JP3820846B2 - Charging method, secondary battery unit and charger - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for charging a secondary battery.
[0002]
[Prior art]
In recent years, the use and number of portable electronic devices such as mobile phones, notebook personal computers, cameras, and videos have exploded.
Furthermore, recently, a standard called Bluetooth has been proposed, and it is expected that wireless communication in a personal area of 10 m or less will be further enhanced. In this case, each device on the reception side and the transmission side (including the case of bidirectional communication) functions as an electronic device.
[0003]
Each of these electronic devices requires a power source for driving. At present, the most commonly used power source is a battery. In recent years, the demand for a secondary battery that can be reused by charging is increasing.
As the use of portable electronic devices as described above, especially in the personal area, becomes more demanding, the demand for secondary batteries is expected to increase further.
[0004]
[Problems to be solved by the invention]
Increasing demand for and use of secondary battery-equipped devices (hereinafter sometimes referred to as “battery-using devices”) and secondary batteries, including portable applications, will inevitably result in charging of secondary batteries. The demand for chargers to do so will increase.
However, on the other hand, using different chargers for each battery using device, in other words, for each secondary battery, not only requires a lot of space, but also needs to be charged with the charger. It also takes time to make the secondary battery correspond. In particular, in portable battery-operated devices, since they are carried when going out, it is necessary to charge them together at home for a limited time. In this case, different chargers are used for each device. It is even more difficult to use.
[0005]
Therefore, the present inventors have studied to use a common charger for a plurality of types of secondary batteries corresponding to a plurality of types of battery using devices. Accordingly, it is possible to charge different types of secondary batteries using the same charger, and it is possible to save a lot of trouble of charging. The common charger is technically easy in principle by sharing the specifications of the connection part with the battery-using device or the secondary battery charger.
[0006]
However, on the other hand, when a common charger is used, it is necessary to change the charging method for each secondary battery. In other words, no matter how much the specifications of the connection part are shared, the secondary battery itself has different characteristics depending on the battery-using device, so the voltage at full charge, the charge rate (rate), constant current charge and constant current charge are constant. Appropriate charging is impossible without changing the voltage charging or changing the timing charging pattern.
[0007]
Currently, what is called a smart battery, which has a memory element and a microprocessor inside, has been proposed. If the above specifications are made common so that a common charger can be used using this smart battery, it is possible to charge appropriately for each battery. However, since a smart battery requires an element such as a microprocessor for each battery, it is not only disadvantageous for reducing the size and weight of the battery, but also increases the cost of the entire charging system.
[0008]
[Means for Solving the Problems]
In view of the above problems, the present invention employs the following configuration.
(1) A charging method for charging a plurality of types of secondary batteries having different charging patterns using a common charger,
In each of the secondary batteries, a charging parameter for identifying a charging pattern at the time of charging is stored, and a parameter storage unit electrically separated from the secondary battery is provided,
The charger for the secondary battery, have rows charged by a predetermined charging pattern according to said charging parameter,
A charging method characterized in that, during charging , a deterioration parameter indicating a degree of deterioration of the secondary battery is obtained by measuring a time required for charging in the constant voltage mode, and stored in the parameter storage unit .
(2) A charging method for charging a plurality of types of secondary batteries having different charging patterns using a common charger,
Each of the secondary batteries includes a parameter storage unit that stores a charging parameter for identifying a charging pattern at the time of charging,
The charger, the calculation function provided therein, have rows charged by a predetermined charging pattern according to said charging parameter,
A charging method characterized in that, during charging , a deterioration parameter indicating a degree of deterioration of the secondary battery is obtained by measuring a time required for charging in the constant voltage mode, and stored in the parameter storage unit .
(3) A charging method for charging a plurality of types of secondary batteries having different charging patterns, each used for a portable device, using a common charger,
Each of the secondary batteries includes a parameter storage unit that stores a charging parameter for identifying a charging pattern at the time of charging,
The charger for the secondary battery, have rows charged by a predetermined charging pattern according to said charging parameter,
A charging method characterized in that, during charging , a deterioration parameter indicating a degree of deterioration of the secondary battery is obtained by measuring a time required for charging in the constant voltage mode, and stored in the parameter storage unit .
(4) The charging method according to any one of (1) to (3), wherein the charging parameter includes a parameter indicating a charging pattern.
(5) The charging method according to any one of (1) to (3), wherein the charging parameter includes a type identification parameter given to each secondary battery having a different charging pattern.
(6) The charging method according to (5), wherein the charger stores the type identification parameter of the secondary battery and a charging pattern for the type identification parameter in association with each other.
(7) and the secondary battery, stores charge parameters for identifying the charging pattern during charging, and possess a secondary battery and electrically separated parameter storage unit,
The parameter storage unit further stores a deterioration parameter indicating the degree of deterioration of the secondary battery,
The deterioration parameter measures the time required for charging in the constant voltage mode at the time of charging, reads the discharge time from a predetermined voltage to another lower predetermined voltage, or reads the voltage value after discharging for a certain time from the predetermined voltage A secondary battery unit characterized by being obtained by any of the above .
(8) and the secondary battery, and a parameter storage unit that stores a charging parameter to identify the charge pattern during charging possess,
The parameter storage unit further stores a deterioration parameter indicating the degree of deterioration of the secondary battery,
The deterioration parameter measures the time required for charging in the constant voltage mode at the time of charging, reads the discharge time from a predetermined voltage to another lower predetermined voltage, or reads the voltage value after discharging for a certain time from the predetermined voltage A secondary battery unit for portable equipment, characterized in that it is obtained by any of the above .
( 9 ) The secondary battery unit according to ( 7 ) or ( 8 ), wherein the charging parameter includes a parameter indicating a charging pattern.
( 10 ) The secondary battery unit according to ( 7 ) or ( 8 ), wherein the charging parameter includes a type identification parameter given to each secondary battery having a different charging pattern.
( 11 ) In a battery charger for a secondary battery, including a power supply circuit, a charge control circuit, and a microprocessor that controls driving of the power supply circuit and the charge control circuit .
The microprocessor
Based on the charging parameters provided to the secondary battery to be charged, it has a calculation function for generating a predetermined charge pattern as a control signal to be sent to the charging control circuit,
A charger having a calculation function for obtaining a deterioration parameter indicating a degree of deterioration of the secondary battery by measuring a time required for charging in the constant voltage mode during charging.
( 12 ) The charger according to ( 11 ), wherein the charging parameter includes a parameter indicating a charging pattern.
( 13 ) The charger includes the type identification parameter given to each secondary battery having a different charge pattern. ( 14 ) The charger according to ( 11 ), wherein the microprocessor includes the type identification parameter of the secondary battery and the type identification parameter. The charger according to ( 13 ), which stores a charging pattern corresponding to the type identification parameter in association with each other.
[0009]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the drawings.
FIG. 1 is a block diagram collectively showing the configurations of a charger and a secondary battery in the first aspect of the present invention.
The charger 101 includes a power supply circuit 102, a charge control circuit 103, a microprocessor 104, and a regulator 105. The power supply circuit 102 is a circuit that outputs direct current by rectifying and smoothing input from a general household AC power supply. The charging control circuit 103 charges the lithium secondary battery 205 connected to the charging terminal 106 based on the output of the power supply circuit 102. The regulator 105 supplies an operating voltage to the microprocessor 105 based on an input from a general household AC power source.
[0010]
The microprocessor 104 provided in the charger 101 includes a RAM, a ROM, a timer, an A / D converter, and the like. The microprocessor 104 outputs an operation signal to the power supply circuit 102 to drive the power supply circuit 102 and outputs a control signal constituting a charge pattern to the charge control circuit 103 to control charging. At this time, the microprocessor 104 inputs a data signal DATA such as a charging parameter from the memory element 204 and uses it for charging control. That is, the microprocessor 104 has a calculation function for generating a predetermined charging pattern as a control signal to be sent to the charging control circuit based on the charging parameter stored in the memory element 204. At this time, if necessary, a signal from the charging control circuit 103 and a temperature signal T from the thermistor 203 described later may be input and used for charging control. The temperature signal T is input to the microprocessor 104 through the thermistor terminal 107, and the charging parameter signal DATA is input to the microprocessor 104 through the data terminal 108. The microprocessor 104 further supplies an operating voltage Vcc to a memory element 204, which will be described later, via a memory element power supply terminal 109, and supplies a clock signal CLK to the memory element 204 via a clock terminal 110. The data signal DATA to be stored in the memory element 204 is supplied via the data terminal 108.
[0011]
The microprocessor 104 also stores an algorithm for measuring the time required for charging in the constant voltage mode with a timer during charging.
The secondary battery unit 201 includes a lithium secondary battery 205, a protection circuit 202, a thermistor 203, and a memory element 204 as a parameter storage unit. Examples of the secondary battery unit 201 include those used for various portable devices such as a mobile phone, a notebook personal computer, a camera, a video, a headphone stereo, a PDA, a game machine, a wireless mouse, and a radio. The weight of the portable device is usually 10 kg or less, preferably 5 kg or less, more preferably 0.1 kg or more, while it is usually 0.001 kg or more, preferably 0.01 kg or more, more preferably 0.1 kg or more. . If the weight is too large, it is inconvenient to carry and too small is not practical. In FIG. 1, the secondary battery unit 201 is not shown integrally with the battery using device, but the secondary battery unit may be separated from the battery using device for charging and used for charging. It may be used for charging while remaining integrated. Therefore, when the secondary battery unit and the battery using device are integrated and charged, the components other than the lithium secondary battery 205 of the secondary battery unit 201 can also serve as components in the battery using device. .
[0012]
The lithium secondary battery 205 is a battery using lithium as an electromotive material. For example, a positive electrode and coke using a lithium transition metal oxide such as lithium cobalt oxide as a positive electrode active material and a carbonaceous material such as graphite are used as a negative electrode active material. And a non-aqueous electrolyte solution. In the present invention, there are a plurality of types of lithium secondary batteries used in the charger 101, and various types of characteristics such as capacity, rate characteristics, cycle characteristics, and durability are different. The lithium secondary battery 205 is charged via the charging terminal 206.
[0013]
The protection circuit 202 is a circuit that stops or lowers the battery function during overcharge, overdischarge, or overcurrent, and is disposed in parallel with the lithium secondary battery 205. The thermistor 203 is used for monitoring the temperature of the secondary battery unit. The temperature signal T obtained from the thermistor 203 is read from the thermistor terminal 207.
[0014]
A memory element 204 as a parameter storage unit is a memory such as an EEPROM or an SRAM, and stores a charging parameter for identifying a predetermined charging pattern suitable for the secondary battery unit 201. Here, as the parameters indicating the charge pattern, the voltage at full charge, the speed (rate) of charge, whether or not to switch between constant current charge and constant voltage charge, charge completion current value, initial charge current value, overdischarge A voltage value, an overcharge voltage value, and the like are stored. The memory element 204 is electrically separated from the lithium secondary battery. That is, the operating voltage of the memory element 204 is not supplied from the lithium secondary battery 205 but is supplied from the charger 101 via the memory element power supply terminal 208. Further, the clock signal of the memory element 204 is supplied from the microprocessor 104 via the clock terminal 209. Further, the memory element 204 supplies a data signal such as a charging parameter stored in the memory to the microprocessor 104 via the data terminal 210, and inputs a data signal such as a degradation parameter described later from the microprocessor 104. To do.
[0015]
Although the secondary battery unit 201 includes the memory element 204, it does not necessarily include a microprocessor inside the so-called smart battery. Therefore, all the arithmetic processing of the data recorded in the memory element is performed on the charger 101 side.
Next, a charging method for each secondary battery will be described.
[0016]
When the charger 101 to the battery unit 201 is disposed in a chargeable state, the microprocessor 1 04 first reads the temperature signal T from the thermistor 203, that the temperature is within a predetermined range Check. If it is not within the predetermined temperature range, the charging operation is not performed. Next, the microprocessor 204 reads from the memory element 204 of the secondary battery unit 201 a charge pattern when the secondary battery unit is charged. According to the read charge pattern, the microprocessor 204 outputs a control signal to the charge control circuit 103 and also outputs an operation signal to the power supply circuit 102 to start / continue / end the charging operation. Normally, charging is performed first in the constant voltage mode, and then charging is performed in the constant current mode. At this time, the charging operation is controlled with reference to a signal from the charging control circuit 103 and a temperature signal T from the thermistor 203 as necessary. Since the control signal to the charging control circuit is in accordance with the charging pattern stored in the memory element 204, appropriate charging can be performed according to the type of the secondary battery unit.
[0017]
As described above, the microprocessor 104 stores an algorithm for measuring the time required for charging in the constant voltage mode using a timer. Generally, the required time becomes longer as the deterioration of the battery proceeds. Therefore, the degree of deterioration of the lithium secondary battery 205 at that time can be understood from the required time. Therefore, at the time of charging, the microprocessor 104 calculates a deterioration parameter D indicating the degree of battery deterioration from the required time, and stores this in the memory element 204 of the secondary battery unit 201. At this time, if the deterioration parameter D ′ stored in the memory device 204 in the same manner at the previous charging exists, the deterioration parameter D ′ is rewritten to the newly updated deterioration parameter D. In this way, the microprocessor is provided with a calculation function for obtaining a deterioration parameter indicating the degree of deterioration of the secondary battery, and the battery deterioration parameter obtained by calculation at the time of charging is stored in the memory element 204. Thus, when the secondary battery unit is used in the battery-powered device, the accurate remaining amount can be displayed. In other words, the battery-operated device normally obtains the battery capacity from the battery voltage and displays the remaining capacity, but the relationship between the battery voltage and the capacity (voltage / capacity curve) changes depending on the degree of battery deterioration. The remaining amount display must contain large errors or low accuracy. On the other hand, by reading the deterioration parameter D from the memory element as described above, the conversion from the battery voltage to the battery capacity can be corrected according to the degree of deterioration, and the remaining amount display becomes more accurate. The deterioration parameter can be written in the memory element 204 by making a slight modification to the charging algorithm, and it is almost unnecessary to add new hardware, so that the present invention is particularly effective.
In this case, the relationship between the voltage and the capacity when there is no deterioration is preferably stored in the memory element 204 in the form of a comparison table or a function from the viewpoint of more accurate remaining amount display. More preferably, the above relationship is stored for each battery temperature and / or for each rate at the time of use, so that the above relationship is more appropriately referred to when the battery is used, and a more accurate remaining amount display is made possible.
[0018]
Next, a charging operation as a whole including attachment / detachment of the secondary battery to / from the charger will be described.
First, with respect to the charger 101, the first secondary battery unit 201 is arranged in a state where a charging operation can be performed (first arrangement step). Next, as described above, the charging parameter is read from the memory element 204 to the microprocessor 104 for the arranged secondary battery unit 201 (first parameter reading step), and based on the read charging parameter. Then, the first secondary battery unit 201 is charged with a predetermined charging pattern (first charging step). After the end of charging, the arranged first secondary battery is removed from the charger (first end step). With the above operation, all the charging operations for the first secondary battery unit 201 are completed.
[0019]
Since the charger 101 is a charger that is common to a plurality of types of secondary batteries, the battery that is subsequently charged after the completion of all the charging operations for the first secondary battery unit is the first secondary battery unit. May be a different type of second secondary battery unit (in this case, the function is the same as that of the first secondary battery unit, and thus is represented by the same reference numeral 201).
[0020]
When the second secondary battery unit 201 is arranged in a state in which the charger 101 can be charged (second arrangement step), the following operation is performed to read the charging parameters as in the case of the first secondary battery unit. , Charging, and removal of the secondary battery unit are performed (second parameter reading step, second charging step, and second end step).
Furthermore, although the above steps are repeated continuously or intermittently, charging for each secondary battery unit is performed according to the charging parameters associated with each secondary battery unit, so for each secondary battery unit Appropriate charging is possible.
[0021]
The charging method, secondary battery unit, and charger of the present invention are not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the invention.
For example, in the first mode, the secondary battery unit 201 is provided with an EEPROM or SRAM as the memory element 204 that stores the charging pattern itself and the deterioration parameter of the battery. As the storage unit, a serial number communication circuit 304 can be used as shown in FIG. 2 instead of the memory element. In FIG. 2, what is indicated by the reference numerals in FIG. 1 is the same as that in the first embodiment.
[0022]
The serial number communication circuit 304 includes a binary code string that forms a different serial number for each individual battery and a control circuit. The serial number has a type identification parameter given to each secondary battery having a different charge pattern. include. In this case, the charging pattern itself is not stored in the memory element. However, for example, a plurality of types of charging patterns and a plurality of type identification parameters are stored in advance in the microprocessor 104 in the charger 101. I am letting. Therefore, as in the case of the first aspect, when the microprocessor 104 reads the serial number including the type identification parameter stored in the serial number communication circuit, the charging pattern and type stored in the memory element in the microprocessor are read. A predetermined charging pattern can be read from the correspondence with the identification parameter.
[0023]
In the second aspect, the secondary battery unit 201 does not require even a relatively expensive EEPROM or SRAM, and can further reduce the number of terminals for communication, further reducing the size and weight of the battery and reducing the cost. Is possible. Moreover, on the other hand, it is not necessary to add new hardware on the charger side.
In the first aspect, the charger has only one set of charging terminals corresponding to DC + and GND, but may of course have a plurality of sets. In this case, various batteries can be set in the charger 101 at the same time for charging.
[0024]
Furthermore, in the first aspect, a lithium secondary battery is exemplified as the type of battery, but various secondary batteries such as a nickel metal hydride battery can be used. Rather, in the present invention, not only a plurality of types of secondary batteries based on the same electrochemical reaction, but also the use of secondary batteries based on different electrochemical reactions such as lithium ion batteries and nickel metal hydride batteries are completely problematic. Can be recharged.
[0025]
Furthermore, in the first aspect, as a method for obtaining the deterioration parameter, a method of reading the charging time in the constant voltage mode has been described, but in addition, for example, the discharging time from a predetermined voltage to another lower predetermined voltage. And a method of reading a voltage value after discharging for a certain time from a predetermined voltage.
[0026]
【The invention's effect】
According to invention of Claim 1, 2, 3, 7 , 8, and 11 , a common charger is used for a plurality of types of secondary batteries having different charging patterns, and each of the secondary batteries In addition, since the charging parameters for identifying the charging pattern at the time of charging are stored, it is possible to appropriately charge each secondary battery. In particular, in the inventions according to claims 1 and 7 , since the charging parameter is provided in a parameter storage unit that is electrically separated from the secondary battery, the power of the secondary battery is not consumed. Further, in the inventions according to claims 2 and 11 , since the calculation function provided in the charger is used in applying the charging parameter to the actual charging, only the charging parameter is necessary on the secondary battery side, The secondary battery can be reduced in size and weight. Furthermore, according to the invention described in claims 3 and 8 , since the secondary battery to be charged is used in a portable device, there is a need to use a common charger for a plurality of types of secondary batteries. It is particularly high, and therefore the effect of the present invention is particularly remarkable.
[0027]
According to the fourth, ninth, and twelfth aspects of the present invention, since the charging parameter includes a parameter indicating a charging pattern, appropriate charging can be easily performed by reading and calculating the parameter as it is.
According to the invention described in claims 5 and 6, claim 10 and claims 13 and 14 , the charging parameter includes a type identification parameter given for each secondary battery having a different charging pattern. If the type identification parameter and the charging parameter are stored in association with each other, appropriate charging can be easily performed. In addition, since the type identification parameter can be stored and communicated with a very simple device, the cost can be reduced by reducing the size and weight of the battery and reducing the number of terminals.
[0028]
According to the present invention, at the time of charging, a deterioration parameter indicating the degree of deterioration of the secondary battery is obtained, and this is stored in the parameter storage unit, so that the degree of deterioration can be grasped and more accurate when the secondary battery is used. A high remaining amount can be displayed.
[Brief description of the drawings]
FIG. 1 is a block diagram collectively showing configurations of a charger and a secondary battery in a first aspect of the present invention.
FIG. 2 is a block diagram collectively showing respective configurations of a charger and a secondary battery in the second mode of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 101 Charger 102 Power supply circuit 103 Charge control circuit 104 Microprocessor 201 Secondary battery unit 202 Protection circuit 203 Thermistor 204 Memory element 205 Lithium secondary battery 304 Serial number communication circuit

Claims (14)

A charging method for charging a plurality of types of secondary batteries with different charging patterns using a common charger,
In each of the secondary batteries, a charging parameter for identifying a charging pattern at the time of charging is stored, and a parameter storage unit electrically separated from the secondary battery is provided,
The charger for the secondary battery, have rows charged by a predetermined charging pattern according to said charging parameter,
A charging method characterized in that, during charging , a deterioration parameter indicating a degree of deterioration of the secondary battery is obtained by measuring a time required for charging in the constant voltage mode, and stored in the parameter storage unit . A charging method for charging a plurality of types of secondary batteries with different charging patterns using a common charger,
Each of the secondary batteries includes a parameter storage unit that stores a charging parameter for identifying a charging pattern at the time of charging,
The charger, the calculation function provided therein, have rows charged by a predetermined charging pattern according to said charging parameter,
A charging method characterized in that, during charging , a deterioration parameter indicating a degree of deterioration of the secondary battery is obtained by measuring a time required for charging in the constant voltage mode, and stored in the parameter storage unit . A charging method that uses a common charger to charge a plurality of types of secondary batteries with different charging patterns, each used for a portable device,
Each of the secondary batteries includes a parameter storage unit that stores a charging parameter for identifying a charging pattern at the time of charging,
The charger for the secondary battery, have rows charged by a predetermined charging pattern according to said charging parameter,
A charging method characterized in that, during charging , a deterioration parameter indicating a degree of deterioration of the secondary battery is obtained by measuring a time required for charging in the constant voltage mode, and stored in the parameter storage unit .   The charging method according to claim 1, wherein the charging parameter includes a parameter indicating a charging pattern.   The charging method according to claim 1, wherein the charging parameter includes a type identification parameter given for each secondary battery having a different charging pattern.   The charging method according to claim 5, wherein the charger stores the type identification parameter of the secondary battery and a charging pattern corresponding to the type identification parameter in association with each other. A secondary battery storing charging parameters for identifying the charging pattern during charging, and possess a secondary battery and electrically separated parameter storage unit,
The parameter storage unit further stores a deterioration parameter indicating the degree of deterioration of the secondary battery,
The deterioration parameter measures the time required for charging in the constant voltage mode at the time of charging, reads the discharge time from a predetermined voltage to another lower predetermined voltage, or reads the voltage value after discharging for a certain time from the predetermined voltage A secondary battery unit characterized by being obtained by any of the above . A secondary battery, and a parameter storage unit that stores a charging parameter to identify the charge pattern during charging possess,
The parameter storage unit further stores a deterioration parameter indicating the degree of deterioration of the secondary battery,
The deterioration parameter measures the time required for charging in the constant voltage mode at the time of charging, reads the discharge time from a predetermined voltage to another lower predetermined voltage, or reads the voltage value after discharging for a certain time from the predetermined voltage A secondary battery unit for portable equipment, characterized in that it is obtained by any of the above . The secondary battery unit according to claim 7 or 8 , wherein the charging parameter includes a parameter indicating a charging pattern. The secondary battery unit according to claim 7 or 8 , wherein the charge parameter includes a type identification parameter given to each secondary battery having a different charge pattern. In a secondary battery charger having a power supply circuit, a charge control circuit, and a microprocessor that controls driving of the power supply circuit and the charge control circuit ,
The microprocessor
Based on the charging parameters provided to the secondary battery to be charged, it has a calculation function for generating a predetermined charge pattern as a control signal to be sent to the charging control circuit,
A charger having a calculation function for obtaining a deterioration parameter indicating a degree of deterioration of the secondary battery by measuring a time required for charging in the constant voltage mode during charging. The charger according to claim 11 , wherein the charging parameter includes a parameter indicating a charging pattern. The charger according to claim 11 , wherein the charging parameter includes a type identification parameter given to each secondary battery having a different charging pattern. The charger according to claim 13 , wherein the microprocessor stores the type identification parameter of the secondary battery and a charging pattern corresponding to the type identification parameter in association with each other.

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