JPH05290893A - Battery device - Google Patents

Abstract

PURPOSE:To enable accurate announcement of the consumable time of a battery device and accurate announcement of the consumable time even in no-load condition when a computing processing unit can be operated. CONSTITUTION:A battery device comprises a chargeable batteries 11a to 11d, a computing processing unit 15 for detecting the consumption capacity of the batteries 11a to lid and calculating the remaining consumable time from the consumption capacity, and a display circuit 17 for displaying the consumable time from the processing unit 15. The processing unit 15 detects the consumption capacity from current information by way of the batteries 11a to 11d, a detecting resistor 12, an amplifier 13, and further an A/D converter 14.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery device used for supplying power to a video camera or the like.

[0002]

2. Description of the Related Art Conventionally, various types of primary batteries or secondary batteries have been mounted for power supply in electronic devices such as portable radio receivers and so-called handy type video cameras. Further, in an electronic device or the like equipped with a secondary battery or the like that can be charged and used repeatedly, in order to easily attach / detach to / from the electronic device or the charging device, a single or a plurality of secondary batteries or the like A battery device, which is a so-called battery pack, in which is stored in one case is used.

For example, as shown in FIG. 3, the battery device includes a battery case 30 made of a resin material and having a substantially rectangular parallelepiped shape, and a plurality of discharges stored in the battery case 30. / Rechargeable battery 31a,
31b, 31c, 31d (hereinafter, referred to as batteries 31a to 31d
Abbreviated. ) And are formed.

The battery device needs to be mounted on an electronic device such as a video camera (hereinafter abbreviated as a load) or a charging device (hereinafter abbreviated as a charger) and electrically connected thereto. Therefore, a substantially elliptical anode terminal plate 30a is formed on one surface 30c of the outer casing of the battery device (that is, one surface of the battery case 30) that comes into contact with the load or the charger.
And the cathode terminal plate 30b are mounted side by side. In FIG. 3, an opening portion for the anode and the cathode is formed on one surface 30c of the battery case 30, and the opening portion is formed from the inside of the battery case 30 by the anode terminal plate 30a and the cathode terminal plate 30b. The anode terminal plate 30 so as to cover the
a and the cathode terminal plate 30b are mounted side by side. In addition,
The anode terminal plate 30a is electrically connected to the anode side of the battery 31a, and the cathode terminal plate 30b is electrically connected to the cathode side of the battery 31d.

In order to mount the battery device on the load or the charger, or to prevent the battery device from coming off or dropping from the load or the charger after mounting, For example, battery case 3
Guides 30d, 30e, 3 on both end surfaces of the connection surface 30c
0f and 30g are provided.

On the other hand, in the batteries 31a to 31d formed in a substantially cylindrical shape, for example, the anode side of the battery 31a and the cathode side of the battery 31b are mounted side by side in the battery case 30. Further, the battery 31
A connector for the anode of a and the cathode of the battery 31b (not shown)
Connection in the same way, as shown by the broken line in the figure,
The positive and negative electrodes are arranged differently from the adjacent batteries, and they are connected in series so that the maximum output can be obtained by connecting with each connector. Further, the anode side of the battery 31a is an anode terminal plate 30a, and the cathode side of the battery 31d is a cathode terminal plate 30b.
Are connected.

When such a battery device is connected to a load, it supplies the electric power stored in the batteries 31a to 31d to the load via the anode terminal plate 30a and the cathode terminal plate 30b, and also the charger. Power is supplied to the batteries 31a to 31d through the anode terminal plate 30a and the cathode terminal plate 30b.

[0008]

By the way, the above-mentioned battery device has a positive electrode member incorporated in the battery device,
Discharge capacity (rated capacity) depending on the negative electrode member or electrolyte
Is prescribed. Therefore, when the battery device supplies power to a portable electronic device such as a video camera equipped with the battery device by the discharge capacity, the capacity of the battery device becomes 0, and charging by the charging device or the like occurs. Will be forced to.

On the other hand, in an electronic device or the like equipped with the battery device, there is a risk that the electronic device may not operate normally before the time when the capacity of the battery device becomes completely zero. is there. Therefore, it is desired to predict the charging timing of the battery device.

In response to such a demand, for example, as shown in FIG. 4, it is known that one surface of the outer casing of the battery device indicates the remaining capacity of the battery device as a percentage.

However, in the above-described battery device that indicates the remaining capacity in percentage, it is possible to determine how much electronic equipment or the like equipped with the battery device can be used even if the user can be notified of the remaining capacity of the battery device. Can not do it. Further, when the battery device is usable for various electronic devices and the like, it is difficult to accurately predict the charging timing from the remaining capacity because the consumption voltage varies depending on the electronic device and the like used. ..

On the other hand, when connecting the battery device to a charging device or the like for charging, for example, by providing a light emitting diode (LED) on one surface of the outer casing of the charging device or the like, When the light emitting diode is lit, charging is being performed, and when the light emitting diode is not lighting, the user is informed that the charging is completed.

However, although the above-mentioned light emitting diode or the like can represent the above-described charging / completion of charging, it cannot predict the timing of completion of charging.

Therefore, it is desired that the charging timing, the charging ending timing, etc. of the battery device can always be accurately predicted and notified to the user.

The present invention has been made in view of the above circumstances. First, it displays the consumable time (usable time, dischargeable time) of the battery according to the consumed capacity of the battery. Another object is to provide a battery device capable of displaying the charging completion time of the battery according to the charging capacity of the battery.

[0016]

In order to achieve the above-mentioned object, one battery device according to the present invention is a rechargeable battery and a consumption device that detects the consumed capacity of the battery and outputs consumed capacity information. A capacity detecting means, a consumable time calculating means for calculating a consumable time of the battery from the consumed capacity information from the consumed capacity detecting means and outputting consumable time information, and a consumable time calculating means The above problem is solved by having a consumable time display means for displaying the consumable time according to time information.

Another battery device according to the present invention is
A rechargeable battery, a charging capacity detecting means for detecting the charging capacity of the battery and outputting charging capacity information, and a charging completion time of the battery is calculated from the charging capacity information from the charging capacity detecting means to complete charging. The problem is solved by having a charging completion time calculating means for outputting time information and a charging completion time displaying means for displaying the charging completion time according to the charging completion time information from the charging completion time calculating means. ..

[0018]

In one battery device according to the present invention, the consumed capacity detecting means detects the consumed capacity of the battery and outputs the consumed capacity information, and the consumable time calculating means uses the consumed capacity information from the consumed capacity detecting means. The consumable time of the battery is calculated and consumable time information is output, and the consumable time display means displays the consumable time according to the consumable time information from the consumable time calculation means.

Further, in another battery device according to the present invention, the charge capacity detecting means detects the charge capacity of the battery and outputs the charge capacity information, and the charge completion time calculating means calculates the charge from the charge capacity detecting means. The charge completion time of the battery is calculated from the capacity information and the charge completion time information is output, and the charge completion time display means displays the charge completion time according to the charge completion time information from the charge completion time calculation means.

[0020]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Specific embodiments to which the present invention is applied will be described in detail below with reference to the drawings. FIG. 1 is a schematic circuit diagram showing an embodiment of a battery device according to the present invention. FIG. 2 is an external perspective view of the battery device of the above-described embodiment, showing a display means for the dischargeable time or the charge completion time.

First, referring to FIG. 1, a plurality of rechargeable batteries 11a, 11b, 11c and 11d (hereinafter referred to as battery 11a
Abbreviated to 11d. ) Are connected in series. Further, the anode terminal 10a is connected to the anode side of the battery 11a via a detection resistor 12 having a low resistance of, for example, about 20 mΩ,
A cathode terminal 10b is connected to the cathode side of the battery 11d. As a result, the battery device can be electrically connected to an electronic device or the like (hereinafter abbreviated as a load) or a charging device or the like (hereinafter abbreviated as a charger).

Here, the anode terminal 10a and the cathode terminal 10
When a load is connected to b, the electric power stored in the batteries 11a to 11d is supplied to the load via the anode terminal 10a and the cathode terminal 10b, and the anode terminal 10a and the cathode terminal 10b are connected to the load. When the charger is connected, electric power is stored in the batteries 11a to 11d from the charger via the anode terminal 10a and the cathode terminal 10b.

At this time, the detection resistor 12 converts the current flowing through the load or the charger into a voltage and detects it.
The voltage detected by the detection resistor 12 is input to the amplifier 13. The detection voltage from the detection resistor 12 is amplified by the amplifier 13, and the output signal is output from the arithmetic processing unit 15 and the analog / digital converter (hereinafter referred to as A / D).
Abbreviated as converter. ) 14 is input. Further, the amplified signal from the amplifier 13 is digitally converted by the A / D converter 14, and the output signal thereof is the arithmetic processing unit 15 described above.
Entered in. Therefore, the output signal from the amplifier 13 and the output signal from the A / D converter 14 are input to the arithmetic processing unit 15. Each output signal represents current value information.

The arithmetic processing unit 15 first identifies the polarity of the current flowing through the detection resistor 12 by comparing the output signal from the amplifier 13 with a reference voltage. Thereby, the arithmetic processing unit 15 determines to which of the load / charger the battery device is connected. In addition,
The arithmetic processing unit 15 has a built-in comparator or the like for performing the above-described processing.

In accordance with the result of the polarity of the current flowing through the detection resistor 12, the arithmetic processing unit 15 switches to the discharge mode / charge mode. For example, this arithmetic processing unit 15
When it is determined that the battery device is connected to a load, the battery device is switched to a discharge mode in which the consumed capacities of the batteries 11a to 11d are detected and the consumable time of the batteries 11a to 11d is calculated. Fifteen,
When it is determined that the battery device is connected to the charger, the battery device switches to a charging mode in which the charge capacities of the batteries 11a to 11d are detected and the charging completion time of the batteries 11a to 11d is calculated.

First, the case where the arithmetic processing unit 15 is switched to the discharge mode will be described.

The discharge mode in this embodiment corresponds to one battery device according to the present invention, and when the arithmetic processing unit 15 determines the output signal from the amplifier 13 and switches to the discharge mode, First, the arithmetic processing device 1
Reference numeral 5 calculates a current value (current value information) flowing through the detection resistor 12 from the output signal from the A / D converter 14, and further, its supply time from the time point when the current value information starts to be calculated, that is, The discharge time (use time) of the battery device is measured. Then, the arithmetic processing unit 15 determines [(current value) × (time)] at constant intervals from the current value information and the discharge time, that is, the consumed capacity of the batteries 11a to 11d consumed by the load (consumed capacity). Information).

The above-described processing is repeatedly performed during the usage time in which the battery device is used.

The current value (current value information) calculated from the output signal from the A / D converter 14 is subjected to correction processing with respect to the temperature change of the battery device, whereby an accurate current value (hereinafter , Correction current value) has been calculated. In order to perform this correction processing, a temperature sensor 16 is provided in the battery device, and current value correction rate information is stored in the arithmetic processing device 15. That is, the temperature change information detected by the temperature sensor 16 is input to the arithmetic processing unit 15, and the arithmetic processing unit 15 corrects the current value by the current value correction rate information for the temperature change. Therefore, the arithmetic processing unit 15 always calculates an accurate current value (hereinafter, correction current value), and
With this, the accurate consumed capacity is always calculated.

Table 1 shows an example of the current value correction rate with respect to the temperature change.

[0031]

[Table 1]

Next, the arithmetic processing unit 15 calculates the remaining capacity at the present time of the battery unit from the above-mentioned consumed capacity and the rated capacity (or the remaining capacity) of the batteries 11a to 11d stored in the arithmetic processing apparatus 15. To calculate. Then, the remaining capacity information at this time is newly stored by deleting the rated capacity information (or the remaining capacity information) stored in the storage unit.

The rated capacity information (or the remaining capacity information) stored in the storage unit is subjected to a correction process for the no-load time of the battery device, that is, the spontaneous discharge when the battery device is not connected to the load. This correction process is performed, for example, when the battery device is connected to a load, and thereby, it is possible to always supply an accurate remaining capacity (hereinafter, corrected remaining capacity) when the battery device is used. In order to perform this correction processing, the arithmetic processing unit 15 is provided with a timer and the spontaneous discharge amount correction rate information is stored. That is, the arithmetic processing unit 15 calculates the natural discharge amount from the no-load time detected by the timer, and further the rated capacity information (or the remaining capacity information) is corrected by the natural discharge amount.

Table 2 shows an example of the natural discharge amount correction rate.

[0035]

[Table 2]

Next, the arithmetic processing unit 15 uses the above-mentioned rated capacity (or corrected remaining capacity) or the remaining capacity at the present time and the above-mentioned corrected current value to determine the available time (usable time) of the battery apparatus at the present time. Time, dischargeable time) is calculated. This consumable time information is output to the display circuit 16.

The discharge mode processing function of the arithmetic processing unit 15 described above corresponds to the consumed capacity detecting means and the consumable time calculating means of one battery device according to the present invention. And
A microprocessor is applied to the arithmetic processing unit 15 in order to realize the consumed capacity detecting means and the consumable time calculating means.

The dischargeable time information from the arithmetic processing unit 15 is output to and displayed on the display circuit 17 which is a display means including a liquid crystal display element (LCD) or the like. In addition,
The display circuit 17 needs to be formed at a good visual field position for the user when the battery device is attached to a portable electronic device such as a video camera. For example, as shown in FIG. The battery device is disposed on the back side of the contact surface with the electronic device while ensuring a good view position for the user.

Therefore, with the one battery device according to the present invention, it is possible to always display the correct consumable time on the outer casing of the battery device, so that the charging timing of the battery device can be accurately displayed to the user or the like. It becomes possible to notify.

In the battery device of this embodiment,
Even when the battery device is not connected to the electronic device, the dischargeable time of the battery device can be displayed on the display circuit 17 if the capacity for operating the arithmetic processing device 15 normally remains.

In the battery device of this embodiment,
When the battery device is connected to various electronic devices having different consumption voltages and capable of supplying electric power, a selection circuit 18 for selecting various electronic devices is provided as shown in FIG. May be. By this selection circuit 18,
Even when the battery device is connected to various electronic devices having different consumption voltages, it is possible to always display the correct dischargeable time.

Next, the case where the arithmetic processing unit 15 is switched to the charging mode will be described.

The charging mode in this embodiment corresponds to another battery device according to the present invention, and when the arithmetic processing unit 15 discriminates the output signal from the amplifier 13 and switches to the charging mode, Similarly to the above, the arithmetic processing unit 15 calculates the current value (current value information) flowing through the detection resistor 12 from the output signal from the A / D converter 14, and further starts calculating the current value information. The supply time (that is, the charging time of the battery device) is measured from that point. Then, the arithmetic processing unit 15 calculates the charge capacity (charge capacity information) for each constant time from the current value information and the discharge time.

The current value (current value information) is corrected by the current value correction rate calculated from the temperature change information from the temperature sensor 16 as described above. Therefore, an accurate current value (hereinafter, corrected current value) is always calculated, and an accurate charge capacity is always calculated.

Further, the arithmetic processing unit 15 has the above-mentioned charge capacity and the battery 11a stored in the arithmetic processing unit 15.
From the remaining capacity of 11 to 11d, the current capacity of the battery device until the charging is completed (hereinafter, the charging completion capacity) is calculated. Then, this charge completion capacity information is newly stored by deleting the remaining capacity information stored in the storage unit.

The remaining capacity information stored in the storage unit is corrected by the amount of natural discharge calculated from the natural discharge time from the timer of the arithmetic processing unit 15 as described above. As a result, when the battery device is connected to the charger, it is possible to always supply an accurate remaining capacity (hereinafter, corrected remaining capacity).

Further, the arithmetic processing unit 15 calculates the charge completion time of the battery unit from the above-described corrected residual capacity or charge completed capacity and the corrected current value, as described above. Then, this charging completion time is output to the display circuit 17.

The charge mode processing function of the arithmetic processing unit 15 described above corresponds to a charge capacity detecting means and a charge completion time calculating means of another battery device according to the present invention.

Then, the charging completion time information output from the arithmetic processing unit 15 is output to the display circuit 17 which is a display means and displayed.

Therefore, the other battery device according to the present invention can always display the accurate charging completion time on the outer casing of the battery device, thereby making it possible to notify the user or the like of the charging end timing of the battery device. It is possible to make an accurate announcement.

In the battery device of this embodiment,
Even when the battery device is not connected to the charger, the charge completion time of the battery device can be displayed on the display circuit 17 if the capacity for operating the arithmetic processing device 15 normally remains.

Needless to say, the battery device of this embodiment is not limited to the above embodiment. For example, the battery device of the present embodiment may be configured to have a function corresponding to one battery device according to the present invention and a function corresponding to another battery device according to the present invention independently. ..

Further, in the battery device of this embodiment, for example, a changeover switch or the like may be provided in the battery device of this embodiment so that the dischargeable time / charging completion time can be switched and displayed according to the convenience of the user. .. Further, when the battery device is not connected to the electronic device or the charger, the remaining capacity of the battery device stored in the arithmetic processing device 15 is, for example, a percentage ratio of the remaining capacity calculated from the rated capacity to the rated capacity. With the above display circuit 1
It may be displayed on 7.

Further, in the battery device of this embodiment, the display circuit 17 is not limited to the liquid crystal display element (LCD), and for example, a light emitting diode (LED) capable of displaying a dischargeable time or a charge completion time. ) And other various measuring instruments (meters, etc.) may be used.

Further, in the battery device of this embodiment, the current detected by the detection resistor 12 is stored by, for example, storing the relational information between the voltages of the batteries 11a to 11d and the remaining capacity in the arithmetic processing device 15 in advance. The remaining capacity may be calculated from the voltage value information obtained by converting the value information into a voltage, and the consumable time or the charging completion time may be displayed from the remaining capacity, which can be changed without departing from the spirit of the present invention.

[0056]

As is apparent from the above description, according to one battery device of the present invention, the consumed capacity detecting means detects the consumed capacity of the battery and the consumable time calculating means detects the consumed capacity information. It is possible to accurately notify the user or the like of the consumable time or the charging timing of the battery device by calculating the consumable time of the battery from the above and displaying the consumable time by the consumable time display means. Become. Furthermore, when the consumed capacity detecting means and the consumable time calculating means are operable, the consumable time can be accurately notified even in a no-load state.

According to another battery device of the present invention, the charging capacity detecting means detects the charging capacity of the battery and the charging completion time calculating means calculates the charging completion time of the battery from the charging capacity. By displaying the charging completion time by the charging completion time display means, it is possible to inform the user etc. of the charging completion time or the charging end timing of the battery device accurately, and further, the charging capacity detection means and the charging When the completion time calculating means is operable, the charging completion time can be accurately recognized.

[0058]

[Brief description of drawings]

FIG. 1 is a schematic circuit diagram showing an embodiment of a battery device according to the present invention.

FIG. 2 is an external perspective view of the battery device according to the present invention viewed from the back side.

FIG. 3 is a schematic perspective view showing a conventional battery device.

FIG. 4 is an external perspective view of a conventional battery device viewed from the back side.

[Explanation of symbols]

 10a ・ ・ ・ Anode terminal 10b ・ ・ ・ ・ ・ Cathode terminal 11a, 11b, 11c, 11d ・ ・ ・ ・ ・ Battery 12 ・ ・ ・ ・ ・ Detection resistor 13 ・ ・ ・ ・ ・ Amplifier 14 ・ ・ ・ ・ ・A / D converter 15 ・ ・ ・ ・ ・ Arithmetic processing device 16 ・ ・ ・ ・ ・ Temperature sensor 17 ・ ・ ・ Display circuit 18 ・ ・ ・ ・ ・ Selection circuit

Claims (2)

[Claims] 1. A rechargeable battery, a consumed capacity detecting means for detecting consumed capacity of the battery and outputting consumed capacity information, and a consumable time of the battery based on consumed capacity information from the consumed capacity detecting means. And a consumable time calculating means for calculating and outputting the consumable time information, and a consumable time display means for displaying the consumable time according to the consumable time information from the consumable time calculating means. Battery device. 2. A rechargeable battery, a charging capacity detecting means for detecting a charging capacity of the battery and outputting charging capacity information, and a charging completion time of the battery based on the charging capacity information from the charging capacity detecting means. A charging completion time calculating means for calculating and outputting charging completion time information; and a charging completion time displaying means for displaying the charging completion time according to the charging completion time information from the charging completion time calculating means. Battery device.