WO2006115037A1 - 電池パック及びその接続システム - Google Patents
電池パック及びその接続システム Download PDFInfo
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- WO2006115037A1 WO2006115037A1 PCT/JP2006/307619 JP2006307619W WO2006115037A1 WO 2006115037 A1 WO2006115037 A1 WO 2006115037A1 JP 2006307619 W JP2006307619 W JP 2006307619W WO 2006115037 A1 WO2006115037 A1 WO 2006115037A1
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- WO
- WIPO (PCT)
- Prior art keywords
- charging
- terminal
- information
- charge
- battery pack
- Prior art date
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Classifications
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/46—Accumulators structurally combined with charging apparatus
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/48—Accumulators combined with arrangements for measuring, testing or indicating the condition of cells, e.g. the level or density of the electrolyte
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/0029—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries with safety or protection devices or circuits
- H02J7/0031—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries with safety or protection devices or circuits using battery or load disconnect circuits
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/007—Regulation of charging or discharging current or voltage
- H02J7/00712—Regulation of charging or discharging current or voltage the cycle being controlled or terminated in response to electric parameters
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B3/00—Line transmission systems
- H04B3/54—Systems for transmission via power distribution lines
- H04B3/548—Systems for transmission via power distribution lines the power on the line being DC
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/425—Structural combination with electronic components, e.g. electronic circuits integrated to the outside of the casing
- H01M10/4257—Smart batteries, e.g. electronic circuits inside the housing of the cells or batteries
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/00032—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries characterised by data exchange
- H02J7/00045—Authentication, i.e. circuits for checking compatibility between one component, e.g. a battery or a battery charger, and another component, e.g. a power source
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B2203/00—Indexing scheme relating to line transmission systems
- H04B2203/54—Aspects of powerline communications not already covered by H04B3/54 and its subgroups
- H04B2203/5404—Methods of transmitting or receiving signals via power distribution lines
- H04B2203/5416—Methods of transmitting or receiving signals via power distribution lines by adding signals to the wave form of the power source
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B2203/00—Indexing scheme relating to line transmission systems
- H04B2203/54—Aspects of powerline communications not already covered by H04B3/54 and its subgroups
- H04B2203/5429—Applications for powerline communications
- H04B2203/5454—Adapter and plugs
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B2203/00—Indexing scheme relating to line transmission systems
- H04B2203/54—Aspects of powerline communications not already covered by H04B3/54 and its subgroups
- H04B2203/5462—Systems for power line communications
- H04B2203/547—Systems for power line communications via DC power distribution
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
Definitions
- the present invention relates to a battery pack using a secondary battery and a connection system for connecting the battery pack to a charging device or a load device.
- the charging device is defined as a device that is connected to the battery pack and supplies charging power to the secondary battery
- the load device is defined as a device that is connected to the battery pack and operates by the discharging power of the secondary battery.
- Battery packs using secondary batteries are widely used as power sources for portable electronic devices such as mobile phones, notebook personal computers (hereinafter referred to as notebook personal computers), and PDAs.
- the battery pack has a function to protect the secondary battery from overcharge, overdischarge, short circuit, etc., a function to calculate and display the remaining capacity according to the requirements of the charging device or load device to which it is connected, A function to communicate with the load device, compatibility with the connection device, or a function to detect imitations is provided as appropriate.
- a battery pack 100 of a mobile phone includes a secondary battery 101, a battery protection IC 102 and a protection element 105 that protect the secondary battery 101 from overdischarge, overcharge, and overcurrent.
- PTC element 103 that suppresses short-circuit current
- thermistor 104 for detecting battery temperature during charging, etc. are connected.
- Connecting terminals 106, 107, 108 are connected to the charging device, and thermistor 104 monitors the battery temperature.
- the battery pack is charged and connected to the load device (mobile phone) by connecting terminals 106 and 107 to discharge the battery power to the load device.
- a smart battery system that conforms to the system management bus standard that connects the battery pack and the computer itself with a bidirectional 2-wire bus is used for the laptop computer to manage power. Has been.
- a battery pack that can be connected is specified in order to prevent a failure or accident caused by being connected to a charging device that does not support the battery pack, or to prevent a failure or accident caused by using a counterfeit battery pack.
- a battery pack provided with ID storage means for recording identification information is known.
- Figure 8 shows that the imitation battery pack is connected to the load device and In order to prevent the battery pack from being connected to a charging device other than the battery charger, an ID circuit unit 207 is provided in the battery pack 200, and a connecting device (load device or charging device) for connecting the battery pack 200.
- 1 shows a conventional configuration of a battery pack provided with an ID detection unit 307 on the 300 side and a connection system thereof.
- a battery pack 200 includes a secondary battery 201, temperature detection means 202 that detects the temperature, voltage, and charge / discharge current of the secondary battery 201, voltage detection means 203, and current detection means 204. And a control circuit 206 that detects the overcharge, overdischarge, and overcurrent states of the secondary battery 201 from the detection information from each detection means and controls the protection element 205 to ONZOFF, and an ID circuit section that stores identification information 207, the positive and negative electrodes of the secondary battery 201 are connected to the positive electrode charging / discharging terminal 208 and the negative electrode charging / discharging terminal 209, respectively, and the ID circuit unit 207 is connected to the ID terminal 210.
- connection device 300 indicates a charging device here, the charging power supply 301, the ID detection unit 307 that reads identification information from the ID circuit unit 207, and the compatibility of the read identification information power battery pack 200 And a condition selection unit 306 for controlling the output of the charging power from the charging power source 301.
- connection between the battery pack and the charging device or the load device transmits control information, HD information, etc. in addition to the positive and negative DC power transmission lines.
- Connection of information transmission lines is indispensable.
- signal transmission lines other than the two line connections that basically transmit the necessary DC power so three or more connection terminals are required to connect the battery pack to the connection device.
- electromagnetic interference EMI: Electro Magnetic Interference
- electrostatic breakdown are more likely to occur.
- connection terminal There is a risk of being affected by the loss of work and stored information. Also, it is difficult to reduce the size of the connection terminal and the wiring man-hours required for the connection, which tends to increase costs.
- connection terminals it is preferable to reduce the number of connection terminals, and it is an ideal configuration to have only two connection terminals for connecting DC power transmission lines that are basically necessary.
- information transmission is performed as an electromagnetic connection or an optical connection, and the connection terminal includes a positive electrode and a negative electrode for DC power transmission.
- a configuration with only one charge / discharge terminal is known (for example, see Patent Document 1).
- Patent Document 1 Japanese Patent Laid-Open No. 05-135804
- connection terminals to be mechanically connected are only two charge / discharge terminals of the positive electrode and the negative electrode.
- the battery pack and the connection device are not connected.
- the component for electromagnetically or optically connecting the battery pack and the charging device or the load device needs to be opposed to each other with a predetermined accuracy in the vicinity of the battery pack and the charging device or the load device.
- the position of the components arranged in the battery pack and the charging device or the load device for information transmission is limited, and the arrangement space increases, which makes it difficult to apply to small devices such as portable electronic devices.
- the present invention performs transmission of information between a battery pack and a charging device or a load device using a DC power transmission line, and terminal connection is performed using two DC power transmission lines.
- a first invention of the present application is a battery pack comprising a secondary battery, and a positive electrode charging / discharging terminal and a negative electrode charging / discharging terminal connected to the positive electrode and the negative electrode, respectively.
- charging information for supplying charging power to the secondary battery by connecting the identification information read from the identification information recording means to the positive charge / discharge terminal and the negative charge / discharge terminal.
- Information signal that is modulated and transmitted to an identification signal that can be conveyed through the positive charge / discharge terminal or the negative charge / discharge terminal to a load device that is connected to the device or the positive charge / discharge terminal and the negative charge / discharge terminal and operates by the discharge power of the secondary battery Transmission means.
- the connection of the battery pack to the charging device or the load device is performed using DC power.
- identification information is transmitted from the information signal transmitting means to the charging device or the load device when the battery pack is connected to the charging device or the load device. Can be sent through.
- the charging device or load device can determine the suitability of the identification information transmitted through the power connection terminal, and can prevent the occurrence of malfunctions and malfunctions due to the connection of non-compliant battery packs. it can.
- there are only two terminal connections there is little influence of electromagnetic interference or electrostatic breakdown, damage and malfunction can be prevented, and downsizing and cost reduction can be achieved by simplifying the connection structure.
- the second invention of the present application relates to a secondary battery, a positive electrode charge / discharge terminal and a negative electrode charge / discharge terminal connected to the positive electrode and the negative electrode, respectively, and a battery operating state for detecting an operating state of the secondary battery.
- the battery pack comprising the detecting means, charging is performed to connect the operating state detection information detected by the battery operating state detecting means to the positive electrode charging / discharging terminal and the negative electrode charging / discharging terminal to supply charging power to the secondary battery.
- the device is connected to the positive charge / discharge terminal and the negative charge / discharge terminal, and is modulated and transmitted to an operation state detection signal that can be conveyed through the positive charge / discharge terminal or the negative charge / discharge terminal to a load device that operates by the discharge power of the secondary battery.
- Information signal transmission means is provided.
- the connection of the battery pack to the charging device or the load device is only the connection between the two power connection terminals of the positive electrode and the negative electrode serving as a DC power transmission line, and the battery pack is connected to the charging device or
- the operation state detection information can be transmitted from the information signal transmitting means to the charging device or the load device through the power connection terminal.
- the operating state detection information power transmitted through the power connection terminal can also determine the operating state of the battery pack, and it is possible to detect a malfunction such as an abnormality and respond quickly.
- there are only two terminal connections it is possible to prevent damage and malfunctions that are less affected by electromagnetic interference and electrostatic breakdown, and it is possible to reduce the size and cost by simplifying the connection structure. .
- the third invention of the present application relates to a secondary battery, a positive electrode charging / discharging terminal and a negative electrode charging / discharging terminal connected to the positive electrode and the negative electrode, respectively, and a battery operating state for detecting an operating state of the secondary battery.
- Identification information in which identification information is recorded in a battery pack provided with detection means The recording means and the identification information read from the identification information recording means or the operation state detection information detected by the operation state detection means are connected to the positive charge / discharge terminal and the negative charge / discharge terminal to charge the secondary battery.
- a charging device or a load device that operates with the discharge power of the secondary battery by connecting to the charging device or the positive electrode charging / discharging terminal and the negative electrode charging / discharging terminal, And an information signal transmitting means for transmitting.
- the connection of the battery pack to the charging device or the load device is only the connection between the two power connection terminals of the positive electrode and the negative electrode serving as a DC power transmission line, and the information signal transmission unit to the charging device
- identification information and operation state detection information can be transmitted to the load device through the power connection terminal.
- the charging device or load device can determine the suitability of the identification information transmitted through the power connection terminal and prevent malfunctions and malfunctions due to the connection of non-conforming battery nodes. Therefore, it is possible to determine the operation state of the battery pack from the operation state detection information, and it is possible to detect a malfunction such as occurrence of an abnormality and respond quickly. Also, since there are only two terminal connections, there is little influence of electromagnetic interference or electrostatic breakdown, and damage or malfunction can be prevented.
- the fourth invention of the present application relates to a secondary battery, a positive electrode charging / discharging terminal and a negative electrode charging / discharging terminal connected to the positive electrode and the negative electrode, respectively, and a battery operating state for detecting an operating state of the secondary battery.
- An identification information recording means for recording identification information and a question signal conveyed from the charging device or the load device through the positive electrode charging / discharging terminal or the negative electrode charging / discharging terminal on the battery pack provided with the detecting means.
- Information signal receiving means for demodulating and retrieving question information, identification information read from the identification information recording means in response to a request described in the question information, or operation state detection information detected by the operation state detection means Connected to the positive charge / discharge terminal and negative charge / discharge terminal to supply charge power to the secondary battery, or connected to the positive charge / discharge terminal and negative charge / discharge terminal to operate with the discharge power of the secondary battery And an information signal transmitting means for modulating and transmitting the information signal that can be conveyed through the positive charge / discharge terminal or the negative charge / discharge terminal.
- the connection of the battery pack to the charging device or the load device is a direct current power. Only the connection between the two power connection terminals of the positive and negative electrodes serving as a transmission line, and the identification information corresponding to the request from the information signal transmission means or the request from the charging device or the load device received by the information signal reception means or Operating state detection information can be transmitted through the power connection terminal.
- the charging device or load device can also determine the suitability of the discriminating information transmitted through the power connection terminal, and it is possible to prevent malfunctions and malfunctions caused by the connection of non-conforming battery packs.
- the operating state detection information ability can also determine the operating state of the battery pack, and it is possible to detect problems such as the occurrence of abnormalities and respond quickly. In addition, since there are only two terminal connections, it is possible to prevent damage and malfunctions that are less affected by electromagnetic interference and electrostatic breakdown.
- the battery pack charging device or the load device in each of the above configurations is only the connection between the two connection terminals of the positive electrode and the negative electrode, the battery pack is connected to the charging device or the load device. If the electrical connection can be easily and miniaturized, it will be less susceptible to the effects of static electricity damage due to less electromagnetic interference through the information transmission line.
- the information signal transmitting means in each battery pack is a DC power transmission line as an identification signal or an operation state detection signal obtained by modulating a carrier wave of a predetermined frequency by a predetermined modulation method based on the identification information or the operation state detection information. It is possible to transmit information through a DC power transmission line and to connect the battery pack and the charging device or load device with two terminal connections. Become.
- the information signal transmitting means intermittently charges / discharges the current by configuring pulse current to modulate the charge current flowing through the positive charge / discharge terminal or the negative charge / discharge terminal based on the identification information or the operation state detection information.
- Information signals can be superimposed on the DC power transmission line by pulse modulation. Therefore, it is possible to transmit information through the DC power transmission line, and the connection between the battery knock and the charging device or the load device can be made with two terminal connections.
- the fifth invention of the present application provides a battery pack comprising a secondary battery and a positive electrode charging / discharging terminal and a negative electrode charging / discharging terminal respectively connected to the positive electrode and the negative electrode thereof.
- a charging device connected to the negative electrode charging / discharging terminal to supply charging power to the secondary battery, or
- the battery pack includes identification information recording means that records identification information.
- And information signal transmitting means for modulating and transmitting the identification information read from the identification information recording means into an identification signal that can be conveyed to the charging device or load device through the positive charge / discharge terminal or the negative charge / discharge terminal,
- the charging device or the load device demodulates the information signal received by the information signal receiving means for demodulating the information signal conveyed through the positive electrode charging / discharging terminal or the negative electrode charging / discharging terminal and reading the identification information.
- Power supply control means for controlling the charging power output of the charging device or the discharging power input to the load device.
- the connection between the battery pack and the charging device or the load device is only the connection between the two power connection terminals of the positive electrode and the negative electrode that are the DC power transmission line, and the battery pack is protected.
- identification information can be transmitted from the information signal transmitting means to the charging device or the load device through the power connection terminal.
- the charging device or the load device can extract the identification information by demodulating the identification signal transmitted through the power connection terminal by the information signal receiving means.
- the charging device or the load device can also determine the suitability of the battery pack with its discriminatory information ability, and it is possible to prevent the occurrence of malfunctions and malfunctions due to the connection of non-conforming battery packs.
- since there are only two terminal connections it is possible to prevent damages and malfunctions that are less affected by electromagnetic interference and electrostatic breakdown, and it is possible to reduce the size and cost by simplifying the connection structure. Monkey.
- the sixth invention of the present application relates to a secondary battery, a positive electrode charge / discharge terminal and a negative electrode charge / discharge terminal connected to the positive electrode and the negative electrode, respectively, and a battery operating state for detecting an operating state of the secondary battery.
- a battery pack comprising detection means is connected to the positive electrode charging / discharging terminal and the negative electrode charging / discharging terminal and connected to a charging device or positive electrode charging / discharging terminal and negative electrode charging / discharging terminal for supplying charging power to the secondary battery.
- the battery pack uses the battery operating state detection means to detect the operating state detection information as the positive electrode charging / discharging terminal or the negative electrode charging / discharging terminal.
- An information signal transmitting means that modulates and transmits an operation state detection signal that can be conveyed through the electric terminal, and the charging device or the load device receives the information signal conveyed through the positive charge / discharge terminal or the negative charge / discharge terminal.
- Information signal receiving means for demodulating and reading out the operating state detection information, and power supply control means for controlling the charging power output of the charging device or the discharging power input to the load device based on the read out operating state detection information. It is provided.
- the connection between the battery pack and the charging device or the load device is only the connection between the two power connection terminals of the positive electrode and the negative electrode serving as the DC power transmission line, and the information signal transmission means
- the battery pack operating state detection information can be transmitted to the charging device or the load device through the power connection terminal.
- the charging device or load device can detect the operating status of the battery pack that has been transmitted through the power connection terminal, and can detect the malfunction of the battery pack and respond quickly. .
- the effects of electromagnetic interference and electrostatic breakdown can be reduced, and damage and malfunctions can be prevented. Miniaturization and cost reduction can be achieved by simplifying the connection structure.
- the seventh invention of the present application relates to a secondary battery, a positive electrode charge / discharge terminal and a negative electrode charge / discharge terminal connected to the positive electrode and the negative electrode, respectively, and a battery operating state for detecting an operating state of the secondary battery.
- a battery pack comprising detection means is connected to the positive electrode charging / discharging terminal and the negative electrode charging / discharging terminal and connected to a charging device or positive electrode charging / discharging terminal and negative electrode charging / discharging terminal for supplying charging power to the secondary battery.
- the battery pack includes identification information recording means that records identification information, and identification information read from the identification information recording means or the The operation state detection information detected by the battery operation state detection means is modulated into an information signal that can be conveyed to the charging device or the load device through the positive charge / discharge terminal or the negative charge / discharge terminal.
- An information signal transmitting means wherein the charging device or the load device demodulates the information signal conveyed through the positive charge / discharge terminal or the negative charge / discharge terminal and reads the identification information or the operation state detection information.
- the connection between the battery pack and the charging device or the load device is only the connection between the two power connection terminals of the positive electrode and the negative electrode serving as a DC power transmission line, and the information signal transmission means
- Identification information and operation state detection information can be transmitted from the power connection terminal to the charging device or the load device.
- the charging device or load device can determine the suitability of identification information transmitted through the power connection terminal, and can prevent the occurrence of malfunctions and malfunctions due to the connection of non-compliant battery packs.
- the operation state of the battery pack can be determined from the operation state detection information, and it is possible to detect a malfunction such as the occurrence of an abnormality and respond quickly. Also, since there are only two terminal connections, there is little effect of electromagnetic interference or electrostatic breakdown, and damage or malfunction can be prevented.
- the eighth invention of the present application relates to a secondary battery, a positive electrode charge / discharge terminal and a negative electrode charge / discharge terminal connected to the positive electrode and the negative electrode, respectively, and a battery operating state for detecting an operating state of the secondary battery.
- a battery pack comprising detection means is connected to the positive electrode charging / discharging terminal and the negative electrode charging / discharging terminal and connected to a charging device or positive electrode charging / discharging terminal and negative electrode charging / discharging terminal for supplying charging power to the secondary battery.
- the battery pack includes identification information recording means for recording identification information, and the positive charge / discharge terminal from the charging device or load device.
- an information signal receiving means for demodulating the question signal transmitted through the negative electrode charging / discharging terminal to extract the question information, and reading from the identification information recording means in response to the request described in the question information.
- Information signal transmission means for modulating the output identification information or the operation state detection information detected by the battery operation state detection means and transmitting it as a response signal through the positive charge / discharge terminal or negative charge / discharge terminal;
- the device or the load device modulates the question information to the connected battery pack and transmits it as a question signal that can be conveyed through the positive charge / discharge terminal or the negative charge / discharge terminal, and a positive charge / discharge terminal.
- an information signal receiving means for demodulating the response signal conveyed from the battery pack through the negative electrode charging / discharging terminal and reading the identification information or the operation state detection information, and decoding the read identification information or operation state detection information.
- Charging device power output or load Power supply control means for controlling discharge power input to the apparatus is provided.
- the connection between the battery pack and the charging device or the load device is only a connection between the two power connection terminals of the positive electrode and the negative electrode that are the DC power transmission line, and the connected battery pack is connected to the battery pack. Then, the charging device or the load device can transmit a necessary request from the information signal transmission means to the battery pack as an inquiry signal.
- the question signal is demodulated by the information signal receiving means in the battery pack that has received the question signal. The identification information is transmitted from the information signal transmitting means to the charging device or the load device through the power connection terminal in response to the request for the query information.
- the charging device or the load device can demodulate the identification signal transmitted through the power connection terminal by the information signal receiving means and take out the identification information, the charging device or the load device has the identification information power of the battery pack. Compatibility can be determined, and malfunctions and malfunctions caused by connection of non-compliant battery packs can be prevented.
- the identification of the battery pack is an identification process through two-way communication, so that the identification level can be enhanced.
- the charging device or the load device can transmit a request regarding the operating state of the battery pack to the battery pack as an information signal transmission means inquiry signal as necessary.
- the interrogation signal is demodulated by the information signal receiving means to extract the interrogation information, and the operation state detection information detected by the battery operation state detection means from the information signal transmission means in response to the request for the interrogation information. Is transmitted to the charging device or the load device through the power connection terminal. Since the charging device or the load device can demodulate the operation state detection signal transmitted through the power connection terminal by the information signal receiving means to extract the operation state detection information, the charging device or the load device also has the operation state detection information power. It is possible to know the operating state of the battery pack and to perform control corresponding to the operating state of the battery pack.
- the charging device or the load device can obtain necessary operation state information as required.
- the connection for two-way communication is only the two terminal connection of the DC power transmission line, it is possible to prevent damage and malfunction that are less affected by electromagnetic interference and electrostatic breakdown, and simplify the connection structure. Downsizing and cost reduction can be achieved by the downsizing.
- the information signal transmitting means in each of the connection systems described above is a DC power as an identification signal, an operation state detection signal, or an inquiry signal obtained by modulating a carrier wave of a predetermined frequency by a predetermined modulation method based on the identification information or operation state detection information or inquiry information.
- a DC power as an identification signal, an operation state detection signal, or an inquiry signal obtained by modulating a carrier wave of a predetermined frequency by a predetermined modulation method based on the identification information or operation state detection information or inquiry information.
- the information signal transmission means is configured to pulse-modulate the charge / discharge current flowing through the DC power transmission line based on the identification information, the operation state detection information, or the query information, thereby performing pulse modulation of the charge / discharge current.
- the information signal can be superimposed on the DC power transmission line. Therefore, it is possible to transmit information through the DC power transmission line, and the connection between the battery pack and the charging device or the load device can be performed with two terminal connections.
- the information signal receiving means in each connection system demodulates the identification signal or the operation state detection signal or the interrogation signal carried through the DC power transmission line by a predetermined demodulation method to identify the identification information or the operation state detection information. Or, it is possible to transmit information through a DC power transmission line by taking out the information as question information, and the connection between the battery pack and the charging device or the load device can be made with two terminal connections.
- the information signal receiving means is configured as a pulse demodulation that takes out the current change of the pulse-modulated charge / discharge current flowing through the DC power transmission line, so that the pulse modulation of the charge / discharge current is applied to the DC power transmission line.
- An information signal can be superimposed. Therefore, it is possible to transmit information through the DC power transmission line, and the connection between the battery pack and the charging device or the load device can be made with two terminal connections.
- FIG. 1 is a block diagram showing a configuration of a battery pack and its connection system according to a first embodiment.
- FIG. 2 is a block diagram showing a configuration when the above connection system is applied to a personal computer.
- FIG. 3 shows a configuration example of signal transmission using the DC power transmission line according to the second embodiment.
- FIG. 4A to FIG. 4B are block diagrams showing modified examples of the same configuration as above.
- FIG. 5A is a graph showing a change in information transmission for pulse width modulation of charge / discharge current in the case of a charging device
- FIG. 5B is a load of a change in information transmission for pulse width modulation of charge / discharge current. It is a graph shown in the case of an apparatus.
- FIG. 6 is a block diagram showing a configuration of a battery pack and its connection system according to a third embodiment.
- FIG. 7 is a block diagram showing a configuration of a conventional battery pack applied to a mobile phone.
- FIG. 8 is a block diagram showing a conventional battery pack having an identification function and its connection system.
- FIG. 1 shows a battery pack connection system including a battery pack 1 according to a first embodiment of the present invention, and a charging device 20 and a load device 30 connected thereto.
- the charging device 20 When the battery pack 1 charges the secondary battery 2, the charging device 20 is connected by connecting the positive charge / discharge terminal 11 to the positive charge terminal 21 of the charging device 20 and the negative charge / discharge terminal 12 to the negative charge terminal 22.
- the secondary battery 2 is charged by the charging power supplied from.
- the load device 30 that operates by the discharge power from the battery node 1
- the positive charge / discharge terminal 11 is connected to the positive discharge terminal 31 of the load device 30 and the negative charge / discharge terminal 12 is connected to the negative discharge terminal 32 of the load device 30.
- the load device 30 By connecting, the load device 30 is operated by the discharge power from the secondary battery 2.
- the battery pack 1 includes a battery protection circuit, and includes temperature detection means 7 for detecting battery temperature, voltage detection means 8 for detecting battery voltage, and current detection means 9 for detecting charge / discharge current.
- the control means 3 to which the operation state detection information from the battery operation state detection means 10 is input detects the overdischarge state, the overcharge state, and the overcurrent state of the secondary battery 2 from the operation state detection information. When detected, the charge / discharge circuit is blocked by the protection element (FET) 6. To protect the secondary battery 2. Further, the battery pack 1 is provided with an identification function for specifying the charging device 20 and the load device 30 to which the battery pack 1 corresponds.
- the identification function includes an identification information recording means 4 that stores identification information for identifying a model, and a modulation that modulates the identification information read from the identification information recording means 4 into an identification signal that can be transmitted by being superimposed on a direct current power transmission line. Circuit (information signal transmission means) 5 and function.
- the control means 3 to which the identification information is input from the identification information recording means 4 inputs the identification information to the modulation circuit 5 as necessary. Since the modulation circuit 5 superimposes the identification signal modulated with the identification information by the modulation method described later on the DC power transmission line, the identification signal is sent to the charging device 20 or the load device 30 through the DC power transmission line.
- the identification information recording means 4 is a memory for storing an ID number, it is simply a resistor having a specific resistance value, or a memory for storing a specific signal or encryption signal in a simple manner. However, an optimal configuration can be implemented according to the level of identification accuracy and decoding accuracy.
- the positive electrode charging / discharging terminal 11 is connected to the positive charging terminal 21 of the charging device 20, and the negative charging / discharging terminal 12 is connected to the negative charging terminal of the charging device 20.
- a DC power transmission line through which the charging current from the charging device 20 flows to the battery pack 1 is formed.
- the control means 3 reads the identification information from the identification information recording means 4 and inputs it to the modulation circuit 5. Therefore, the modulation circuit 5 positively charges an identification signal obtained by modulating the identification information by the modulation method described later with the identification information. The data is transmitted to the charging device 20 through the discharge terminal 11 and the positive electrode charging terminal 21.
- the charging device 20 extracts and identifies the charging power source 23 connected to the positive electrode charging terminal 21 and the negative electrode charging terminal 22, and the identification signal connected to the positive electrode charging terminal 21 and transmitted through the DC power transmission line.
- Demodulator circuit for demodulating information (information signal receiving means) 24 and demodulation circuit The power supply control means 25 is configured to determine whether the identification information output from the path 24 is correct or not, and to control the output of the charging power supply 23 by the power supply management means 26.
- the demodulating circuit 24 demodulates the transmitted identification signal, extracts the identification information, and inputs it to the power supply control means 25.
- the power supply control means 25 determines whether or not the transmitted identification information is correct.
- the power management means 26 permits the output of the charging power from the charging power supply 23, so the battery pack 1 Is supplied with charging power. On the other hand, if the identification information is correct, the power management means 26 does not allow the output from the charging power supply 23 under the control of the power control means 25, so the battery pack 1 is determined to be incompatible and charging is not started. . Therefore, charging is not performed when a battery charger 1 that is incompatible with the battery pack 1 is connected, and a failure due to connection of an inappropriate battery charger is prevented.
- the positive electrode charge / discharge terminal 11 is connected to the positive electrode discharge terminal 31 of the load device, and the negative electrode charge / discharge terminal 12 is connected to the negative electrode discharge terminal of the load device 30.
- a DC power transmission line is formed in which the discharge current from battery pack 1 flows to load device 30.
- the control means 3 reads the identification information from the identification information recording means 4 and inputs it to the modulation circuit 5. Therefore, the modulation circuit 5 uses the positive charge / discharge terminal 11 and the positive discharge terminal 31 as identification signals obtained by modulating the identification information.
- the load device 30 is configured in the same manner as the charging device 20 in the processing of the identification information.
- the load device 30 is connected to the positive electrode discharge terminal 31 and the negative electrode discharge terminal 32, and is connected to the positive electrode discharge terminal 31 to transmit DC power.
- a demodulating circuit (information signal receiving means) 34 that extracts the identification signal transmitted through the line and demodulates it into identification information, and supplies the power to the load 33 by judging whether the identification information output from the demodulating circuit 34 is correct or not
- Power supply control means 35 for controlling the power supply, and power supply management means 36 for managing the power supply to the load 33.
- the demodulating circuit 34 demodulates the transmitted identification signal, extracts the identification information, and inputs it to the power control means 35.
- the power control means 35 determines whether or not the transmitted identification information is correct. If the identification information is correct, the power control means 35 outputs a power supply permission signal to the power management means 36, and the power management means 36 supplies the load 33. Allow discharge power supply Thus, the load device 30 operates when the discharge power from the battery pack 1 is supplied to the load 33. If the identification information is correct, the power control means 35 does not output a power supply permission signal to the power management means 36, so the connected battery pack 1 is determined to be non-conforming and the load 33 must be operated. I can't. Therefore, when a battery power supply that is incompatible with the load device 30 is connected, the load device 30 does not operate, and the occurrence of failure or malfunction due to connection of the battery power supply that is incompatible is prevented.
- the charging device 20 and the load device 30 are separated from each other. Think of the charging device 20 and the load device 30 as one body.
- Fig. 2 shows an example of the power circuit configuration of the notebook computer 40.
- the AC adapter 43 can be used for charging the battery pack 1 or an AC power source as an accessory device of the notebook computer 40. It is a DC power supply source in use. Therefore, the configuration for receiving the identification information provided in each of the charging device 20 and the load device 30 can be shared by the demodulation circuit (information signal receiving means) 44, the power control means 45, and the power management means 46.
- the power management means 46 is an existing configuration for switching control between battery power and AC power in the notebook computer 40.
- the battery pack 1 is connected to the laptop computer 40 by connecting the positive electrode charge / discharge terminal 11 to the positive power source terminal 41 of the laptop computer 40 and the negative electrode charge / discharge terminal 12 to the negative power source terminal 42. Since the identification signal is transmitted from the modulation circuit 5 to the notebook computer 40 through the positive charge / discharge terminal 11 and the positive power supply terminal 41, the notebook computer 40 demodulates the identification signal by the demodulation circuit 44 and identifies the identification information. Is taken out and input to the power control means 45. The power control means 45 determines whether the identification information is correct and outputs a connection permission signal to the power management means 46 when the identification information is correct, so that the power management means 46 permits the battery pack 1 to be connected.
- the battery pack 1 can be charged / discharged, and when a counterfeit or the like with incorrect identification information is connected, charging / discharging is not performed and it does not fit! Occurrence of failure or malfunction due to battery pack 1 is prevented.
- the example of the battery pack of the cellular phone shown in FIG. As an example of the background art of the present invention, the example of the battery pack of the cellular phone shown in FIG.
- the connection between the battery pack 100 and the charging device requires the connection of the temperature detection terminal 108 for detecting the battery temperature in addition to the DC power transmission line of the positive terminal 106 and the negative terminal 107. At least 3 terminals are connected.
- the connection terminals When information is transmitted via a communication bus as in the smart battery system in the notebook personal computer 40, it is necessary to connect at least four terminals. Such an increase in the number of connection terminals is not preferable because it is easily affected by electromagnetic interference and electrostatic breakdown as described above, and increases costs.
- information can be transmitted only by connecting the connection terminals of the positive and negative DC power transmission lines. Further, the information on the battery operating state that is obtained only by transmitting the identification information described above can be transmitted to the charging device 20 or the load device 30 by only two connections of the positive and negative charge / discharge terminals 11 and 12.
- the control information 3 provided in the battery pack 1 is input with the detection information of the battery temperature, the battery voltage, and the charge / discharge current from the battery operating state detection means 10, so that the control is performed.
- the operation information detection information can be output from the control means 3 to the modulation circuit 5.
- the modulation circuit 5 to which the operation state detection information is input modulates the operation state detection information into an operation state detection signal that can be superimposed on the direct current power transmission line by a modulation method described later, and carries the DC power transmission line to detect the operation state.
- a signal can be transmitted to the charging device 20 or the load device 30.
- the operating state detection signal power demodulating circuit 24 that has been transmitted along the DC power transmission line is extracted by the charging circuit 20, and the operating state detection information necessary for the charging control is extracted.
- the charging power controlled by the charging voltage and the charging current corresponding to the operating state of the secondary battery 2 can be supplied to the battery pack 1.
- the control means 3 of the battery pack 1 monitors the charging state and the discharging state, when information indicating the occurrence of an overcharged state or an abnormal phenomenon is transmitted from the battery pack to the charging device 20, the charging device 20 Control to stop charging can be performed.
- the load device 30 when the load device 30 is a notebook computer, when operating with the discharged power of the battery pack 1, it is necessary to save the work data before the secondary battery 2 runs out of battery to prevent data destruction.
- the control means 3 monitors the discharge state, When the information indicating that the remaining capacity is low or the occurrence of an abnormal phenomenon is transmitted from the battery pack to the load device 30, the load device 30 can issue a warning signal display notification, and the user can quickly save the data. Can be performed.
- the configuration for transmitting the operation state detection information from the battery pack 1 to the charging device 20 and the load device 30 is realized by the above-described smart battery system or the like, but with the battery pack 1 by connecting at least four terminals. It is necessary to connect to the charging device 20 or the load device 30. As described above, in the configuration of the present embodiment, it is possible to execute charging or discharging control by only connecting two terminals of a DC power transmission line which is basically indispensable.
- ASK modulation Amplitude Shift Keying
- the modulation circuit 5 and the demodulation circuits 24 and 34 in the configuration of the embodiment use FSK modulation (Frequency Shift Keying).
- the modulation circuit 5 performs FSK modulation on the carrier waves of two frequencies based on the digital information (identification information or operation state detection information) output from the control unit 3 and sends it to the DC power transmission line as an identification signal or operation state detection signal. To do.
- the DC power transmission line force identification signal or the operation state detection signal is received by the demodulation circuits 24 and 34, respectively. It can be demodulated into digital information of identification information or operation state detection information by taking it out, separating it into two transport waves, and combining them after detection.
- the frequency of the carrier wave is an audible frequency.
- FIG. 3 shows a configuration of a second embodiment for transmitting information by pulse-modulating a direct current flowing through a DC power transmission line according to identification information or operation state detection information. It is. Since this method of information transmission interrupts the direct current flowing through the direct current power transmission line, the battery pack 50 can be connected to both the charging device and the load device as desired to be the charging device 60 as shown in the figure. In this case, the pulse modulation method described later can be applied. In addition, the same code
- the control means 3 to which the identification information is input from the identification information recording means 4 the battery pack 50 is connected to the charging device. Since the identification information is output to the modulation circuit (information signal transmission means) 51 when connected to 60, the modulation circuit 51 converts the identification information into the gate of the switching element 52 connected in series with the positive DC circuit according to the identification information. Apply the corresponding pulse signal and perform pulse modulation to interrupt the charging current.
- the positive electrode charging / discharging terminal 11 and the negative electrode charging / discharging terminal 12 are connected to the positive electrode charging terminal 21 and the negative electrode charging terminal 22, respectively, and the charging power source 23 of the charging device 60 is connected to the battery pack 50. Since charging current flows! /, The charging current is intermittent due to pulse modulation.
- a pulse-modulated current flows through a current detection element (for example, a resistor) 61 connected in series with the negative DC circuit of the charging device 60, the charging current detected by the current detection element 61 is detected from the ONZOFF state.
- the demodulating circuit (information signal receiving means) 62 can extract the pulse-modulated identification information. Since the identification information extracted by the demodulation circuit 62 is input to the power control means 25, the power control means 25 determines whether the identification information is correct. If the identification information is incorrect, the power management means 26 Stop supplying charging power from 23.
- the charging current is pulse-modulated with the charging current flowing from the charging device 60 to the battery pack 50. Therefore, if a non-conforming battery pack that is not compatible with the charging device 60 is connected, the non-conforming Since the battery pack may be damaged, a recognition current with a reduced voltage and current is passed until the identification information of the connected battery pack 50 is recognized, and the identification information is determined to be correct. It may be desirable to supply normal charging power.
- the control means 3 When transmitting the operation state detection information of the secondary battery 2 from the battery pack 50, the control means 3 samples the battery temperature, battery voltage, and battery current information from the battery operating state detection means 10, and when this operating state detection information is input to the modulation circuit 51, the modulation circuit 51 detects the operation state. Since the control signal pulse-modulated by information is applied to the gate of the switching element 52, the charging current is pulse-modulated. Since the pulse-modulated charging current can be detected as a pulse signal by the current detection element 61 in the charging device 60, the operating state detection information power controls the charging power supplied to the battery pack 50 as in the case of the identification information. Can do.
- the switching element 52 is used to interrupt the charging current.
- the protection element 6 connected in series with the switching element 52 is also a switching element (FET), like the battery pack 50a shown in FIG. 4A, If the control signal output from the modulation circuit 51 is input to the gate of the protection element 6 via the control means 3, the switching element 52 is eliminated and the information signal transmission to the load device is performed by pulse width modulation. be able to.
- the protection element 6 includes two FETs, a discharge FET 6a that is a power MOS FET for discharge control and a charge FET 6b that is a power MOSFET for charge control. Since the discharge FET 6a and the charge FET 6b are normally controlled to be in a conductive state by the control means 3, the secondary battery 2 can be charged and discharged, and when the control means 3 detects an overcharge state Charging Stops charging by controlling FET6b to shut off. Further, when the control means 3 detects an overdischarge state, the discharge FET 6a is controlled to be cut off and the discharge is stopped.
- the control means 3 receives the identification information from the identification information recording means 4 Is input to the modulation circuit 51.
- the modulation circuit 51 performs a pulse width modulation corresponding to the identification information and inputs it to the gate of the charging FET 6b via the control means 3.
- the charge FET 6b in which the pulse width modulation signal corresponding to this identification information is input to the gate is in a cut-off state and a conductive state between the source and the drain.
- the charge current flowing through the signal is pulse-width modulated with a digital signal corresponding to the identification information.
- the identification information obtained by pulse-width-modulating the charging current can be detected by the current detection element 61 provided in the charging device 60 shown in FIG.
- the electronic device 60 can read the identification information.
- the information signal is transmitted by pulse width modulation, the charging current is interrupted and the charging efficiency is reduced.
- the information signal is transmitted in a short time, and the identification information is transmitted in particular. Because it is a short time at the start of charging, it has little effect on the overall charging time.
- the battery pack 50a is connected to a load device (illustration is omitted, components for information transmission can be configured in the same manner as the charging device 60, and will be described with the same component names and symbols).
- the control means 3 reads the identification information from the identification information recording means 4 and inputs it to the modulation circuit 51.
- the modulation circuit 51 performs pulse width modulation corresponding to the identification information and inputs it to the gate of the discharge FET 6a via the control means 3.
- the source-drain is cut off and conductive, but the parasitic diode p exists between the source and drain.
- the discharge current is not completely interrupted, and the voltage changes according to the pulse width modulation, so the discharge current flowing from the secondary battery 2 to the load device is pulsed with a digital signal corresponding to the identification information. Width modulated. Since the identification information in which the discharge current is pulse-width modulated can be detected by the current detection element 61 provided in the load device, the identification information can be read in the load device. Since the change in the discharge voltage due to the pulse width modulation is small, the voltage drop for operating the load device does not hinder the operation.
- the battery pack 1, 50, 50a to the charging device
- 60 or load device 30 is a unidirectional transmission of information signals, but the battery pack 1, 50, 5 Oa
- information receiving means can be provided so that information can be transmitted in both directions, and information can be transmitted on demand.
- a battery pack connection system provided with this bidirectional information transmission means will be described below.
- FIG. 6 shows a battery pack connection system according to a third embodiment.
- a means for transmitting and receiving information is also provided on the side of the charging device 80 or the load device 90 that is only 70. Note that the same reference numerals are used for components common to the configurations of the first and second embodiments. The description is omitted.
- the battery pack 70 is provided with a demodulation circuit (information signal receiving means) 71 in addition to the modulation circuit 5, and the charging device 80 and the load device 90 have a demodulation circuit (information signal reception). Means) In addition to 24 and 34, modulation circuits (information signal transmission means) 81 and 91 are provided.
- the power control means 82 of the charging device 80 inputs question information such as a personal identification number to the modulation circuit 81.
- the modulation circuit 81 converts the carrier wave of a predetermined frequency into an inquiry signal modulated by a predetermined modulation method, conveys it on the DC power transmission line from the positive electrode charging terminal 21, and transmits it to the battery pack 70.
- the question information transmitted to the positive electrode charge / discharge terminal 11 is demodulated by the demodulator circuit 71, and the question information demodulated by the demodulator circuit 71 is input to the control means 73.
- the control means 73 reads the identification information from the identification information recording means 4 and inputs it to the modulation circuit 5, so that the modulation circuit 5 is identified. Based on the information, a carrier wave of a predetermined frequency is converted into a response signal modulated by a predetermined modulation method, conveyed from the positive electrode charging / discharging terminal 11 on the DC power transmission line, and returned to the charging device 80.
- the charging device 80 inputs the identification information extracted by demodulating the transmitted response signal by the demodulation circuit 24 to the power supply control means 82.
- the power supply control means 82 judges whether the identification information is correct or not.
- the power management means 26 performs control to supply the charging power from the charging power source 23 to the battery pack 70. If the identification information is not correct, the power management means 82 The control which does not supply charging power by means 26 is executed. In the control procedure in which the charging device 80 identifies the battery pack 70, the battery pack 70 executes a procedure of responding to the question from the charging device 80. Therefore, the identification level is improved and the identification information is copied. Effective for recognizing counterfeit products.
- the control means 73 sends the battery temperature information input from the temperature detection means 7 to the modulation circuit 5. input.
- the modulation circuit 5 converts the carrier wave of a predetermined frequency according to the battery temperature information into a response signal modulated by a predetermined modulation method, conveys it on the DC power transmission line from the positive electrode charging / discharging terminal 11, and returns it to the charging device 80.
- Charging device 80 demodulates transmitted response signal Since the battery temperature information demodulated and extracted by the circuit 24 is input to the power supply control means 82, the charging power output from the charging power supply 23 can be controlled to a voltage or current corresponding to the battery temperature.
- the power supply control means 82 of the load device 90 inputs question information such as a password to the modulation circuit 91 as in the case of the charging device 80.
- the modulation circuit 91 converts the predetermined carrier wave into the inquiry signal modulated by the predetermined modulation method according to the required inquiry information, conveys it on the DC power transmission line from the positive electrode discharge terminal 31, and transmits it to the battery pack 70.
- the inquiry information demodulated by the demodulation circuit 71 is input to the control means 73, so that the control means 73 executes a predetermined response according to the contents of the inquiry information.
- the control means 73 reads the identification information from the identification information recording means 4 and inputs it to the modulation circuit 5, so that the modulation circuit 5 Based on the information, a carrier wave having a predetermined frequency is converted into a response signal modulated by a predetermined modulation method, and is conveyed on the DC power transmission line from the positive electrode charging / discharging terminal 11 and returned to the load device 90.
- the load device 90 demodulates the transmitted response signal by the demodulation circuit 34 and inputs the identification information taken out to the power control means 92.
- the power supply control means 92 judges whether the identification information is correct. If the identification information is correct, the power management means 36 permits the battery pack 70 to be connected. In the control procedure in which the load device 90 identifies the battery pack 70, since the battery pack 70 executes a procedure for responding to the question from the load device 90, higher-level identification can be performed. This is effective for recognizing counterfeit products that copy information.
- the control means 73 inputs the calculated remaining capacity of the secondary battery 2 to the modulation circuit 5 as the remaining capacity information.
- the modulation circuit 5 converts the carrier wave of a predetermined frequency into a response signal modulated by a predetermined modulation method, conveys it on the DC power transmission line from the positive electrode charging / discharging terminal 11, and returns it to the load device 90. Since the load device 90 inputs the remaining capacity information obtained by demodulating the response signal transmitted by the demodulator circuit 34 to the power supply control means 92, if the load device 90 is the notebook computer 40, the remaining capacity Information is being transmitted. When the laptop computer 40 arrives, a warning operation is executed to display the decrease in the remaining battery capacity on the display or sound display to prompt the user to save the data or switch to AC power. .
- a carrier wave modulated by information is conveyed and transmitted on the DC power transmission line, but the charging current is pulse-modulated by digital information. It can also be configured to transmit information.
- information is transmitted by pulse-modulating current with digital information, information is transmitted bi-directionally between the battery pack and the charging device or load device in the same way as when the predetermined carrier wave is communicated by the predetermined modulation method. It can be performed.
- the switching means 52 is modulated by the modulation circuit 51 from the control means 3 and the change in current is transmitted to the current detection element 61 in the charging device 60 for demodulation.
- Information is transmitted through circuit 62.
- the power control means 25 can control the charging power supply 23 indirectly by controlling the power management means 26.
- the power control means 25 in the charging device 60 transmits information to the battery pack 50 as a change in current to the power management means 26.
- the battery pack 50 detects this change in current by the internal current detection means 9 and transmits information to the control means 3.
- the battery pack 50 and the charging device 60 can transmit information in both directions.
- FIG. 3 only the charging device 60 is described as a partner that performs bidirectional information communication with the battery pack 50, but the same is true even if the partner is a load device.
- the discharge FET for suppressing the discharge from the battery pack is not subjected to pulse modulation, but the charge is suppressed. It is desirable to modulate the charge FET for. If the width of the pulse modulation is high, short, or pulse with sufficient frequency without being interrupted by the smoothing capacitor built in the load device, it is possible to prevent the load device from causing malfunction. Industrial applicability confirmed
- the connection to the charging device or the load device is basically made up of two positive and negative electrodes through which a necessary charging current or discharging current flows. It is only connected at the terminal, and identification information for identifying a compatible battery pack and battery operating state information such as battery temperature necessary for charging control are superimposed on the DC power transmission line through the two terminals.
- the information transmission path for transmission is formed, so it is possible to transmit information while using only two terminals for DC power transmission, simplifying the terminal configuration that is less susceptible to electromagnetic interference and electrostatic breakdown. It is suitable for miniaturization and high performance of portable electronic devices such as mobile phones and notebook computers by reducing the size and cost of battery packs, charging devices and load devices.
- the connection between the battery pack and the charging device or the load device is basically connected to the DC power transmission line at each of the necessary positive and negative terminals. Therefore, it is possible to carry out information transmission such as identification of the type of battery pack to be connected and the operating state of the battery pack through the DC power transmission line, so there are only two terminals for DC power transmission. Information transmission is also possible, and it is suitable for reducing the size and cost of battery packs, charging devices, and load devices by simplifying the terminal configuration that is not easily affected by electromagnetic interference or electrostatic breakdown. By transmitting information bi-directionally, it is possible to transmit necessary information at any time by making necessary requests at necessary times. And functions are suitable to configured imitation battery pack to prevent the occurrence of a failure or accident when it is connected to the charging device or the loading device by using a inadequate battery protection circuit.
Abstract
Description
Claims
Priority Applications (2)
Application Number | Priority Date | Filing Date | Title |
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EP06731566A EP1892791A1 (en) | 2005-04-22 | 2006-04-11 | Cell pack and its connection system |
US11/918,920 US8148939B2 (en) | 2005-04-22 | 2006-04-11 | Battery pack using a secondary battery and connection system for connecting the battery pack to a charging device or a loading device |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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JP2005-124628 | 2005-04-22 | ||
JP2005124628A JP2006302733A (ja) | 2005-04-22 | 2005-04-22 | 電池パック及びその接続システム |
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WO2006115037A1 true WO2006115037A1 (ja) | 2006-11-02 |
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PCT/JP2006/307619 WO2006115037A1 (ja) | 2005-04-22 | 2006-04-11 | 電池パック及びその接続システム |
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US (1) | US8148939B2 (ja) |
EP (1) | EP1892791A1 (ja) |
JP (1) | JP2006302733A (ja) |
KR (1) | KR20070122464A (ja) |
CN (1) | CN100544112C (ja) |
WO (1) | WO2006115037A1 (ja) |
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Also Published As
Publication number | Publication date |
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US8148939B2 (en) | 2012-04-03 |
US20090039833A1 (en) | 2009-02-12 |
KR20070122464A (ko) | 2007-12-31 |
CN101164192A (zh) | 2008-04-16 |
EP1892791A1 (en) | 2008-02-27 |
JP2006302733A (ja) | 2006-11-02 |
CN100544112C (zh) | 2009-09-23 |
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