JP2002110259A - Storage battery device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform sure monitor control of cells in a storage battery device and inexpensively reduce the wiring space for a cell monitor devices and the number of assembling and inspecting man-hours without requiring address identifying circuit parts for the cell monitor devices. SOLUTION: Master-side control means 23 is provided in a control device 1 for controlling the storage battery device and slave-side control means 14 is provided in each of the plurality of cell monitoring devices 2 for monitoring cell voltage. A self-address set by the processing operation of the master-side control means 23 and the slave-side control means 14 is stored in a storage part and the self-address is added to a control signal based on the cell voltage detected by a voltage detection circuit 13 and then transmitted to the master-side control means 23.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power storage device, and more particularly, to a mobile device such as an electric car or an electric cart,
It is suitable for a power storage device used as a DC power supply for products such as portable devices such as video cameras and personal computers, power supply backup devices in the event of a power failure, and security devices.

[0002]

2. Description of the Related Art In recent years, secondary batteries such as nickel-metal hydride batteries and lithium batteries are excellent in energy density and life, and are being put to practical use as home power storage devices and other power storage media. In these secondary batteries, for example, when used as a power source of a mobile device or a household device, in order to efficiently maintain a required output for a predetermined time, 10 to 30 seconds are required.
Ah battery capacity and a battery voltage of about 100 to 350 V are required. Therefore, a plurality of nickel-metal hydride batteries having a nominal voltage of 1.2 V and lithium batteries having a nominal voltage of 3.6 V are connected in series to form an assembled battery, and a power supply voltage required for the device is obtained using the battery.

A secondary battery is a battery that can be used repeatedly by charging a discharged battery. However, the secondary battery has a limiting voltage value at the time of charging and at the time of discharging, respectively, depending on the composition of the secondary battery itself. Charging or discharging may cause performance degradation of the secondary battery. For this reason, when charging / discharging a secondary battery, a method of charging / discharging while monitoring the battery voltage is adopted.

[0004] Such an assembled battery monitoring apparatus is disclosed in, for example, Japanese Patent Application Laid-Open No. 9-139237, in order to specifically identify a defective storage battery in the assembled battery. A voltage monitoring unit for measuring a battery voltage is provided for each module battery, and battery voltage data detected by each voltage monitoring unit is transmitted to a control device. Then, in order to reduce the number of signal wires between the plurality of voltage monitoring units and the control device that needs the information and the number of signal wires between the voltage monitoring units, the voltage monitoring unit and the control device and each voltage monitoring unit are reduced. The signal wiring between units is a serial signal wiring, and each voltage monitoring unit is equipped with a dip switch. Each address is set in advance by this dip switch, and the address of each voltage monitoring unit is added to the voltage data transmitted to the control device. Thus, the identification in the control device is enabled.

[0005]

However, such a conventional battery monitoring system requires a setting switch for setting an address in each voltage monitoring unit, so that the number of wires in each voltage monitoring unit is limited. In addition, there is a possibility that the address may be set erroneously, resulting in an increase in the number of assembling steps and inspection steps and an increase in cost.

SUMMARY OF THE INVENTION An object of the present invention is to eliminate the need for a circuit component for address identification of each battery monitoring device, which is provided for reliable battery monitoring control, and to reduce the wiring space, assembly man-hour and inspection man-hour of the battery monitoring device. To get the equipment.

[0007]

A first feature of the present invention to achieve the above object is that a plurality of rechargeable batteries connected in series and a battery voltage of the rechargeable batteries in one or more predetermined units are provided. A plurality of battery monitoring devices, a control device that controls a power storage device, and signal wiring that connects the control device and the battery monitoring device and between the battery monitoring devices, wherein the control device is a master side. Control means, the battery monitoring device includes a slave control means having a storage unit, a voltage detection circuit for detecting the battery voltage of the secondary battery and outputting to the slave control means, Each slave-side control means stores a respective self-address set by the processing operation with the master-side control means in the storage unit, and outputs a control signal based on a battery voltage detected by the voltage detection circuit. It adds the self address stored in the storage unit in that a configuration to be transmitted to the master control unit.

A second feature of the present invention is that a plurality of secondary batteries connected in series, a plurality of battery monitoring devices for monitoring the battery voltage of the secondary batteries in one or more predetermined units, and a power storage device are provided. A control device for controlling, and a bus signal line connecting the control device and each of the battery monitoring devices, wherein the control device has master-side control means, and the battery monitoring device includes a random number generation unit and a storage unit. And a voltage detection circuit that detects the battery voltage of the secondary battery and outputs the battery voltage to the slave-side control unit, wherein each of the slave-side control units is generated by the random number generation unit. Each of the self-addresses set by the processing operation with the master-side control means based on the temporary address is stored in the storage section, and the control signal output based on the battery voltage detected by the voltage detection circuit. It adds the self address stored in the storage unit in that a configuration to be transmitted to the master control means.

A third feature of the present invention is that a plurality of secondary batteries connected in series, a plurality of battery monitoring devices for monitoring the battery voltage of the secondary batteries in one or more predetermined units, and a power storage device are provided. A control device for controlling, and a bus signal wiring for connecting the control device and each of the battery monitoring devices are provided, the control device has master-side control means, and the battery monitoring device has a connection port and an insulation circuit. A communication interface circuit, a slave-side control unit having a storage unit, and a voltage detection circuit that detects a battery voltage of the secondary battery and outputs the battery voltage to the slave-side control unit. And the slave-side control means, wherein each of the slave-side control means stores, in the storage unit, its own address set by the processing operation with the master-side control means. To, by adding a self-address stored in the storage unit in the control signal to be output based on the battery voltage detected by the voltage detecting circuit lies in that a configuration to be transmitted to the master control unit.

[0010] A fourth feature of the present invention is that a plurality of secondary batteries connected in series, a plurality of battery monitoring devices for monitoring the battery voltage of the secondary batteries in one or more predetermined units, and a power storage device are provided. A control device for controlling, and signal wiring for connecting between the control device and the battery monitoring device and between the battery monitoring devices, wherein the control device includes a connection port, an insulation circuit, an insulation circuit power supply, and master-side control means. Wherein the insulation circuit of the control device is provided between the connection port and the master side control means, the battery monitoring device is a communication interface circuit having a connection port and an insulation circuit, and a slave side having a storage unit. Control means, and a voltage detection circuit for detecting a battery voltage of the secondary battery and outputting the detected voltage to the slave-side control means. Provided between the control circuit and the side control means, the insulation circuit power supply, the power supply to the insulation circuit of the control device and the insulation circuit of each battery monitoring device, the slave side control means, the master side control means, The self-addresses stored in the storage unit are stored in the storage unit, and the self-address stored in the storage unit is added to a control signal output based on the battery voltage detected by the voltage detection circuit. The configuration is such that the data is transmitted to the master-side control means.

A fifth feature of the present invention is that a plurality of secondary batteries connected in series, a plurality of battery monitoring devices for monitoring the battery voltage of the secondary batteries in one or more predetermined units, and a power storage device are provided. A control device for controlling, and a serial communication signal wiring for connecting the control device and the battery monitoring device and between the battery monitoring devices, wherein the control device has master-side control means, and the battery monitoring device is A slave-side control unit having a storage unit, and a voltage detection circuit that detects a battery voltage of the secondary battery and outputs the battery voltage to the slave-side control unit,
Each of the slave-side control means stores the own address set by changing and processing the message transmitted from the master-side control means in the storage unit, and stores the changed message in the next slave-side control means. It is configured to relay the control signal output based on the battery voltage detected by the voltage detection circuit, add a self-address stored in the storage unit, and transmit the control signal to the master-side control unit.

[0012]

Embodiments of the present invention will be described below with reference to the drawings.

First, a first embodiment of the present invention will be described with reference to FIGS.
This will be described with reference to FIG.

First, a configuration of a power storage device according to a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a configuration diagram of a power storage device according to a first embodiment of the present invention, and FIG. 2 is a configuration diagram of an assembled battery in the power storage device of FIG.

In FIG. 1, a power storage device includes a control device 1,
A plurality of assembled batteries 5 and signal wirings 6 and 7 for connecting these are provided. The control device 1 constitutes a master with the battery pack 5 as a slave, and includes a connection port 21, an insulation circuit 22, a master-side control means 23, and an insulation circuit power supply 2.
Four. The connection port 21 is a port through which the control device 1 transmits and receives signals to and from the outside, and is connected to the first connection port 9 of the battery pack 5 via the signal wiring 6. The insulating circuit 22 insulates signals having different potential levels from the internal circuit of the control device 1 (specifically, the master-side control means 23) and maintains electrical independence from the outside of the battery pack 5. It is.

The master-side control means 23 is composed of, for example, a microcomputer and controls the entire power storage device.
And transmits and receives signals to and from the outside via the insulation circuit 22 and the connection port 21, and outputs an on / off signal to the insulation circuit power supply 24. The insulation circuit power supply 24 is mounted only on the control device 1 and operates based on an on / off signal from the master-side control means 23.
Power is supplied to the insulation circuit 22 and the insulation circuit 11 of each battery pack 5. Thus, the insulation circuit power supply 24 is
And the control device 1 is entrusted with the power cutoff operation related to the reduction in power consumption, thereby simplifying the configuration of the entire device.

The battery pack 5 includes a module battery 4 and a battery monitoring device 2, and constitutes a slave having the control device 1 as a master.

The module battery 4 is configured by connecting a plurality of secondary batteries 3 such as nickel-metal hydride batteries and lithium batteries in series, and is provided so as to generate a required voltage.

The battery monitoring device 2 includes a communication interface circuit 12, a slave control unit 14, a voltage detection circuit 13,
And a signal presence / absence detection circuit 17. The communication interface circuit 12 includes a connection port 19 and an insulation circuit 11.
have. The connection port 19 has a first connection port 9 and a second connection port 10, as shown in FIG. 2, and the first connection port 9 and the second connection port 10 are directly connected. The first connection port 9 in the battery monitoring device 2 connected first to the control device 1 is:
It is connected to the connection port 21 of the control device 1 via the signal wiring 6. The second connection port 10 is connected to the next battery monitoring device 2.
Is connected to the first connection port 9 via the signal wiring 7. The first connection port 9 of the second and subsequent battery monitoring devices 2 is connected to the second connection port 10 of the previous battery monitoring device 2.
Are connected via a signal wiring 7. The last battery monitoring device 2 is connected to the previous battery monitoring device 2 by the first connection port 9.
, And there is no need to connect the second connection port 10 to the next battery monitoring device 2. The insulation circuit 11
It insulates signals having different potential levels from internal circuits of the battery monitoring device 2 (specifically, the slave-side control means 14, the signal presence / absence detection circuit 17, and the voltage detection circuit 13), and includes the control device 1 and other batteries. The monitoring device 2 is kept electrically independent. As a result, the signal wiring 6 connecting the control device 1 and the battery monitoring device 2, the signal wiring 7 connecting the battery monitoring devices 2, and the connection ports 9 and 10 are connected to the control device 1.
And, it becomes a state of being connected independently of the internal circuit of the battery monitoring device 2, and can maintain the communication function without being electrically affected by these internal circuits.

The voltage detection circuit 13 detects the battery state of each secondary battery 3. Specifically, it detects the battery voltage at both ends of each secondary battery 3 and controls the detected battery voltage on the slave side. It is connected to output to the means 14.

The slave-side control means 14 is composed of, for example, a microcomputer. The slave-side control means 14 communicates with the control device 1 and another battery pack 5 via the communication interface circuit 12 and detects the battery voltage detected by the voltage detection circuit 13. A signal is input. If the battery voltage detected by the voltage detection circuit 13 exceeds the limit voltage value of the secondary battery 3, the slave-side control means 14 recognizes the battery voltage, and sends an address set as described later and fault information. A certain control signal is transmitted to the control device 1 through the communication interface circuit 12. Thereby, the control device 1 can identify and recognize the defective battery pack. Further, the slave-side control means 14 has a random number generation unit 15 for generating a temporary address and a storage unit 16 for storing the set address.

The signal presence / absence detection circuit 17 detects the presence / absence of a signal on the line, outputs the signal to the slave side control means 14, and outputs the control signal from the slave side control means 14 when there is no signal on the line. Is controlled. Thus, the output of the bus communication signal lines 6 and 7 onto the line can be performed with a short waiting time.

The signal wiring 6 connects the control device 1 for controlling the entire power storage device and the battery monitoring device 2 to transmit and receive information. The signal wiring 7 is connected to each battery monitoring device 2.
To transmit and receive information. Information to be transferred between the control device 1 and the battery pack 5 and between the battery packs 5 is transmitted and received using the bus connection by the signal wires 6 and 7. Therefore, in this embodiment, information of one transmission source is transmitted to another reception destination at the same time. As a result, control based on detection of a defective secondary battery can be performed quickly, and high reliability can be achieved.

The signal lines 6 and 7 are separately provided as power supply lines together with the bus communication signal lines.
The power of the insulating circuit is supplied to the plurality of battery monitoring devices 2. In addition, as a method of also serving as the bus communication signal line and the power supply line of the insulating circuit power supply 24, it is conceivable to superimpose a signal on the power supply line and to separate only the signal by a difference in frequency band. By doing so, it is possible to reduce the number of cables.

Next, an example of a method for setting a slave address of the power storage device will be described with reference to FIG. FIG. 3 is a flowchart showing a slave address setting method of the power storage device of FIG. FIG. 3A shows a control device 1 on the master side.
FIG. 3B is a flowchart showing the operation of the battery pack 5 on the slave side.

When the master-side control means 23 determines that the setting or resetting of the slave address is necessary, the master-side control means 23 sends an address to all the slave-side control means 14 connected by the bus-connected signal wirings 6 and 7. A setting command is issued or an address reset command is issued and transmitted (step 40). Here, the case of resetting the address will be described, but the same applies to the case where the address setting is necessary.

When receiving this command, the slave-side control means 14 performs a command receiving process (step 50), and determines the type of the command (step 51). In this determination, if it is determined that the command is an address reset command, a random number generation unit 15 (here, a random number generation program using the battery voltage detection data as a seed) of the slave-side control unit 14 is used. Is a predetermined upper limit value and is 255 in this case), and the random number is used as a temporary self address (step 52).

Next, the reply data is prepared (step 53), the temporary address is counted as the waiting time, the reply waiting time is adjusted by the adopted random number (step 54), and the temporary address is returned. Is transmitted to the master-side control means 23 (step 55). The waiting time can be set to the minimum necessary waiting time by using the signal presence detecting circuit 17 together.

The master control means 23, which has received the provisional address from the slave control means 14, performs a provisional address reception process (step 41), and determines whether the number of valid reception data is equal to the number of provisional address types. Is determined (step 42). On the master side control unit 23 side, if all the slave side control units 14 have different temporary addresses, the number of valid reception data and the number of types of temporary addresses should be finally the same.
If it is determined that the number of valid reception data and the number of types of temporary addresses are not the same, the process returns to step 40 to issue an address reset command, and is repeated until the number of valid reception data and the number of types of temporary addresses become the same. .

If the number of valid received data and the number of types of temporary addresses are the same in step 42, the master-side control means 23 determines whether the temporary addresses are duplicated (step 43). If there is an overlap in the temporary addresses, the process returns to step 40 to issue an address reset command, and repeats until there is no overlap in the temporary addresses.

When duplication of the temporary address is eliminated, the master-side control means 23 issues an address determination command, assuming that different address data is distributed to all of the slave-side control means 14, and issues an address determination command. It is transmitted to the slave side control means 14. In response to the transmission of the address determination command, the slave-side control means 14
A command receiving process is performed (step 50), and the type of the command is determined (step 51). In this judgment,
If it is determined that the command is an address determination command, the temporary address is stored in the storage unit 16 as the true self address of the master-side control unit 23 (step 5).
6) The processing from step 53 to step 55 is performed.
In this way, the addresses of the plurality of battery monitoring devices 2 can be automatically determined.

As described above, since the temporary address is generated by the random number generation unit 15 and the processing is performed so as to determine the temporary address as the self address, the self address can be easily set in each battery monitoring device 2.

If it is determined in step 51 that the type of the command is not the address setting command or the address determination command, the process returns to step 50.

According to this embodiment, the battery monitoring device 2 uses the address automatically set by the processing operation of the control means.
If the battery voltage detected by the voltage detection circuit 13 exceeds the limit voltage value of the secondary battery 3, the slave side control means 14 recognizes the battery voltage and sends the defect information together with this address. Is transmitted to the control device 1 through the communication interface circuit 12 so that the master-side control unit 23 of the control device 1 can identify the defective battery pack 5. Therefore, the control device 1 can reliably perform the necessary control by specifying the defective battery pack 5, for example, alarming the existence of the battery pack 5 to the outside.

Further, since circuit components such as a dip switch for setting an address in each voltage monitoring device 5 are not required, the number of wirings in each voltage monitoring device 5 can be reduced.
It is possible to prevent erroneous wiring and erroneous address setting based on circuit components, to reduce the number of assembling steps and inspection steps, and to reduce the number of circuit parts and wiring space in each voltage monitoring device 5, thereby reducing costs. it can.

Furthermore, since the control means of the control device 1 is the master control means and the control means of each battery monitoring device 2 is the slave control means, the plurality of battery monitoring devices 2 are substantially the same. And can be inexpensive.

Next, a second embodiment of the present invention will be described with reference to FIGS.
This will be described with reference to FIG.

First, the configuration of the battery pack in the power storage device according to the second embodiment of the present invention will be described with reference to FIG. FIG. 4 is a configuration diagram of a battery monitoring device in a power storage device according to a second embodiment of the present invention. In the present embodiment, the connection configuration with the control device and other battery monitoring devices is common to that of the first embodiment, so that illustration and redundant description are omitted.

The battery monitoring device 2 shown in FIG. 4 receives information from the upstream master at the connection port 9 when the control device 1 as the master and the battery monitoring device 2 as the slave are connected. , The information is relayed from the connection port 10 to the downstream slaves, the downstream slaves are also relayed by the same means, and the information from the master is transmitted to all the slaves. The serial communication signal wirings 6 and 7 are provided.

Specifically, a first insulation circuit 11a and a second insulation circuit 11b are provided as insulation circuits, and the first connection port 9 and the first insulation circuit 11a are connected to the differential amplifier 18a for reception and the differential amplifier for transmission. The connection is made via an amplifier 18b, and the second connection port 10 and the second insulating circuit 11b are connected via a reception differential amplifier 18c and a transmission differential amplifier 18d. The first insulating circuit 11a is connected to the input port Si1 and the output port So2 of the slave control means 14, and the second insulating circuit 11b is connected to the slave control means 1
4 is connected to the input port Si2 and the output port So2.

The slave side control means 14 has a storage section 16 for recording an address, but does not have the random number generation section shown in the first embodiment.

Next, an example of a method of setting a slave address of the power storage device will be described with reference to FIG. FIG. 5 is a message format showing a slave address setting method of the power storage device according to the second embodiment of the present invention. This embodiment is characterized in that a telegram (command data sentence) is used to set the slave address.

When it is determined that the setting or resetting of the slave address is necessary, the master-side control means 23 determines the first slave-side control means 1 connected by the signal wiring 6.
4 and transmits and transmits a message A for address setting or a message A for address resetting. In this message example, the maximum number of slave connections is 16, and the number of actually configured slaves is 8.
This is an example of a message in the case where the number is set, and includes a message type, a command type, attached data, and the like. The message type is information for distinguishing transmission from the master side to the slave side or transmission from the slave side to the master side, and becomes H'00 in the former case and H'01 in the latter case. . The command type is information for distinguishing between address setting and address resetting. The attached data is information for identifying and identifying the slave address, and is assigned to the actual slave from the first bit by the number of the actual slaves, and 1 is set to the subsequent bits. In addition,
Here, the case of address reset will be described.
Address setting is performed in the same manner.

When the first slave side control means 14 connected first to the master side control means 23 receives the above-mentioned message A from the master side control means 23 through the first connection port 9, this first message A Is determined by the master-side control means 23 and the first slave-side control means 1
4 and processes the data bit indicating the existence of itself, such as message B, into the 8th bit of the attached data and stores it in the storage unit 16 as its own address.
The message B is relayed from the connection port 10 to the downstream control means 14 on the downstream side.

When receiving the message A, the next downstream slave side control means 14 judges the message B and determines that it is the second slave side control means 14 from the master side control means 23. After recognizing and processing the data bit indicating the existence of itself to the seventh bit of the attached data of the message and storing it in the storage unit 16 as its own address, the second
The message is relayed from the connection port 10 to the slave side control means 14 on the downstream side. In this way, the self address of each slave side control means 14 is automatically set and stored in the storage section 16.
And relays the message to the slave-side control means 14 on the downstream side while sequentially processing the message.

The terminal (eighth in this embodiment) slave side control means 14 is the master side control means 2.
3 can set the total number of slaves in advance, so that when the slave-side control means 14 at the end processes the message,
The end slave side control means 14 itself can recognize that it is the end. As a result, the slave side control means 14 at the end changes the message type to H'01, and returns the message C to the upstream slave side control means 14 instead of the downstream slave side control means 14 this time. I do.

The next upstream slave-side control means 14 changes the message type to H'01, relays it further upstream, and finally the message C is transmitted to the master-side control means 23. Thereby, the master-side control unit 23 can confirm whether the address setting of all the slave-side control units 14 is completed.

As described above, in this embodiment, the communication addresses of the plurality of battery monitoring devices 2 can be determined automatically and in the order of connection.

[0049]

According to the present invention, reliable battery monitoring control can be performed, and the wiring space and the number of assembling steps of the battery monitoring device can be reduced without requiring a circuit component for address identification of each battery monitoring device. Further, a power storage device that can reduce the number of inspection steps can be obtained.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a power storage device according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a battery pack in the power storage device of FIG.

FIG. 3 is a flowchart showing a slave address setting method of the power storage device of FIG.

FIG. 4 is a configuration diagram of a battery pack in a power storage device according to a second embodiment of the present invention.

FIG. 5 is a message format showing a slave address setting method according to a second embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Control device, 2 ... Battery monitoring device, 3 ... Secondary battery, 4 ...
Module battery, 5 battery pack, 6 signal wiring, 7 signal wiring, 9 first connection port, 10 second connection port, 1
DESCRIPTION OF SYMBOLS 1 ... Insulation circuit, 12 ... Communication interface circuit, 13
... voltage detection circuit, 14 ... slave side control means, 15 ... random number generation unit, 16 ... storage unit, 17 ... signal presence / absence detection circuit, 1
9 connection port, 21 connection port, 22 insulation circuit,
23: master side control means, 24: insulation circuit power supply.

Continuing on the front page (72) Inventor Toyooka Okawa 800, Tomita, Odai-machi, Ohira-machi, Shimotsuga-gun, Tochigi Prefecture Inside the Hitachi, Ltd.Cooling Division F-term in business division (reference) 5G003 BA03 EA08 FA06 FA08 GC05 5H030 AA09 AS03 AS08 AS11 FF44

Claims (5)

[Claims] 1. A plurality of secondary batteries connected in series, a plurality of battery monitoring devices monitoring the battery voltage of the secondary batteries in one or more predetermined units, a control device controlling a power storage device,
A signal line for connecting the control device and the battery monitoring device and each of the battery monitoring devices, wherein the control device has master-side control means, and the battery monitoring device has a slave-side control having a storage unit. Means, and a voltage detection circuit for detecting the battery voltage of the secondary battery and outputting the battery voltage to the slave-side control means, wherein each of the slave-side control means is set by a processing operation with the master-side control means. Each of the self addresses is stored in the storage unit, and the self address stored in the storage unit is added to a control signal output based on the battery voltage detected by the voltage detection circuit and transmitted to the master side control unit. A power storage device, comprising: 2. A plurality of rechargeable batteries connected in series, a plurality of battery monitoring devices monitoring the battery voltage of the rechargeable batteries in one or more predetermined units, a control device controlling a power storage device,
A bus signal line for connecting between the control device and each of the battery monitoring devices, wherein the control device has master-side control means, and the battery monitoring device has a random-number generation unit and a storage unit. And a voltage detection circuit that detects the battery voltage of the secondary battery and outputs the battery voltage to the slave-side control unit, wherein each of the slave-side control units is based on a temporary address generated by the random number generation unit. The respective self-addresses set by the processing operation with the master-side control means are stored in the storage unit, and the self-address stored in the storage unit is output to a control signal output based on the battery voltage detected by the voltage detection circuit. A power storage device, wherein an address is added and transmitted to the master-side control means. 3. A plurality of secondary batteries connected in series, a plurality of battery monitoring devices monitoring the battery voltage of the secondary batteries in one or more predetermined units, a control device controlling a power storage device,
A bus interface for connecting the control device and each of the battery monitoring devices, the control device has master-side control means, the battery monitoring device has a communication interface circuit having a connection port and an insulation circuit, A slave-side control unit having a storage unit; and a voltage detection circuit for detecting a battery voltage of the secondary battery and outputting the battery voltage to the slave-side control unit, wherein the insulation circuit includes the connection port and the slave-side control unit. , Each of the slave-side control means,
While storing each self-address set by the processing operation with the master-side control means in the storage unit,
A power storage device, wherein a self-address stored in the storage unit is added to a control signal output based on a battery voltage detected by the voltage detection circuit, and the control signal is transmitted to the master-side control unit. 4. A plurality of secondary batteries connected in series, a plurality of battery monitoring devices for monitoring the battery voltage of the secondary batteries in one or more predetermined units, a control device for controlling a power storage device,
The control device and the battery monitoring device and signal wiring for connecting between each battery monitoring device, the control device,
A connection port, an insulation circuit, an insulation circuit power supply and a master-side control means, an insulation circuit of the control device is provided between the connection port and the master-side control means, and the battery monitoring device includes a connection port and an insulation A communication interface circuit having a circuit, a slave-side control unit having a storage unit, and a voltage detection circuit that detects a battery voltage of the secondary battery and outputs the battery voltage to the slave-side control unit. An insulation circuit is provided between the connection port and the slave-side control means, and the insulation circuit power supply supplies power to the insulation circuit of the control device and the insulation circuit of each of the battery monitoring devices. Means for storing the respective self-addresses set by the processing operation with the master-side control means in the storage unit, and detecting the battery detected by the voltage detection circuit. Power storage device and transmits to the master-side control means adds the self address stored in the storage unit in the control signal to be output on the basis of the pressure. 5. A plurality of rechargeable batteries connected in series, a plurality of battery monitoring devices monitoring the battery voltage of the rechargeable batteries in one or more predetermined units, a control device controlling a power storage device,
A serial communication signal line connecting the control device and the battery monitoring device and between the battery monitoring devices, wherein the control device has master-side control means, and the battery monitoring device is a slave having a storage unit. Side control means, and a voltage detection circuit for detecting the battery voltage of the secondary battery and outputting the detected voltage to the slave side control means, wherein each of the slave side control means includes a message transmitted from the master side control means. Control in which the self-addresses set by performing the changing process are stored in the storage unit, and the changed message is relayed to the next slave-side control means, and is output based on the battery voltage detected by the voltage detecting circuit. A power storage device, wherein a self-address stored in the storage unit is added to a signal and transmitted to the master-side control unit.