JP2009261246A - Battery system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a battery system which prevents life reduction due to secondary battery deterioration, firing, and leakage of liquid by stopping charge without fail at overheat, in a battery system which charges a secondary battery. <P>SOLUTION: The battery system has multiple sets of battery packs 4; a charger 1 which charges the battery packs 4; and a control unit 2 which controls the operation of the charger 1. The battery pack 4 has a temperature sensor 6 and a temperature switch 5. The output of the temperature sensor 6 is input into the control unit 2 and the temperature switch 5 is connected to the charger 1. The control unit 2 stops the operation of the charger 1 when the temperature input from the temperature sensor 6 is at or over a first temperature. When the temperature of some battery pack 4 is at or over the second temperature, the temperature switch 5 corresponding to the battery pack 4 is opened, and operation of the charger 1 stops. A mounting detecting switch 12, which detects the mounting of the battery pack 4, is connected in parallel with the temperature switch 5, and it is closed when the battery pack 4 is not mounted. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a battery system, and more particularly to a battery system for charging a storage battery.

  In the storage battery charging control technology, proposals shown in the following Patent Documents 1 and 2 have been made for the purpose of safely stopping charging and fully exhibiting the storage capacity.

  In Patent Document 1, the charging voltage of a nickel metal hydride storage battery is measured by a voltage measuring means, and the voltage measured 1 minute after the start of charging is compared with a preset voltage. When the measured voltage is higher than the preset voltage, It is described that charging is determined and charging is stopped, and Patent Document 2 describes that a secondary battery is charged with a constant current and then charged with a constant voltage or a pulsed current. Alternatively, when the average charging current per pulse is below a predetermined value, full charge is detected, the temperature of the secondary battery is measured, and the full charge detection current value, which is the current value for stopping charging, is calculated based on the temperature. It is described to change.

JP-A-8-140280 JP 2002-58171 A

  When charging a secondary battery with a charger, the monitoring and control unit monitors the temperature and voltage, and controls to stop charging by detecting full charge due to the change. It is also assumed that this will continue. In preparation for such a case, the monitoring control unit regards the secondary battery as an abnormal temperature when the temperature exceeds a certain value, and performs control to forcibly stop the charger.

  However, due to the failure of the monitoring control unit itself, charging control may become impossible and charging may continue.In this case, the secondary battery overheats and deteriorates, leading to a reduction in life, and further, ignition and leakage The problem of reaching.

  Said problem is a common problem which arises in secondary batteries, such as a lead acid battery, a nickel metal hydride storage battery, and a lithium ion storage battery.

  The present invention has been made in view of the above problems, and a problem to be solved by the present invention is that, in a battery system for charging a secondary battery, charging is reliably stopped during overheating, and the secondary battery is deteriorated. It is an object of the present invention to provide a battery system that prevents lifetime reduction, ignition, and liquid leakage.

In the present invention, in order to solve the above problem, as described in claim 1,
A battery system comprising: a plurality of assembled batteries formed by connecting one or more secondary batteries; a charger that charges the plurality of assembled batteries; and a control unit that controls the operation of the charger. Each of the batteries includes a temperature sensor that detects the temperature of the assembled battery and a temperature switch that opens and closes according to the temperature of the assembled battery, and the temperature of the assembled battery detected by the temperature sensor is input to the control unit. The control unit issues a control signal for stopping the operation of the charger to the charger when the temperature of the assembled battery input from any of the temperature sensors is equal to or higher than a first temperature, The temperature switch is connected to the charger by an individual temperature switch circuit. In the first case, the temperature switch has a temperature of the assembled battery including the temperature switch higher than the first temperature. When the temperature is lower than the second temperature, the open state is established, and when the temperature is lower than the second temperature, the closed state is established. When the circuit is open, the operation is stopped, or as a second case, the temperature switch is closed when the temperature of the assembled battery including the temperature switch is equal to or higher than the second temperature. And when the temperature is lower than the second temperature, the charger is in an open state, and when the control signal is not transmitted, the charger is stopped when any of the temperature switch circuits is closed. The battery system characterized by comprising.

In the present invention, as described in claim 2,
The battery system according to claim 1, wherein the temperature switch and the charger perform the operation in the first case, and a temperature switch circuit formed by connecting the temperature switches in series is connected to the charger. Configure.

In the present invention, as described in claim 3,
3. The battery system according to claim 1, wherein a charge switch is inserted into a power supply line from the charger for each of the assembled batteries, and the controller does not stop the operation of the charger, and the temperature is When the temperature of the assembled battery input from a sensor is equal to or higher than the first temperature, a control signal for opening at least the charging switch inserted in the power supply line of the assembled battery at the temperature is generated. To constitute a battery system.

In the present invention, as described in claim 4,
The battery system according to claim 1, further comprising a mounting frame for mounting the assembled battery, the mounting frame including a mounting presence / absence detection switch that opens and closes by detecting whether the assembled battery is mounted, The mounting presence / absence detection switch is open when the assembled battery is mounted, and is closed when the assembled battery is not mounted. The mounting presence / absence detection switch is installed when the assembled battery is mounted. The battery system is connected in parallel to the temperature switch that opens and closes according to the temperature of the battery.

In the present invention, as described in claim 5,
4. The battery system according to claim 1, further comprising: a mounting frame for mounting the assembled battery, wherein the mounting frame detects whether the assembled battery is mounted or not to open / close the mounting system. And the mounting presence / absence detection switch is not connected to the temperature switch but is individually connected to the control unit.

  By carrying out the present invention, by providing double charging stop mechanisms based on the temperature of the secondary battery, in the battery system for charging the secondary battery, the charging is reliably stopped at the time of overheating, and the lifetime due to deterioration of the secondary battery It is possible to provide a battery system that prevents reduction, ignition, and leakage of liquid.

It is a figure explaining the 1st example of an embodiment of the present invention. It is a figure explaining the 2nd Example of this invention. It is a figure explaining the example of a 3rd embodiment of the present invention. It is a figure explaining the 4th Embodiment of this invention. It is a figure explaining the case where a mounting presence detection switch is added to the 1st example of an embodiment of the present invention. It is a figure explaining the example of 5th Embodiment of this invention.

In the power supply system according to the present invention, for example, a plurality of sets of assembled batteries formed by connecting one or more secondary batteries, a charger that charges the plurality of assembled batteries, and a control unit that controls the operation of the charger In a battery system comprising:
Each of the battery packs includes a temperature sensor that detects the temperature of the battery pack and a temperature switch that opens and closes according to the temperature of the battery pack, and the temperature of the battery pack detected by each temperature sensor is sent to the control unit. Each of the temperature switches is connected to the charger, and the control unit stops the charger when the temperature of the assembled battery input from the temperature sensor is equal to or higher than a first temperature, and the temperature switch The charger shall stop when it is open.

  Further, for example, a mounting presence / absence detection switch connected in parallel to the temperature switch for detecting the mounting of the assembled battery is provided, and when the assembled battery is not mounted, the mounting presence / absence detection switch is closed.

  Hereinafter, embodiments of the present invention will be described by way of example in which the secondary battery is a lead storage battery or a nickel hydride storage battery, but the present invention is not limited to this.

<Embodiment 1>
FIG. 1 is a diagram for explaining a first embodiment of the present invention. In the figure, a lead-acid battery (single cell rating 2V, 200Ah) is connected in series with 6 cells to form a battery pack 4 (12V, 200Ah). The charger 1 outputs DC 12V and charges the assembled battery 4. The battery pack 3 includes an assembled battery 4, a temperature sensor 6 (thermistor) that detects the temperature of the assembled battery 4, and a temperature switch 5 (thermostat) that opens and closes according to the temperature of the assembled battery 4. The temperature sensor 6 and the temperature switch 5 are provided in the assembled battery 4.

  The control unit 2 measures the temperature of the assembled battery 4 from the temperature sensor 6 via the temperature detection line 8, and charges via the charge control line 7 when the measured temperature is 60 ° C. or more which is the first temperature. A signal for stopping charging of the charger 1 is transmitted to the charger 1. In response to this, the charger 1 enters an operation stop state.

  The temperature switch 5 is connected to the charger 1 via the temperature switch circuit 9. The temperature switch 5 (thermostat) is opened when the temperature of the assembled battery 4 including the temperature switch 5 is equal to or higher than 80 ° C., which is the second temperature, and is closed when the temperature is lower than that.

  When the temperature switch 5 is closed and the temperature switch circuit 9 is closed, the charger 1 outputs DC power to the assembled battery 4 during charging, the temperature switch 5 is opened, and the temperature switch circuit 9 is opened. When it is, the operation is stopped.

  When charging continues in an abnormal state of the assembled battery 4 and the control unit 2 fails and the charger 1 cannot be stopped, the temperature switch 5 reaches 80 ° C. (second temperature) or more and becomes open, Since the temperature switch circuit 9 is opened, the charger 1 stops.

  In this way, by providing double charging stop mechanisms, charging during overheating is stopped reliably, reducing the life due to deterioration of the secondary battery, preventing ignition and leakage.

  In the present embodiment, the temperature switch 5 is opened at the second temperature (80 ° C.) or higher and closed at the lower temperature (first case). There is also a method (second case) in which the temperature is closed above (° C.) and opened below. In this method, the charger 1 may be controlled to output DC power to the assembled battery 4 when the temperature switch circuit 9 is open, and to stop when the temperature switch circuit 9 is closed.

  In the present embodiment, the second temperature (80 ° C.) is set higher than the first temperature (60 ° C.). This is because the control unit 2 is normally mounted with functions such as a communication function, and has an advantage that a warning can be issued when the secondary battery is overheated to notify the supervisor. This is because overheating can be detected quickly. As long as charging is reliably stopped at the time of overheating, the first and second temperatures may be the same or higher as long as the temperature does not cause deterioration, ignition, or liquid leakage. Absent.

  Further, in the present embodiment, the charger 1 performs control depending on whether the temperature switch circuit 9 is open or closed, but a reference voltage is applied to one end of the temperature switch circuit 9 and the other end is connected to the charger 1. There is also a method of performing charging control by determining whether or not a reference voltage is transmitted by inputting. In this method, for example, 5 V is applied to one end of the temperature switch circuit 9, and the other end (input to the charger 1) is grounded via a resistor (set to a potential of 0 V). If the temperature switch 5 inserted into the temperature switch circuit 9 is closed, a reference voltage (5 V) is applied to the other end, and at this time, the charger 1 may be controlled so that it can be charged. Conversely, one end of the temperature switch circuit 9 is grounded (with a potential of 0 V), the other end is connected to a reference voltage (5 V) via a resistor, and the charger 1 can be charged when the other end is 0 V. There is also a way to make it. There is also a method of prohibiting charging of the charger 1 when the temperature switch 5 is closed at a threshold value or more and the voltage applied to one end is detected at the other end.

<Embodiment 2>
FIG. 2 is a diagram for explaining a second embodiment of the present invention. In the figure, a lead-acid battery (single cell rating 2V, 200Ah) is connected in series with 6 cells to form a battery pack 4 (12V, 200Ah). The battery pack 3 includes an assembled battery 4, a temperature sensor 6 (thermistor) that detects the temperature of the assembled battery 4, and a temperature switch 5 (thermostat) that opens and closes according to the temperature of the assembled battery 4. The temperature sensor 6 and the temperature switch 5 are provided in the assembled battery 4. Three battery packs 3 are provided, and the charger 1 outputs DC 12V to charge the three assembled batteries 4 connected in parallel.

  The controller 2 measures the temperature of each assembled battery 4 from the temperature sensor 6 via the temperature detection line 8, and when the measured temperature is equal to or higher than 40 ° C., which is the first temperature, via the charge control line 7. A signal for stopping charging of the charger 1 is transmitted.

  The temperature switch 5 is connected to the charger 1 via the temperature switch circuit 9. The temperature switch 5 (thermostat) is opened when the temperature of the assembled battery 4 including the temperature switch 5 is equal to or higher than 50 ° C., which is the second temperature, and is closed when the temperature is lower than that. When all three temperature switch circuits 9 are closed, the charger 1 outputs DC power to the assembled battery 4 during charging, and operates when any one of the three temperature switch circuits 9 is open. To stop.

  Normally, the assembled battery 4 reaches 12V, which is the output voltage of the charger 1, and stops charging. However, when charging continues due to an abnormality in the assembled battery 4, the measured value of the temperature sensor 6 is 40 ° C. (first When the temperature becomes equal to or higher, the control unit 2 generates a control signal for stopping the charger 1 and transmits the control signal to the charging control line 7, and the charger 1 stops.

  When charging continues in an abnormal state of the assembled battery 4 and the control unit 2 fails and the charger 1 cannot be stopped, the temperature of the assembled battery 4 of the battery pack 3 in the abnormally charged state is 50 ° C. When the temperature reaches (second temperature) or higher, the corresponding temperature switch 5 is opened, and the corresponding temperature switch circuit 9 is opened, so that the charger 1 stops.

  In this way, by providing double charging stop mechanisms, charging during overheating is stopped reliably, reducing the life due to deterioration of the secondary battery, preventing ignition and leakage.

  In the present embodiment, the temperature switch 5 is opened at a temperature equal to or higher than the second temperature (50 ° C.) and closed at a temperature lower than the second temperature (first case). There is also a method (second case) in which the temperature is closed above (° C.) and opened below. In this method, the charger 1 may output DC power to the assembled battery 4 when all the temperature switch circuits 9 are open, and stop operating when any one of them is closed. .

  In the present embodiment, the second temperature (50 ° C.) is set higher than the first temperature (40 ° C.). This is because the control unit 2 is normally mounted with functions such as a communication function, and has an advantage that a warning can be issued when the secondary battery is overheated to notify the supervisor. This is because overheating can be detected quickly. As long as charging is reliably stopped at the time of overheating, the first and second temperatures may be the same or higher as long as the temperature does not cause deterioration, ignition, or liquid leakage. Absent.

  Further, in the present embodiment, the charger 1 performs control depending on whether the temperature switch circuit 9 is open or closed, but a reference voltage is applied to one end of the temperature switch circuit 9 and the other end is connected to the charger 1. There is also a method of performing charging control by determining whether or not a reference voltage is transmitted by inputting. In this method, for example, 5 V is applied to one end of the temperature switch circuit 9, and the other end (input to the charger 1) is grounded via a resistor (set to a potential of 0 V). If the temperature switch 5 inserted into the temperature switch circuit 9 is closed, a reference voltage (5 V) is applied to the other end, and at this time, the charger 1 may be controlled so that it can be charged. Conversely, one end of the temperature switch circuit 9 is grounded (with a potential of 0 V), the other end is connected to a reference voltage (5 V) via a resistor, and the charger 1 can be charged when the other end is 0 V. There is also a way to make it. There is also a method of prohibiting charging of the charger 1 when the temperature switch 5 is closed at a threshold value or more and the voltage applied to one end is detected at the other end.

<Embodiment 3>
FIG. 3 is a diagram for explaining a third embodiment of the present invention. In the figure, a nickel-metal hydride storage battery (single cell rating 1.2 V, 100 Ah) is connected in series with 10 cells to form an assembled battery 4 (12 V, 100 Ah). The battery pack 3 includes an assembled battery 4, a temperature sensor 6 (thermistor) that detects the temperature of the assembled battery 4, and a temperature switch 5 (thermostat) that opens and closes according to the temperature of the assembled battery 4. The temperature sensor 6 and the temperature switch 5 are provided in the assembled battery 4. Three battery packs 3 are provided, and the charger 1 outputs DC 16V to charge three battery packs 4 connected in parallel. Each of the three battery packs 4 has an FET (field effect transistor). The charge switch 10 consisting of is connected.

  The control unit 2 performs control so that only one assembled battery is charged by closing the charge switch 10 corresponding to the assembled battery 4 specified by the external signal via the charging control line 7 and opening the other. The temperature of each assembled battery 4 is measured from the temperature sensor 6 via the temperature detection line 8, and when the measured temperature is 60 ° C. or more which is the first temperature, the charge control line 7 is used. The charging switch 10 to be opened is opened to stop the charging of the assembled battery 4.

  All three temperature switches 5 are connected in series to form a temperature switch circuit 9 and are connected to the charger 1. The temperature switch 5 (thermostat) is opened when the temperature of the assembled battery 4 including the temperature switch 5 is equal to or higher than 80 ° C., which is the second temperature, and is closed when the temperature is lower than that.

  The charger 1 outputs DC power to the assembled battery 4 when the temperature switch circuit 9 is closed, and stops operating when the temperature switch circuit 9 is open.

  Normally, charging is performed for each battery pack 4 by closing only one charge switch 10, and charging is terminated by detecting full charge based on the temperature rising gradient and voltage of the battery pack 4. When charging continues due to an abnormality in the battery 4 or an abnormality in the full charge detection function, control is performed when the measured value of the temperature sensor 6 of the assembled battery 4 in an abnormal charging state becomes 60 ° C. (first temperature) or higher. The unit 2 generates a control signal for opening the corresponding charging switch 10 and transmits it to the charging control line 7, and charging of the assembled battery 4 is stopped.

  When charging continues in an abnormal state of the assembled battery 4 and the control unit 2 fails and charging cannot be stopped, the temperature of the assembled battery 4 of the battery pack 3 in the abnormal charging state is 80 ° C. (second The temperature switch 5 is opened, and all the temperature switches 5 are connected in series. Therefore, when one of the temperature switches 5 is opened, the temperature switch circuit 9 is opened, and the charger 1 stops. .

  In this way, by providing double charging stop mechanisms, charging during overheating is stopped reliably, reducing the life due to deterioration of the secondary battery, preventing ignition and leakage.

  In the present embodiment, the second temperature (80 ° C.) is set higher than the first temperature (60 ° C.). This is because the control unit 2 is normally mounted with functions such as a communication function, and has an advantage that a warning can be issued when the secondary battery is overheated to notify the supervisor. This is because overheating can be detected quickly. As long as charging is reliably stopped at the time of overheating, the first and second temperatures may be the same or higher as long as the temperature does not cause deterioration, ignition, or liquid leakage. Absent.

  Further, in the present embodiment, the charger 1 performs control depending on whether the temperature switch circuit 9 is open or closed, but a reference voltage is applied to one end of the temperature switch circuit 9 and the other end is connected to the charger 1. There is also a method of performing charging control by determining whether or not a reference voltage is transmitted by inputting. In this method, for example, 5 V is applied to one end of the temperature switch circuit 9, and the other end (input to the charger 1) is grounded via a resistor (set to a potential of 0 V). If all the temperature switches 5 inserted in the temperature switch circuit 9 are closed, a reference voltage (5 V) is applied to the other end, and at this time, the charger 1 may be controlled so that it can be charged. Conversely, one end of the temperature switch circuit 9 is grounded (with a potential of 0 V), the other end is connected to a reference voltage (5 V) via a resistor, and the charger 1 can be charged when the other end is 0 V. There is also a way to make it.

<Embodiment 4>
FIG. 4 is a diagram for explaining a fourth embodiment of the present invention. In the figure, a nickel-metal hydride storage battery (single cell rating 1.2 V, 100 Ah) is connected in series with 10 cells to form an assembled battery 4 (12 V, 100 Ah). The battery pack 3 includes the assembled battery 4, a temperature sensor 6 (thermistor) that detects the temperature of the assembled battery 4, and a temperature switch 5 (thermostat) that opens and closes according to the temperature of the assembled battery 4. And a connector for connecting to the battery mounting frame 11 which is a mounting frame for this purpose. The temperature sensor 6 and the temperature switch 5 are provided in the assembled battery 4. In the present embodiment, three battery packs can be mounted. However, the battery system is not necessarily mounted with all three battery packs. The charger 1 outputs DC 16V to charge the three assembled batteries 4 connected in parallel, and the three assembled batteries 4 are connected to a charging switch 10 composed of an FET (field effect transistor). Yes.

  The control unit 2 performs control so that only one assembled battery is charged by closing the charge switch 10 corresponding to the assembled battery 4 specified by the external signal via the charging control line 7 and opening the other. The temperature of each assembled battery 4 is measured from the temperature sensor 6 via the temperature detection line 8, and when the measured temperature is 60 ° C. or more which is the first temperature, the charge control line 7 is used. The charging switch 10 to be opened is opened to stop the charging of the assembled battery 4.

  All three temperature switches 5 are connected in series to form a temperature switch circuit 9 and are connected to the charger 1. Further, a mounting presence / absence detecting switch 12 that detects whether the battery pack 3 is mounted or not is connected in parallel to each temperature switch 5. The mounting presence / absence detection switch 12 is open when the battery pack 3 is mounted on the corresponding battery mounting frame 11, and is closed when the battery pack 3 is not mounted. In order to configure such a switch, a lever that moves when the battery pack 3 is mounted inside the battery mounting frame 11 may be provided, and the switch that opens and closes in conjunction with the movement of the lever.

  When the temperature switch circuit 9 is closed, the charger 1 outputs DC power to the assembled battery 4 during charging, and stops operating when the temperature switch circuit 9 is open.

  The temperature switch 5 (thermostat) is opened when the temperature of the assembled battery 4 including the temperature switch 5 is equal to or higher than 80 ° C., which is the second temperature, and is closed when the temperature is lower than that.

  Normally, charging is performed for each battery pack 4 by closing only one charge switch 10, and charging is terminated by detecting full charge based on the temperature rising gradient and voltage of the battery pack 4. When charging continues due to an abnormality in the battery 4 or an abnormality in the full charge detection function, control is performed when the measured value of the temperature sensor 6 of the assembled battery 4 in an abnormal charging state becomes 60 ° C. (first temperature) or higher. The unit 2 generates a control signal for opening the corresponding charging switch 10 and transmits it to the charging control line 7, and charging of the assembled battery 4 is stopped.

  When charging continues in an abnormal state of the assembled battery 4 and the control unit 2 fails and charging cannot be stopped, the temperature of the assembled battery 4 of the battery pack 3 in the abnormal charging state is 80 ° C. (second The temperature switch 5 is opened, and all the temperature switches 5 are connected in series. Therefore, when one of the temperature switches 5 is opened, the temperature switch circuit 9 is opened, and the charger 1 stops. .

  When the battery pack 3 is mounted only on the two battery mounting frames 11 among the three battery mounting frames 11, the mounting presence / absence detection switch 12 corresponding to the non-mounted battery mounting frame 11 is closed. As long as the temperature switch 5 of the other battery pack 3 is not opened, charging is possible.

  Thus, even in a battery system in which the number of battery packs mounted is variable, it is possible to provide double charging stop mechanisms and avoid overheating erroneous detection due to non-mounting.

  In the present embodiment, the second temperature (80 ° C.) is set higher than the first temperature (60 ° C.). This is because the control unit 2 is normally mounted with functions such as a communication function, and has an advantage that a warning can be issued when the secondary battery is overheated to notify the supervisor. This is because overheating can be detected quickly. As long as charging is reliably stopped at the time of overheating, the first and second temperatures may be the same or higher as long as the temperature does not cause deterioration, ignition, or liquid leakage. Absent.

  Further, in the present embodiment, the charger 1 performs control depending on whether the temperature switch circuit 9 is open or closed, but a reference voltage is applied to one end of the temperature switch circuit 9 and the other end is connected to the charger 1. There is also a method of performing charging control by determining whether or not a reference voltage is transmitted by inputting. In this method, for example, 5 V is applied to one end of the temperature switch circuit 9, and the other end (input to the charger 1) is grounded via a resistor (set to a potential of 0 V). If all the temperature switches 5 inserted in the temperature switch circuit 9 are closed, a reference voltage (5 V) is applied to the other end, and at this time, the charger 1 may be controlled so that it can be charged. Conversely, one end of the temperature switch circuit 9 is grounded (with a potential of 0 V), the other end is connected to a reference voltage (5 V) via a resistor, and the charger 1 can be charged when the other end is 0 V. There is also a way to make it.

  The method of using the battery mounting frame 11 and connecting the mounting presence / absence detection switch 12 and the temperature switch 5 in parallel can also be applied to the first, second, and third embodiments.

  Further, a battery mounting frame 11 and a mounting presence / absence detection switch 12 are added to the first, second, and third embodiments, and the mounting presence / absence detection switch 12 is not connected to the temperature switch 5 but is individually connected to the control unit 2. It may be connected. FIG. 5 shows a configuration in which a battery mounting frame 11 and a mounting presence / absence detection switch 12 are added to the first embodiment. With such a configuration, the control unit 2 can individually detect the presence or absence of the assembled battery 4 by detecting the open / closed state of the individual mounting presence / absence detection switches. In this configuration, even if the temperature switch 5 is closed at the second temperature (80 ° C.) or higher and opened at the lower temperature (second case) corresponding to the first and second embodiments. Good.

<Embodiment 5>
FIG. 6 is a diagram for explaining a fifth embodiment of the present invention. In the figure, a lead-acid battery (single cell rating 2V, 200Ah) is connected in series with 6 cells to form a battery pack 4 (12V, 200Ah). The battery pack 3 includes three sets of assembled batteries 4, a temperature sensor 6 (thermistor) that detects the temperature of the three sets of assembled batteries 4, and a temperature switch 5 (thermostat) that opens and closes according to the temperature of the three sets of assembled batteries 4. Is a component. The charger 1 outputs DC 12V and charges three sets of assembled batteries 4 connected in parallel. In the present embodiment, the number of temperature sensors 6 and the number of temperature switches 5 are smaller than the number of assembled batteries 4.

  The control unit 2 measures the temperature of the assembled battery 4 from the temperature sensor 6 via the temperature detection line 8, and charges via the charge control line 7 when the measured temperature is 60 ° C. or more which is the first temperature. The signal which stops charge of the device 1 is transmitted.

  The temperature switch 5 is connected to the charger 1 via the temperature switch circuit 9. The temperature switch 5 (thermostat) is opened when the temperature (for example, the maximum value) of the three battery packs 4 is equal to or higher than 80 ° C., which is the second temperature, and is closed when the temperature is lower than that. The charger 1 outputs DC power to the assembled battery 4 when the switch circuit 9 is closed, and stops operating when the switch circuit 9 is open.

  Normally, the assembled battery 4 reaches 12V, which is the output voltage of the charger 1, and stops charging. However, when charging continues due to an abnormality in the assembled battery 4, the measured value of the temperature sensor 6 is 60 ° C. (first When the temperature becomes equal to or higher, the control unit 2 generates a control signal for stopping the charger 1 and transmits the control signal to the charging control line 7, and the charger 1 stops.

  When charging continues in an abnormal state of the assembled battery 4 and the control unit 2 fails and the charger 1 cannot be stopped, the temperature switch 5 of the battery pack 3 in the abnormal charging state is opened, and the temperature switch Since the circuit 9 is opened, the operation of the charger 1 is stopped.

  In this way, by providing double charging stop mechanisms, charging during overheating is stopped reliably, reducing the life due to deterioration of the secondary battery, preventing ignition and leakage.

  In the present embodiment, the temperature switch 5 is opened at the second temperature (80 ° C.) or higher and closed at the lower temperature (first case). There is also a method of closing at above (° C.) and opening at below (second case). In this method, the charger 1 may be controlled to output DC power to the assembled battery 4 when the temperature switch circuit 9 is open, and to stop when the temperature switch circuit 9 is closed.

  In the present embodiment, the second temperature (80 ° C.) is set higher than the first temperature (60 ° C.). This is because the control unit 2 is normally mounted with functions such as a communication function, and has an advantage that a warning can be issued when the secondary battery is overheated to notify the supervisor. This is because overheating can be detected quickly. As long as charging is reliably stopped at the time of overheating, the first and second temperatures may be the same or higher as long as the temperature does not cause deterioration, ignition, or liquid leakage. Absent.

  Further, in the present embodiment, the charger 1 performs control depending on whether the temperature switch circuit 9 is open or closed, but a reference voltage is applied to one end of the temperature switch circuit 9 and the other end is connected to the charger 1. There is also a method of performing charging control by determining whether or not a reference voltage is transmitted by inputting. In this method, for example, 5 V is applied to one end of the temperature switch circuit 9, and the other end (input to the charger 1) is grounded (0 V) via a resistor. If the temperature switch 5 inserted into the temperature switch circuit 9 is closed, a reference voltage (5 V) is applied to the other end, and at this time, the charger 1 may be controlled so that it can be charged. Conversely, one end of the temperature switch circuit 9 is grounded (0V), the other end is connected to the reference voltage (5V) through a resistor, and the charger 1 is able to be charged when the other end is 0V. There is also a method. There is also a method of prohibiting charging of the charger 1 when the temperature switch 5 is closed at a threshold value or more and the voltage applied to one end is detected at the other end.

  Features of the power supply system according to the present invention include, for example, a plurality of assembled batteries formed by connecting one or more secondary batteries, a charger that charges the plurality of assembled batteries, and an operation of the charger. In the battery system including the control unit, each of the assembled batteries includes a temperature sensor and a temperature switch, each of the temperature sensors is input to the control unit, and the temperature switch is connected to the charger. The control unit performs control to stop the operation of the charger when the temperature input from the temperature sensor is equal to or higher than the first temperature, and stops the operation when the temperature switch is open. The switch for detecting the mounting of the assembled battery closes the mounting presence / absence detecting switch connected in parallel to the temperature switch when not mounted. With this feature, in a battery system for charging a secondary battery, it is possible to provide a battery system that reliably stops charging when the battery is overheated and prevents life reduction, ignition and leakage due to deterioration of the secondary battery. Become.

  As described above, the embodiment of the present invention has been described by taking the case where the secondary battery is a lead storage battery or a nickel metal hydride storage battery as an example, but the present invention is not limited thereto.

  Below, the effect produced by this invention is demonstrated.

  (1) When charging a secondary battery with a charger, the monitoring control unit detects abnormal temperatures when the temperature of the secondary battery exceeds a certain value in preparation for charging to continue due to a malfunction of the full charge detection function. However, due to the failure of the monitoring control unit itself, charging control may become impossible and charging may continue.In this case, the secondary battery overheats and deteriorates. Progresses and the life is shortened, and further, there is a problem that it leads to ignition or leakage.

  According to the present invention, it is possible to provide a battery system that reliably stops charging when overheated and prevents a reduction in life, ignition and leakage due to deterioration of the secondary battery.

  (2) In a battery system in which the number of battery packs mounted is variable, when a temperature switch that is opened when overheated is used to stop charging, a part corresponding to the temperature switch is considered open when a part is not mounted, The battery is falsely detected as overheated.

  According to the present invention, since the non-mounting of the battery pack is detected and the portion corresponding to the temperature switch is closed, charging can be stopped when overheating is detected regardless of the number of mounting.

  1: charger, 2: control unit, 3: battery pack, 4: assembled battery, 5: temperature switch, 6: temperature sensor, 7: charge control line, 8: temperature detection line, 9: temperature switch circuit, 10: Charging switch, 11: battery mounting frame, 12: mounting presence / absence detection switch.

Claims (5)

In a battery system comprising: a plurality of assembled batteries formed by connecting one or more secondary batteries; a charger that charges the plurality of assembled batteries; and a control unit that controls the operation of the charger.
Each of the assembled batteries includes a temperature sensor that detects the temperature of the assembled battery, and a temperature switch that opens and closes depending on the temperature of the assembled battery,
The temperature of the assembled battery detected by the temperature sensor is input to the control unit,
When the temperature of the assembled battery input from any one of the temperature sensors is equal to or higher than a first temperature, the control unit issues a control signal for stopping the operation of the charger to the charger.
The temperature switches are each connected to the charger by a separate temperature switch circuit,
As a first case, the temperature switch is opened when the temperature of the assembled battery including the temperature switch is equal to or higher than a second temperature higher than the first temperature, and the temperature is changed to the second temperature. When the temperature is less than the temperature, the charger is closed, and when the control signal is not transmitted, the charger is in an inoperative state when any of the temperature switch circuits is open, or
As a second case, the temperature switch is closed when the temperature of the assembled battery including the temperature switch is equal to or higher than the second temperature, and is opened when the temperature is lower than the second temperature. The battery system is in a state where the battery charger is in an operation stop state when any of the temperature switch circuits is closed when the control signal is not transmitted. The temperature switch and the charger perform the operation in the first case,
The battery system according to claim 1, wherein a temperature switch circuit formed by connecting the temperature switches in series is connected to the charger. The battery system according to claim 1 or 2,
For each assembled battery, a charging switch is inserted into the power supply line from the charger,
When the temperature of the assembled battery input from the temperature sensor is equal to or higher than the first temperature without stopping the operation of the charger, the control unit feeds the assembled battery at the temperature at least. A battery system for generating a control signal for opening the charging switch inserted in the battery. The battery system according to claim 1,
A mounting frame for mounting the assembled battery is provided,
The mounting frame comprises a mounting presence / absence detection switch that opens and closes by detecting whether the assembled battery is mounted,
The mounting presence / absence detection switch is open when the assembled battery is mounted, and closed when not mounted.
The battery system according to claim 1, wherein the mounting presence / absence detection switch is connected in parallel to the temperature switch that opens and closes depending on a temperature of the assembled battery when the assembled battery is mounted. The battery system according to any one of claims 1 to 3,
A mounting frame for mounting the assembled battery is provided,
The mounting frame comprises a mounting presence / absence detection switch that opens and closes by detecting whether the assembled battery is mounted,
The battery mounting system is characterized in that the mounting presence / absence detection switch is not connected to the temperature switch but is individually connected to the control unit.

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