JP2004071243A - Battery pack - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a battery pack capable of detecting residual power of cells without consuming the power thereof. <P>SOLUTION: The battery pack is equipped with a wireless tag having a coil generating electricity by the electromagnetic wave from the outside, and the power generated at the wireless tag is supplied to an EEPROM in which, the residual power is recorded, by the above, the residual power is read by the EEPROM and transmitted to the outside. <P>COPYRIGHT: (C)2004,JPO

Description

【００５０】
表１は、電池セルの電力残量を算出するためのテーブルである。
【００５１】
表１の最上段には、充電回数の範囲が示されており、表１の左端には、電池セルの放電電圧が示されている。
【００５２】
ここで、例えば、充電回数が５０回目であって、電池セルの放電電圧が３．４Ｖであるとすると、表１に表されるところの、最上段が「１００回まで」、すなわち左から２列目で、かつ左端が「３・４Ｖ」、すなわち下から３段目のところに示されている「３０」により、電力残量が３０％であることが算出される。この電池パック１では、充電回数が何回目であれ、電池セルの放電電圧が３．２Ｖ未満になると、実際には電力残量はゼロになっていなくても電力残量は「０」とされる。
【００５３】
また、表１からは、充電回数によって電池容量は減少するものの、充電回数によって検出可能な電池セルの電圧は変化していない様子が読み取れる。
【００５４】
図６は、電池セルの放電電圧と放電時間との関係を表すグラフ図である。
【００５５】
図６には、充電回数ごとの、電池セルの放電電圧と放電時間との関係が示されているが、充電回数が増加しても最高放電電圧は同じである。ただし、充電回数が進むごとに放電電圧の下がり方は早くなっている。
【００５６】
図７は、電池パックにおける電力残量の算出動作のフローチャートである。
【００５７】
図７には、電池パック１の電圧検出回路１０２において検出された電圧値が制御部１０５に送信されてくると起動されるルーチンが示されている。
【００５８】
ステップＳ１１では、ＥＥＰＲＯＭ１０６からの充電回数の読み出しが行なわれ、ステップＳ１２では、電圧検出回路１０２から送信された電圧値と、読み出した充電回数を基に、ＥＥＰＲＯＭ１０６に記憶されている電池残量算出テーブルから電池残量を算出する。その後、ステップＳ１３では、送信された電圧値と、算出された電池残量とのＥＥＰＲＯＭ１０６への書き込みが行なわれ、このルーチンを終了する。
【００５９】
このように電力残量がＥＥＰＲＯＭ１０６に書き込まれた後、電池パック１に備えられている無線タグによる電量残量の読み出しが行われる。
【００６０】
無線タグ１０７は、前述したようにＥＥＰＲＯＭ１０６に電力を供給してＥＥＰＲＯＭ１０６を起動させ、ＥＥＰＲＯＭ１０６に記録されている電池残量と充電回数とを読み出す。が、このとき、同じくＥＥＰＲＯＭ１０６に記録されている充電回数も読み出す。無線タグ１０７は、読み出した充電回数が５００以上であると、この電池パックの電池寿命が尽きていることを表す電池寿命フラグをアサートする。
【００６１】
また、この無線タグ１０７は、電圧検出回路１０２にも電力を供給しており、この電圧検出回路１０２をこの電力で起動させ、この電圧検出回路で検出された電圧を読み出す。無線タグ１０７では、この読み出した電圧が２．０Ｖ未満であると、電池セルがセルショートを起こしていることをあらわすセルショートフラグのアサートを行う。無線タグは、セルショートフラグがアサートされていなければ、電力残量および充電回数を、充電回数が５００回以上であるときには電池寿命が尽きていることを表す情報も一緒に外部に送信する。一方、セルショートフラグがアサートされているときは、電池セルがセルショートを起こしていることを表す情報を、電力残量および充電回数の代わりに外部に送信する。
【００６２】
したがって、この電池パック１では、外部からの電磁波の送信に対し、電池セルがセルショートを起こしていないときは、最新の電力残量および充電回数、場合によっては電池寿命が尽きていることを表す情報も外部に送信され、電池セルがセルショートを起こしている時は、そのことを表す情報のみが外部に送信される。この外部への情報の送信には、前述したように、電池セルに蓄えられている電力は一切使用されていない。
【００６３】
図８は、電池パックの無線タグが動作するときに起動されるルーチンのフローチャートである。
【００６４】
図８には、無線タグ１０７に電磁波が送信されてきたときに起動されるルーチンが示されており、ステップＳ２１では、無線タグからＥＥＰＲＯＭ１０６に供給された電力により、ＥＥＰＲＯＭ１０６が起動され、無線タグによる充電回数および電力残量の読み出しが行なわれる。その後、ステップＳ２２に進む。
【００６５】
ステップＳ２２では、無線タグ１０７から電圧検出回路１０２に供給された電力により、電圧検出回路１０２では電池セルの電圧が検出され、その検出された電圧の無線タグによる読み出しが行なわれる。その後、ステップＳ２３に進み、電圧検出回路１０２で検出された電圧が、２．０Ｖ未満、すなわち電池セルがセルショートを起こしているか否かが判定される。
【００６６】
ステップＳ２３において、セルショートが発生していると判定されると、ステップＳ２８に進み、無線タグに備えられたセルショートフラグのアサートが行なわれ、その後、ステップＳ２９において、電池セルにセルショートが発生していることを表す情報が外部に送信され、このルーチンを終了する。
【００６７】
一方、ステップＳ２３において、セルショートが発生していないと判定されると、ステップＳ２４に進み、すでに読み込んだ充電回数が５００以上であるか否かが判定される。
【００６８】
ステップＳ２４において、充電回数が５００回以上であると判定されると、ステップＳ２５に進み、無線タグに備えられている電池寿命フラグがアサートされる。その後、ステップＳ２６に進み、電力残量、充電回数、電池寿命が尽きていることとを表わす情報が外部に送信され、このルーチンを終了する。
【００６９】
一方、ステップＳ２４において、充電回数が５００回以上ではないと判定されると、ステップＳ２７に進み、電力残量および充電回数が外部に送信され、このルーチンを終了する。
【００７０】
以上説明した、本実施形態の電池パック１では、自分自身の電力を消費することなく、外部に対し、電力残量および充電回数を送信することができ、その充電回数が電池寿命が尽きていることを表す５００以上である場合には、そのことを表す情報も外部に送信する。さらに、この電池パック１では、電池セルがセルショートを起こした場合には、そのことを表す情報が、上記電池残量および充電回数などに代わり外部に送信される。
【００７１】
尚、本実施形態では、無線タグが電圧検出回路に電力を供給し、電圧検出回路で検出された電圧によって、電池セルがセルショートを起こしたか否かを判定し、セルショート起こしている場合にはそのことを表す情報を外部に送信する例を挙げて説明したが、無線タグが、電圧検出回路で検出された電圧と、充電回数を外部に送信するものであってもよい。また、本実施形態では、無線タグがＥＥＰＲＯＭにのみ電力を供給し、ＥＥＰＲＯＭに記録されている電力残量および充電回数のみを外部に送信するものであってもよく、さらには、ＥＥＰＲＯＭには、充電回数をカウントするカウンタ領域が設けられておらず、無線タグが電力残量のみを外部に送信するものであってもよい。
【００７２】
【発明の効果】
以上説明したように、本発明の電池パックによれば、電池セルの電力残量を電池セルの電力を消費せずに知ることができる。
【図面の簡単な説明】
【図１】本発明の、第１の電池パックと第２の電池パックの共通の実施形態の外観斜視図である。
【図２】本実施形態の内部ブロック図である。
【図３】本実施形態の電池パックの電力系統図である。
【図４】電池容量と充電回数の関係を示す図である。
【図５】本発明の電池パックが、充電器に嵌め込まれることにより起動するルーチンである。
【図６】電池セルの放電電圧と放電時間との関係を表すグラフ図である。
【図７】電池パックにおける電力残量の算出動作のフローチャートである。
【図８】電池パックの無線タグが動作するときに起動されるルーチンのフローチャートである。
【符号の説明】
１　電池パック
１１　プラス端子
１２　マイナス端子
１０１　電池セル
１０２　電圧検出回路
１０３　放電スイッチ
１０４　充電スイッチ
１０５　制御部
１０６　ＥＥＰＲＯＭ
１０７　無線タグ
１０７ａ　コイル[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a rechargeable battery pack.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a battery pack is known in which an internal battery cell is charged by being supplied with electric power from the outside, and the electric power charged in the battery cell is supplied to the outside.
[0003]
Japanese Patent Application Laid-Open No. 11-233159 proposes a battery pack that emits light from a light-emitting body provided in itself to represent the remaining power.
[0004]
In the proposed battery pack, as a means for indicating the remaining electric power, the light emitter is turned on or blinked in a predetermined pattern corresponding to the remaining electric power, and the battery cell is charged with electric power for performing these operations. Powered by electricity.
[0005]
[Problems to be solved by the invention]
In other words, the proposed battery pack has a problem that the remaining amount of power is reduced to display the remaining amount of power.
[0006]
An object of this invention is to provide the battery pack which can know the electric power residual amount of a battery cell, without consuming the electric power of a battery cell in view of the said situation.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, the first battery pack of the present invention comprises:
In the battery pack that is charged by receiving power from the outside to the internal battery cell and supplies the power charged to the battery cell to the outside,
A charge counter that counts the number of times the battery cell is charged;
A voltage monitor for detecting the voltage of the battery cell;
A remaining amount calculating unit that calculates the remaining amount of power remaining in the battery cell based on the number of times of charging counted by the charging number counter and the voltage of the battery cell detected by the voltage monitor;
A memory unit that stores the remaining amount of electric power remaining in the battery cell, calculated by the remaining amount calculation unit;
The coil has a coil that receives power supplied by electromagnetic induction from the outside and transmits information to the outside, and uses the power supplied via the coil to access the memory unit to store the remaining amount in the coil. And a wireless tag for wireless transmission via the wireless communication device.
[0008]
In the first battery pack of the present invention, a wireless tag that operates with power generated by electromagnetic induction from the outside supplies the power to the memory unit, and the remaining amount of power read from the memory unit activated by the power is output to the outside. Is transmitted by the wireless tag. Thereby, according to the 1st battery pack of this invention, the electric power residual amount of a battery cell can be known, without consuming the electric power of a battery cell.
[0009]
In order to achieve the above object, the second battery pack of the present invention comprises:
In the battery pack that is charged by receiving power from the outside to the internal battery cell and supplies the power charged to the battery cell to the outside,
A charge counter that counts the number of times the battery cell is charged;
A voltage monitor for detecting the voltage of the battery cell;
A memory unit that stores the number of times of charging counted by the number of times of charging counter and the voltage detected by the voltage monitor;
The coil has a coil for receiving power supplied by electromagnetic induction from the outside and transmits information to the outside, and uses the power supplied via the coil to access the memory unit and the voltage of the battery cell. And a wireless tag that wirelessly transmits the number of times of charging through the coil.
[0010]
In the second battery pack of the present invention, the voltage of the battery cell and the number of times of charging the battery cell necessary for calculating the remaining battery capacity are stored in the memory unit, and the electric power generated by electromagnetic induction is used. The operating wireless tag supplies its power to the memory unit, and the voltage of these battery cells and the number of times of charging the battery cell read from the memory unit activated by this power are wirelessly transmitted to the outside by this wireless tag. . Thereby, the remaining battery level can be calculated based on the voltage of these battery cells transmitted to the outside by the second battery pack of the present invention and the number of times of charging the battery cells. Therefore, according to the second battery pack of the present invention, the remaining power of the battery cell can be known without consuming the power of the battery cell.
[0011]
Here, the wireless tag of the first battery pack of the present invention supplies power to the voltage monitor in addition to the memory unit, and reads the voltage detected by the voltage monitor,
When the read voltage is less than a predetermined threshold, the wireless tag preferably wirelessly transmits information indicating that the battery cell has caused a cell short circuit instead of the remaining amount. .
[0012]
If it does in this way, generation | occurrence | production of the cell short of a battery cell can be known.
[0013]
In addition, the wireless tag of the second battery pack of the present invention supplies power to the voltage monitor in addition to the memory unit, and reads the voltage detected by the voltage monitor,
When the read voltage is less than a predetermined threshold, the wireless tag wirelessly transmits information indicating that the battery cell is short-circuited instead of the voltage and the number of times of charging. It is preferable.
[0014]
If it does in this way, generation | occurrence | production of the cell short of a battery cell can be known.
[0015]
Here, the memory unit of the first battery pack of the present invention stores the number of times of charging counted by the number of times of charging counter in addition to the remaining amount,
It is also a preferable aspect that the wireless tag transmits the number of times of charging in addition to the remaining amount.
[0016]
In this way, in addition to the remaining battery level, the number of times of charging the battery cell can be known without consuming the power of the battery cell, which is advantageous in determining the battery life.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the battery pack of the present invention will be described.
[0018]
FIG. 1 is an external perspective view of a common embodiment of the first battery pack and the second battery pack according to the present invention.
[0019]
FIG. 1 shows a battery pack 1 of the present embodiment, and a plus terminal 11 and a minus terminal 12 are provided in order from the left on the lower side of the battery pack shown in FIG. This battery pack 1 is a secondary battery using lithium ions.
[0020]
A protrusion 13 provided at the end of the battery pack 1 is shown in the upper part of FIG. 1, and a coil to be described later is disposed inside the protrusion.
[0021]
FIG. 2 is an internal block diagram of the present embodiment.
[0022]
In FIG. 2, the battery pack 1, the positive terminal 11, the battery cell 101 to which power is charged, the negative terminal 12 to which the negative side of the battery cell is connected, the battery cell is connected to both ends, and the voltage of the battery cell is The voltage detection circuit 102 to detect, the control part 105 which controls operation | movement of the battery pack 1 whole, and the calculation of a battery remaining charge, the discharge switch 103 and the charge switch 104 which operate | move by the instruction | indication of the control part 105, and a power remaining charge calculation A wireless memory having an EEPROM 106 that stores a reference table to be referred to and a calculated power remaining amount, and a coil 107a that generates power by external electromagnetic waves and transmits information to the outside. A tag 107 is shown.
[0023]
The discharge switch 103 and the charge switch 104 are connected in parallel between the plus terminal 11 and the plus side of the battery cell, and these switches are switched according to instructions from the control unit 105 during charging and discharging.
[0024]
When the voltage detection circuit 102 detects the voltage of the battery cell 101, the voltage detection circuit 102 transmits the detection voltage to the control unit 105.
[0025]
Each time the control unit 105 instructs the charging switch 104 to turn on, the control unit 105 increments a counter that counts the number of times of charging described later. A counter for counting the number of times of charging is provided in the EEPROM 106 described later.
[0026]
Further, the control unit 105 refers to a table for calculating the remaining battery level stored in the EEPROM 106 described later based on the voltage transmitted from the voltage detection circuit 102 and the number of times of charging stored in the counter. The remaining battery level is calculated, and the result and voltage value are written in the EEPROM 106.
[0027]
The EEPROM 106 stores the voltage value, the number of times of charging, the remaining battery level calculation table, and the remaining battery level described above.
[0028]
The wireless tag 107 operates by power generated by electromagnetic waves from the outside and supplies this power to the EEPROM 106 and the voltage detection circuit 102.
[0029]
FIG. 3 is a power system diagram of the battery pack of the present embodiment.
[0030]
As will be described later in detail, FIG. 3 shows that power can be supplied to the EEPROM 106 and the voltage detection circuit 102 by two systems of a battery cell and a wireless tag.
[0031]
In the battery pack 1, the voltage output from the wireless tag is set higher than the voltage of the fully charged battery cell.
[0032]
Further, as will be described in detail later, the wireless tag 107 has a battery life flag and a voltage for indicating that the battery life of the battery pack 1 is exhausted when the number of times of charging read from the EEPROM 106 is 500 or more. When the voltage detected by the detection circuit is less than 2.0 V, a cell short flag is provided to indicate that the battery cell has caused a cell short.
[0033]
Here, the charging operation and discharging operation of the battery pack 1 will be described with reference to FIG.
[0034]
First, when the battery pack 1 is fitted in a charger (not shown), a control signal is transmitted from the control unit 105 to the charging switch 104, and charging by the charger is performed on the battery cell.
[0035]
In this battery pack 1, the number of times of charging performed so far is counted up in accordance with an instruction to the charging switch 104, and the number of times of charging is overwritten in the counter area of the EEPROM 106 every time it is updated.
[0036]
FIG. 4 is a diagram illustrating the relationship between the battery capacity and the number of times of charging.
[0037]
The horizontal axis of FIG. 4 shows the number of times of charging, and the vertical axis of FIG. 4 shows the battery capacity.
[0038]
FIG. 4 shows the ratio of the chargeable power amount for each number of times of charging when the amount of power that can be charged to an unused battery pack is 100.
[0039]
For example, when the number of times of charging is 100, the battery capacity is reduced to about 90, and when the number of times of charging is 500, the battery capacity is reduced to about 50.
[0040]
In other words, since the battery capacity of the battery pack 1 decreases as the number of times of charging increases, when the number of times of charging reaches 500, only about half of the power can be charged compared to an unused battery pack.
[0041]
FIG. 5 is a routine that starts when the battery pack of the present invention is fitted into a charger.
[0042]
In step S1, the number of times of charging accompanying the turning on of the charging switch 103 by the control unit 105 is added. In step S2, the number of times of charging is written to the EEPROM 106 by the control unit 105. Thereafter, the process proceeds to step S3, where it is determined whether or not charging is completed based on the number of times of charging and the voltage of the battery cell. If it is determined in step S3 that charging has not been completed, step S3 is repeated. If it is determined that charging is complete, this routine is terminated.
[0043]
The battery pack 1 in which the battery cells are charged in this way is used in a portable device such as a camera or a video camera.
[0044]
When the battery pack 1 is attached to a portable device or the like, a control signal is transmitted from the control unit 105 of the battery pack 1 to the discharge switch 103, and power can be supplied to the portable device.
[0045]
In the battery pack 1, the voltage detection circuit 102 detects the voltage of the battery cell 101 at predetermined time intervals. The detected voltage is transmitted to the control unit 105. The rated output voltage of the battery pack 1 is 3.7V, and when the rated output voltage is less than 2.5V, the power supply from the battery pack to the portable device is stopped.
[0046]
Based on the voltage of the battery cell detected and transmitted by the voltage detection circuit 102 and the number of times of charging recorded in the EEPROM 106, the control unit 105 also stores the remaining power of the battery cell, which is also stored in the EEPROM 106. The current remaining power is calculated with reference to the table for calculating.
[0047]
In this battery pack 1, if the voltage of the battery cell 101 is 2.0 V or more, the remaining power is calculated each time the voltage is detected. Therefore, the EEPROM 106 always has the latest remaining power. To be recorded.
[0048]
Here, a table for calculating the remaining power of the battery cell is shown in Table 1 below.
[0049]
[Table 1]

[0050]
Table 1 is a table for calculating the remaining power of the battery cell.
[0051]
The range of the number of times of charging is shown at the top of Table 1, and the discharge voltage of the battery cell is shown at the left end of Table 1.
[0052]
Here, for example, if the number of times of charging is the 50th and the discharge voltage of the battery cell is 3.4 V, the uppermost stage shown in Table 1 is “up to 100 times”, that is, 2 from the left. In the row and the left end is “3.4V”, that is, “30” shown in the third row from the bottom, it is calculated that the remaining power is 30%. In this battery pack 1, no matter how many times the charge is performed, when the discharge voltage of the battery cell becomes less than 3.2 V, the remaining power is actually “0” even if the remaining power is not zero. The
[0053]
Further, it can be seen from Table 1 that although the battery capacity decreases with the number of times of charging, the detectable voltage of the battery cell does not change with the number of times of charging.
[0054]
FIG. 6 is a graph showing the relationship between the discharge voltage of the battery cell and the discharge time.
[0055]
FIG. 6 shows the relationship between the discharge voltage of the battery cell and the discharge time for each number of times of charge, but the maximum discharge voltage is the same even if the number of times of charge is increased. However, as the number of times of charging proceeds, the discharge voltage decreases more quickly.
[0056]
FIG. 7 is a flowchart of the calculation operation of the remaining power in the battery pack.
[0057]
FIG. 7 shows a routine that is started when the voltage value detected by the voltage detection circuit 102 of the battery pack 1 is transmitted to the control unit 105.
[0058]
In step S11, the number of times of charging is read from the EEPROM 106, and in step S12, the remaining battery level calculation table stored in the EEPROM 106 based on the voltage value transmitted from the voltage detection circuit 102 and the read number of times of charging. To calculate the remaining battery level. Thereafter, in step S13, the transmitted voltage value and the calculated remaining battery level are written to the EEPROM 106, and this routine is terminated.
[0059]
After the remaining power is written in the EEPROM 106 as described above, the remaining power is read by the wireless tag provided in the battery pack 1.
[0060]
As described above, the wireless tag 107 supplies power to the EEPROM 106 to activate the EEPROM 106, and reads the remaining battery level and the number of times of charging recorded in the EEPROM 106. However, at this time, the number of times of charging recorded in the EEPROM 106 is also read out. When the read charge count is 500 or more, the wireless tag 107 asserts a battery life flag indicating that the battery life of the battery pack is exhausted.
[0061]
The wireless tag 107 also supplies power to the voltage detection circuit 102. The voltage detection circuit 102 is activated with the power and reads the voltage detected by the voltage detection circuit. When the read voltage is less than 2.0 V, the wireless tag 107 asserts a cell short flag indicating that the battery cell has caused a cell short. If the cell short flag is not asserted, the wireless tag transmits the remaining power and the number of times of charging together with information indicating that the battery life is exhausted when the number of times of charging is 500 times or more. On the other hand, when the cell short flag is asserted, information indicating that the battery cell has caused a cell short is transmitted to the outside instead of the remaining power and the number of times of charging.
[0062]
Therefore, in the battery pack 1, when the battery cell is not short-circuited with respect to the transmission of electromagnetic waves from the outside, it indicates that the latest remaining power and the number of times of charge, and in some cases, the battery life is exhausted. Information is also transmitted to the outside, and when the battery cell is short-circuited, only information indicating that is transmitted to the outside. As described above, the power stored in the battery cell is not used for the transmission of information to the outside.
[0063]
FIG. 8 is a flowchart of a routine that is started when the wireless tag of the battery pack operates.
[0064]
FIG. 8 shows a routine that is started when an electromagnetic wave is transmitted to the wireless tag 107. In step S21, the EEPROM 106 is started by the power supplied from the wireless tag to the EEPROM 106, and the wireless tag is used. The number of times of charging and the remaining power are read out. Thereafter, the process proceeds to step S22.
[0065]
In step S22, the voltage of the battery cell is detected by the voltage detection circuit 102 by the power supplied from the wireless tag 107 to the voltage detection circuit 102, and the detected voltage is read by the wireless tag. Thereafter, the process proceeds to step S23, in which it is determined whether or not the voltage detected by the voltage detection circuit 102 is less than 2.0 V, that is, whether or not the battery cell is short-circuited.
[0066]
If it is determined in step S23 that a cell short has occurred, the process proceeds to step S28, where the cell short flag provided in the wireless tag is asserted, and then in step S29, a cell short occurs in the battery cell. Information indicating that this is in progress is transmitted to the outside, and this routine is terminated.
[0067]
On the other hand, if it is determined in step S23 that no cell short has occurred, the process proceeds to step S24, where it is determined whether or not the number of times of charging already read is 500 or more.
[0068]
If it is determined in step S24 that the number of times of charging is 500 times or more, the process proceeds to step S25, and the battery life flag provided in the wireless tag is asserted. Thereafter, the process proceeds to step S26, and information indicating that the remaining power, the number of times of charging, and the battery life is exhausted is transmitted to the outside, and this routine is terminated.
[0069]
On the other hand, if it is determined in step S24 that the number of times of charging is not 500 times or more, the process proceeds to step S27, the remaining power and the number of times of charging are transmitted to the outside, and this routine is terminated.
[0070]
In the battery pack 1 of the present embodiment described above, the remaining amount of power and the number of times of charging can be transmitted to the outside without consuming its own power, and the number of times of charging has exhausted the battery life. In the case of 500 or more representing that, information representing that is also transmitted to the outside. Furthermore, in the battery pack 1, when a battery cell has a cell short, information indicating that is transmitted to the outside instead of the remaining battery level and the number of times of charging.
[0071]
In this embodiment, the wireless tag supplies power to the voltage detection circuit, and it is determined whether or not the battery cell has caused a cell short according to the voltage detected by the voltage detection circuit. In the above description, the information indicating that is transmitted to the outside. However, the wireless tag may transmit the voltage detected by the voltage detection circuit and the number of times of charging to the outside. Further, in the present embodiment, the wireless tag may supply power only to the EEPROM and transmit only the remaining power and the number of times of charging recorded in the EEPROM to the outside. A counter area for counting the number of times of charging may not be provided, and the wireless tag may transmit only the remaining amount of power to the outside.
[0072]
【The invention's effect】
As described above, according to the battery pack of the present invention, the remaining power of the battery cell can be known without consuming the power of the battery cell.
[Brief description of the drawings]
FIG. 1 is an external perspective view of a common embodiment of a first battery pack and a second battery pack according to the present invention.
FIG. 2 is an internal block diagram of the present embodiment.
FIG. 3 is a power system diagram of the battery pack of the present embodiment.
FIG. 4 is a diagram showing the relationship between battery capacity and the number of times of charging.
FIG. 5 is a routine that starts when the battery pack of the present invention is fitted into a charger.
FIG. 6 is a graph showing the relationship between the discharge voltage and discharge time of a battery cell.
FIG. 7 is a flowchart of a remaining power calculation operation in the battery pack.
FIG. 8 is a flowchart of a routine that is started when the wireless tag of the battery pack operates.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Battery pack 11 Positive terminal 12 Negative terminal 101 Battery cell 102 Voltage detection circuit 103 Discharge switch 104 Charge switch 105 Control part 106 EEPROM
107 wireless tag 107a coil

Claims (5)

In the battery pack that is charged by receiving power from the outside to the internal battery cell and supplies the electric power charged to the battery cell to the outside,
A charge counter that counts the number of times the battery cell is charged;
A voltage monitor for detecting the voltage of the battery cell;
A remaining amount calculating unit that calculates the remaining amount of power remaining in the battery cell based on the number of times of charging counted by the charging number counter and the voltage of the battery cell detected by the voltage monitor;
A memory unit that stores the remaining amount of electric power remaining in the battery cell, calculated by the remaining amount calculation unit;
The coil has a coil that receives power supplied from outside by electromagnetic induction and transmits information to the outside, and uses the power supplied via the coil to access the memory unit to store the remaining amount in the coil A battery pack comprising a wireless tag that wirelessly transmits via a battery. In the battery pack that is charged by receiving power from the outside to the internal battery cell and supplies the electric power charged to the battery cell to the outside,
A charge counter that counts the number of times the battery cell is charged;
A voltage monitor for detecting the voltage of the battery cell;
A memory unit that stores the number of times of charging counted by the number of times of charging counter and the voltage detected by the voltage monitor;
The coil has a coil that receives power supplied from outside by electromagnetic induction and transmits information to the outside, and uses the power supplied through the coil to access the memory unit and the voltage of the battery cell And a wireless tag that wirelessly transmits the number of times of charging through the coil. In addition to the memory unit, the wireless tag further supplies power to the voltage monitor, and reads the voltage detected by the voltage monitor,
The wireless tag wirelessly transmits information indicating that the battery cell has caused a cell short when the read voltage is less than a predetermined threshold instead of the remaining amount. The battery pack according to claim 1. In addition to the memory unit, the wireless tag further supplies power to the voltage monitor, and reads the voltage detected by the voltage monitor,
When the read voltage is less than a predetermined threshold, the wireless tag wirelessly transmits information indicating that the battery cell has caused a cell short circuit instead of the voltage and the number of times of charging. The battery pack according to claim 2. In addition to the remaining amount, the memory unit further stores the number of times of charging counted by the number of times of charging counter,
The battery pack according to claim 1, wherein a wireless tag transmits the number of times of charging in addition to the remaining amount.

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