharge efficiency and an electric vehicle with good power supply utilization efficiency.

1 is a side view of an electric motorcycle equipped with a power supply device including a battery cooling system according to an embodiment of the present invention. It is the schematic which looked at the electric motorcycle from the rear side except for the rear wheel. It is a side view which shows only the power supply device provided with the battery cooling system. It is the same top view. It is a cross-sectional view showing an arrangement example of a large number of batteries in the power supply unit. It is explanatory drawing which shows the structural example of a battery. FIG. 5 is a cross-sectional plan view of a cooling fan housing portion of the cooling unit shown in FIGS. 3 and 4. It is a sectional side view of the cooling fan accommodating part similarly. It is a perspective view of one fan which constitutes the cooling fan similarly.

It is a circuit diagram which shows the structural example of a cooling fan drive control means. It is a flowchart of the process by the control circuit shown in FIG. 10 at the time of implementing Example 1 of a battery cooling method. It is a flowchart of the process by the control circuit shown in FIG. 10 at the time of implementing Example 2 of a battery cooling method.

Explanation of symbols

1: Electric motorcycle 2: Vehicle body 3: Main frame 3a: Bifurcated portion 4: Front wheel 5: Rear wheel 6: Handle 7: Seat seat 8: Electric motor for travel 9: Power transmission device 10: Control device 11: Power supply device 12: Cooling unit 12a: Cover 12b: Air port 13: Cooling fan 13A: Sending fan 13B: Suction fan 14: Air duct 15: Main switch (key switch) 16: Display panel 17: Charger 18: Motor drive circuit 19: Heat sink 20: Power supply unit 21: Case 21a: Vent hole 22: Partition plate 22a: Vent hole 23: Battery 24: Elastic ring 25a to 25e: Temperature sensor 26, 27: Gas-liquid separation plate 26a, 27a: Intake / exhaust hole 28: Mounting bracket 29: Under cover 30: Circuit board 31: DC / DC converter 32: Control Circuit 33: timer 34: transistor 35: Relay 36: Diode 37: Connector 38: insulating plate 40: support member 40a: opening 41: partition wall 42A: main chamber 42B: auxiliary chamber 45, 46: wiring

Claims (5)

A first power supply unit that is connected to a power supply unit that accommodates a plurality of batteries in a case with a space around each adjacent battery, and a ventilation hole provided in the case of the power supply unit, and sends air into the case A cooling fan composed of a cooling fan for operation and a cooling fan for second air blowing operation for sucking air out of the case;
Based on the information on the temperature detected by the plurality of temperature sensors, the intake and exhaust holes are provided on a surface different from the surface provided with the vent hole of the case, and a plurality of temperature sensors are disposed at different positions in the case. the blowing operation of the cooling fan, the the blowing operation by the first cooling fan for the second blowing operation from the air operation by the cooling fan for blowing operation, or by the second cooling fan for blowing operation battery cooling system, characterized in that a cooling fan drive control means from the blowing operation automatically switches to the blowing operation by the cooling fan for the first blowing operation. In the battery cooling system of claim 1, wherein the cooling fan drive control means, wherein the blowing operation of the cooling fan at a predetermined time interval, the second blowing operation from the air operation by the first cooling fan for blowing operation And a function of automatically switching from a blowing operation by the cooling fan for the second blowing operation to a blowing operation by the cooling fan for the first blowing operation . Battery cooling system. 3. The battery cooling system according to claim 1, wherein the ventilation hole is provided in an upper portion of one end surface of the case, and a plurality of the intake and exhaust holes are provided in a lower surface of the case. The power supply device provided with the battery cooling system as described in any one of Claims 1 thru | or 3 . An electric vehicle equipped with the power supply device according to claim 4 .

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