JP2001054243A - Charging device, charging method, and power supply device - Google Patents

Abstract

(57) [Problem] To electrically determine whether a battery connected to a battery terminal is a primary battery or a secondary battery, and to reliably determine the type of battery. A battery terminal (23) to which a primary battery (21) or a secondary battery (22) is connected, a voltage applied from the outside, a charging terminal (24) connected to the battery terminal (23), a battery terminal (23) and a charging terminal (24). Between the battery terminals 23
Disconnecting circuit 25 for disconnecting the charging terminal 24 and the battery terminal 2
3 and a disconnection circuit 25
Is turned on, and the first voltage of the battery terminal 23 when the voltage from the charging terminal 24 is applied and the battery terminal 23 when the voltage from the charging terminal 24 is not applied to the battery terminal 23
Power supply control circuit 2 for calculating the amount of voltage change from the second voltage
And the power supply control circuit 28 determines the type of the battery connected to the battery terminal 23 based on the amount of voltage change, and determines that the battery connected to the battery terminal 23 is the primary battery 21. The cutting circuit 25 is turned off.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a charging device and a charging method capable of connecting a primary battery and a secondary battery to a first terminal and a power supply device, and more particularly, to a power supply device connected to the first terminal. The present invention relates to a charging device, a charging method, and a power supply device that can electrically determine a type of a battery and charge only when a secondary battery is connected to a first terminal.

[0002]

2. Description of the Related Art A portable electronic device such as a portable recording and / or reproducing apparatus using an optical disc, a disc cartridge or the like as a recording medium uses a primary battery or a secondary battery as a power source and supplies a DC power from the outside. Some are provided with a DC power supply terminal so as to be able to perform the operation. This type of portable electronic device is provided with a charging device so that a secondary battery can be charged. Since the primary battery and the secondary battery have very similar shapes, this charging device is currently used to prevent a user from performing a charging operation accidentally when using the primary battery. Provide a detection mechanism to detect the type of battery that is, that is, whether the battery currently used is a primary battery or a secondary battery,
When the detection mechanism detects that the battery is a primary battery, charging is forcibly prohibited.

Conventionally, this detection mechanism is provided with a detection section comprising a concave portion or a protrusion indicating that the battery is a secondary battery in a housing of the secondary battery, thereby making the external shape different from that of the primary battery. By providing a mechanical detection switch in the battery storage unit in which the primary battery or the secondary battery is stored, the type of the battery stored in the battery storage unit is detected. That is, when the primary battery is stored in the battery storage unit, the detection switch is turned on or off when the primary battery is stored in the battery storage unit, and the secondary battery is stored in the battery storage unit. When the detection is performed, the detection switch is turned off or on by the detection unit, so that the primary battery and the secondary battery are determined.

[0004]

The portable electronic device has been further downsized in order to improve the convenience. In this case, the charging device provided with the above-described detection mechanism needs to provide a mechanical detection switch in the battery storage unit, which hinders further miniaturization of the portable electronic device. Also, if the detection section of the secondary battery is damaged, the detection switch cannot detect the detection section,
If the user erroneously performs the charging operation while using the primary battery, the charging device may charge the primary battery. Further, if the mechanically provided detection switch is damaged by an impact or the like, the detection unit provided on the secondary battery cannot be detected. Was charged. If the primary battery is charged, the primary battery will leak.

Therefore, according to the present invention, it is electrically determined whether the battery connected to the first terminal is a primary battery or a secondary battery, so that the battery is reliably a primary battery or a secondary battery. It is an object of the present invention to provide a charging device and a charging method capable of determining whether the power supply device has been charged, and a power supply device including the charging device.

[0006]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, a charging device according to the present invention has a first terminal to which a primary battery or a secondary battery is connected, a voltage externally applied, A second terminal connected to the first terminal;
And a disconnection circuit provided between the first terminal and the second terminal for disconnecting the first terminal and the second terminal, and a voltage for detecting a voltage of the first terminal to which the primary battery or the secondary battery is connected. A detection circuit, a first voltage of the first terminal detected by the voltage detection circuit when the disconnection circuit is on, and a second voltage of the first terminal detected by the voltage detection circuit when the disconnection circuit is off. A power supply control circuit for calculating a voltage change amount with respect to the voltage. Then, the power supply control circuit determines the type of the battery connected to the first terminal based on the amount of voltage change, and when determining that the battery connected to the first terminal is a primary battery, turns off the disconnection circuit. Turn off.

In order to solve the above-mentioned problems, the charging method according to the present invention applies an external voltage to a first terminal to which a primary battery or a secondary battery is connected via a second terminal. Step, detecting and storing a first voltage of a first terminal to which a primary or secondary battery to which an external voltage is applied is connected, and disconnecting the first terminal and the second terminal Detecting the second voltage of the first terminal to which the primary battery or the secondary battery is connected after disconnecting the first terminal and the second terminal, and storing the first voltage and the first voltage. Calculating the voltage change amount of the second voltage, determining the type of the battery connected to the first terminal based on the voltage change amount, and determining that the primary battery is connected to the first terminal. Disconnecting the first terminal and the second terminal when determining Obtain.

Further, in order to solve the above-mentioned problems, the power supply device according to the present invention has a first terminal to which a primary battery or a secondary battery is connected, a voltage applied from the outside,
A second terminal connected to the first terminal, a cutting circuit provided between the first terminal and the second terminal for cutting the first terminal and the second terminal, and a primary battery or a secondary battery. A voltage detection circuit for detecting a voltage of a first terminal to which a secondary battery is connected, an output circuit for fixing different voltages applied by the first terminal and the second terminal and outputting the same to each circuit, and a disconnection circuit Between the first voltage of the first terminal detected by the voltage detection circuit when the switch is on and the second voltage of the first terminal detected by the voltage detection circuit when the disconnection circuit is off And a power supply control circuit that calculates Then, the power supply control circuit determines the type of the battery connected to the first terminal based on the amount of voltage change, and when determining that the battery connected to the first terminal is a primary battery, turns off the disconnection circuit. Turn off.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an optical disk reproducing apparatus to which the present invention is applied will be described with reference to the drawings. This optical disk reproducing device is a portable device that is formed slightly larger than an optical disk and uses a primary battery, a secondary battery, or an external power supply as a power supply. As shown in FIG. 1, the optical disc reproducing apparatus 1 irradiates a reproduction-only optical disc 10 on which an information signal such as a musical tone signal is recorded with a light beam and detects a reflected return light beam. An optical pickup 11 for reading an information signal from the optical disk 5; an RF amplifier 12 for amplifying an output signal output from the optical pickup 11;
A signal processing circuit 13 for converting the RF signal from the second to an analog signal to generate a reproduced signal, an amplifier 14 for amplifying the reproduced signal, and earphones, headphones, speakers, etc. for outputting the reproduced signal amplified by the amplifier 14. And an output unit 15. Further, the optical disk reproducing device 1 includes an RF amplifier 1
A servo circuit 16 for performing servo control based on the output of
A drive circuit 17 for driving and controlling the optical pickup 11 based on a servo signal from the servo circuit 16, a main controller 18 for controlling the signal processing circuit 13 and the servo circuit 16, and electric power to these circuits such as a reproduction system circuit. And a power supply circuit 20 for supplying.

The optical pickup 11 includes a semiconductor laser that emits a light beam, an objective lens that focuses the light beam emitted from the semiconductor laser, a photodetector that detects a return light beam reflected by the optical disk 10, and the like. Is provided.
The light beam emitted from the semiconductor laser is converged by the objective lens and is irradiated on the signal recording surface of the optical disc 10. Then, the return light beam reflected by the signal recording surface of the optical disk 10 is converted into an electric signal by a photodetector, and the photodetector supplies the electric signal to the RF amplifier 12. The objective lens is held by a driving mechanism such as a biaxial actuator, and is driven and displaced in a focusing direction parallel to the optical axis of the objective lens and in a tracking direction orthogonal to the optical axis of the objective lens.

The RF amplifier 12 generates an RF signal, a focus error signal, and a tracking error signal based on an output signal from a photodetector constituting the optical pickup. For example, a focus error signal is generated by an astigmatism method, and a tracking error signal is generated by a three-beam method or a push-pull method. Then, the RF amplifier 12 supplies the RF signal to the signal processing circuit 13, and supplies the focus error signal and the tracking error signal to the servo circuit 16.

The signal processing circuit 13 includes an error detection and correction circuit for detecting and correcting a code error, a digital / analog conversion circuit (A / D conversion circuit) for converting a digital signal into an analog signal, and the like. The signal processing circuit 13 detects and corrects a code error in the RF signal by the error detection and correction circuit, and then converts the error-corrected RF signal into an analog signal by the A / D conversion circuit to generate a reproduced signal.

A servo circuit 1 to which a focus error signal and a tracking error signal are supplied from an RF amplifier 12
6 generates a servo signal for reproducing the optical disk 10. Specifically, the servo circuit 16 generates a focusing servo signal based on the focus error signal such that the focus error signal becomes 0, and generates a focusing servo signal based on the tracking error signal. Next, a tracking servo signal is generated. Then, the servo circuit 16 transmits the focusing servo signal and the tracking servo signal to the drive circuit 17.
To supply.

The drive circuit 17 drives and controls a two-axis actuator for driving an objective lens constituting the optical pickup 11 based on the focusing servo signal and the tracking servo signal generated by the servo circuit 16. The drive circuit 17 drives the biaxial actuator based on the focusing servo signal, and drives and displaces the objective lens in a focusing direction parallel to the optical axis of the objective lens. Further, the drive circuit 17 drives the biaxial actuator based on the tracking servo signal, and drives and displaces the objective lens in a tracking direction orthogonal to the optical axis of the objective lens.

The main controller 18 also controls the servo circuit 16 based on an operation signal from the operation section 19.
And the signal processing circuit 13 and the like. For example, the operation unit 1
9 is pressed, a reproduction start signal is input to the main controller 18, and the main controller 18 controls the servo circuit 16 and the drive circuit 17 based on the reproduction start signal, and And drives the signal processing circuit 13.

The optical disk reproducing apparatus 1 is provided with a power supply circuit 20 for supplying power to each circuit. As shown in FIG. 2, the power supply circuit 20 includes a battery terminal 23 serving as a first terminal to which a primary battery or a secondary battery 21 or 22 connected in series is connected, and a battery terminal 23 connected to the battery terminal 23. 2, a disconnection circuit 25 for disconnecting the connection between the battery terminal 23 and the charging terminal 24, a voltage detection circuit 26 for detecting a voltage applied to the battery terminal 23,
Power supply control for switching and controlling a DC / DC converter 27 that supplies power to the optical pickup 11, the signal processing circuit 13, the main controller 18, and the like while keeping the voltage applied to the battery terminal 23 and the charging terminal 24 constant. And a circuit 28.

The primary battery 21 and the secondary battery 22 are, for example, A
The primary battery 21 connected to the battery terminal 22 and having a size of type 4 has an initial voltage of, for example, 1.55 V when not used, and the secondary battery 22 has a full charge of 1.3 V.
Then, a primary battery 21 or a secondary battery 22 in which two batteries are connected in series is connected to the plus terminal 23a and the minus terminal 23b constituting the battery terminal 23. The positive terminal 23a is connected to the output terminal 29 connected to the above-mentioned reproduction system circuit driven at the predetermined voltage V _CC1 and to the DC / DC converter 27. Also, the negative terminal 23b
Are always grounded via the charging terminal 24.

The charging terminal 24 is a connector to which a jack of an AC / DC converter is connected, to which a DC voltage is applied. The charging terminal 24 includes a positive terminal 24a,
Negative side terminal 24b and grounded GND terminal 24c
The positive terminal 24a is connected to the power supply control circuit 28 to detect that the charging terminal 24 is connected to the jack of the AC / DC converter. The negative terminal 24a and the GND terminal 24c are always connected, and the negative terminal 24a is
It is grounded via the ND terminal 24c.

The disconnecting circuit 25 includes a charging terminal 24, a positive terminal 23 a of the battery terminal 23, and the DC / DC converter 2.
7, the input side is connected to an intermediate connection point between the plus side terminal 24a of the charging terminal 24 and the power supply control circuit 28, and the output side is connected to the plus side terminal 23a of the battery terminal 23 via the rectifying element 31 and the DC / DC terminal. It is connected to an intermediate connection point with the DC converter 27. The cutting circuit 25 is controlled by a power supply control circuit 28. The disconnection circuit 25 is turned on only when the secondary battery 22 is connected to the battery terminal 23, and connects the battery terminal 23 and the charging terminal 24.

The cutting circuit 25 and the battery terminal 23
A rectifying element 31 is provided between the rectifying element 31 and the positive side terminal 23a. The rectifying element 31 rectifies the charging current so that a current flows from the charging terminal 24 to the battery terminal 23 and the DC / DC converter 27. The output of the rectifier 31 is connected to the positive terminal 23a of the battery terminal 23 and the DC / D
It is connected to an intermediate connection point with the C converter 27.

A voltage detecting circuit 26 for detecting a voltage applied to the battery terminal 23 is provided at an intermediate connection point between the positive terminal 23 a of the battery terminal 23 and the DC / DC converter 27 in order to detect the voltage of the battery terminal 23. It is connected. The voltage detection circuit 26 detects the voltage of the battery terminal 23 to which the primary battery 21 or the secondary battery 22 is connected when the disconnection circuit 25 is off and on. Then, the voltage detection circuit 26
A voltage signal corresponding to the voltage of the battery terminal 23 is supplied to the power supply control circuit 28.

The DC / DC converter 27 has a battery terminal 2
3 and is connected to the positive terminal 24a of the charging terminal 24 when the cutting circuit 25 is turned on. DC / DC converter 27
Is connected to an output terminal 32 connected to each of the above-described reproduction circuits driven by the output voltage V _CC2 by setting the voltage applied from the battery terminal 23 and the charging terminal 24 to a predetermined voltage V _CC2 .

The power supply control circuit 28 controls on / off switching of the disconnection circuit 25. When the jack of the AC / DC converter is connected to the charging terminal 24, the power control circuit 28 detects that a voltage is applied to the charging terminal 24, and turns on the disconnection circuit 25. The power supply control circuit 28
Is supplied with a voltage signal indicating the voltage of the battery terminal 23 detected by the voltage detection circuit 26, and based on this voltage signal,
The switching of the disconnection circuit 25 is performed. Specifically, the power supply control circuit 28 is connected to a jack of an AC / DC converter at the charging terminal 24, and when a predetermined voltage is applied to the charging terminal 24, the battery terminal 23 when the disconnection circuit 25 is turned on. Voltage signal indicating the first voltage of the first and disconnection circuit 2
5 indicating the second voltage of the battery terminal 23 when the switch 5 is off.
Are supplied. Then, the power supply control circuit 28
Is obtained by subtracting the second voltage signal when the disconnection circuit 25 is off from the first voltage signal when the disconnection circuit 25 is on, and connecting the AC / DC converter jack to the charging terminal 24. Is calculated when the disconnection circuit 25 is ON and OFF.

Further, the power supply control circuit 26
The voltage difference ΔV _B between the terminal voltage when a voltage is applied so as to charge the battery and the terminal voltage when the voltage for this charge is not applied is previously stored in a storage circuit as a threshold value. ing. Then, the power supply control circuit 26 determines that the voltage change ΔV of the battery terminal 23 when the disconnection circuit 25 detected by the voltage detection circuit 26 is on and off is larger than the voltage change ΔV _{B for} the primary battery 21. At this time, it is determined that the battery connected to the battery terminal 23 is the primary battery 21, and the disconnection circuit 25 is turned off.

Further, the power supply control circuit 28
When the same voltage as the voltage applied when charging the secondary battery 22 is applied, the voltage increase rate X from the start of charging to the elapse of a predetermined time is stored as a threshold. When the detected voltage increase rate Y of the battery terminal 23 is smaller than the voltage increase rate of the primary battery 21, the power supply control circuit 28 determines whether the battery connected to the battery terminal 23 is the secondary battery 2.
2 is determined.

That is, when a voltage is applied between the terminals to charge the primary battery 21, the terminal voltage of the primary battery 21 rapidly rises with time as shown in FIG. When the application of the voltage to the primary battery 21 is stopped, the voltage between the terminals of the primary battery 21 decreases by ΔV _B. Then, when the application of the voltage to the primary battery 21 is restarted, the voltage between the terminals of the primary battery 21 becomes substantially ΔΔ again.
Increases V _B min. When a voltage is applied between the terminals so as to charge the secondary battery 22, as shown in FIG. 4, the voltage rises more gradually with the passage of time than in the case of the primary battery 21 shown in FIG. When the charging of the secondary battery 22 is stopped, the voltage between the terminals of the secondary battery 22 decreases by ΔV _R smaller than the decrease ΔV _{B in} the case of the primary battery 21, for example, 0.2 V. Then, again to resume charging the secondary battery 22, the terminal voltage of the secondary battery 22 is again increased substantially [Delta] V _R min. That is, the voltage change amount [Delta] V _B when no voltage is applied and when voltage is applied to the primary battery 21 is much larger than the voltage change amount [Delta] V _R during charging when the charge stop of the rechargeable battery 22 Become.

FIG. 5 shows the used primary battery 21 and
3 shows a voltage characteristic between terminals of an unused primary battery 21. In FIG.
As shown, the used primary battery 21 is charged.
When a voltage is applied across the terminals, the primary
The voltage between the terminals of the pond 21 rises rapidly. And use
When the application of voltage to the completed primary battery 21 is stopped,
The terminal voltage of the primary battery 21 is ΔV_B1Descend by one minute. Soshi
Then, the voltage is applied to the used primary battery 21 again.
Is resumed, the voltage across the terminals of the primary battery 21 becomes substantially
ΔV_B1Minutes rise. Similarly, charge unused primary battery 21
When a voltage is applied between the terminals to perform
Accordingly, the inter-terminal voltage of the primary battery 21 sharply increases. So
To stop applying voltage to the unused primary battery 21
Then, the voltage between the terminals of the primary battery 21 becomes the used primary battery.
Voltage change ΔV in case of pond 21_B1ΔV for smaller ones
_B2Descend by one minute. Then, once again, to the unused primary battery 21
When the voltage application is resumed, the terminals of the primary battery 21
The voltage is again approximately ΔV_B2Minutes rise. Used like this
Charge the primary battery 21 and unused primary battery 21
And no voltage applied
Voltage change amount V _B1, V_B2Also when charging the secondary battery 22
And the amount of voltage change V when charging is stopped_RBe greater than
I understand.

FIG. 6 shows the terminal-to-terminal voltage characteristics of the primary battery 21 when the charging current for the primary battery 21 is varied. The charging current is divided into three stages, large, medium and small.
In any case, the voltage between the terminals of the primary battery 21 increases rapidly with time, though the peak voltage is different, and when the charging is stopped, the voltage between the terminals of the primary battery 21 is increased. Drops by ΔV _B3 . Even when the current supplied to the primary battery 21 is changed in this manner, the voltage change amount ΔV _B3 between when the voltage is applied to the primary battery 21 and when the voltage is not applied is changed when the secondary battery 22 is charged and when the charging is stopped. it can be seen much larger than the voltage change amount [Delta] V _R.

As shown in FIGS. 3 and 4, the power supply control circuit 28 applies a voltage increase rate X when the same voltage is applied to the primary battery 21 to charge the secondary battery 22.
Is larger than the case where the charging voltage is applied to the secondary battery 22, the power supply control circuit 28 uses the voltage rise rate X of the primary battery 21 as a threshold, and the detected voltage rise rate Y is smaller than the voltage rise rate X. If smaller, the secondary battery 22 is determined. The power supply control circuit 28 does not charge the primary battery 21 by using the voltage increase rate X of the primary battery 21 as a threshold.

A voltage between terminals when a voltage is applied so as to charge the primary battery 21 stored in the power supply control circuit 28 in advance and a terminal when a voltage for charging is not applied. voltage variation [Delta] V _B and between the voltage, as shown in FIGS. 4 to 6, but the voltage change amount varies depending on usage or the like of the primary battery 21, the voltage change amount [Delta] V _R in the case of the secondary battery 22 Much larger. Therefore, the smallest voltage change amount ΔV _B (for example, the voltage change amount ΔV _{B 2} shown in FIG. 5) in the case of the primary battery 21 is stored in the power supply control circuit 28 as a threshold value. When the voltage change amount ΔV _{B in} the case of the primary battery 21 is larger than the power supply control circuit 28, the power supply control circuit 28 turns off the disconnection circuit 25. At this time, by using the voltage increase rate ΔV _B of the primary battery 21 as a threshold value, The primary battery 21 is not charged.

The power supply circuit 20 as described above includes a battery terminal 2
3 operates when the primary battery 21 or the secondary battery 22 is connected and the charging terminal 24 is connected to the jack of the AC / DC converter. That is, the cutting circuit 25
Is connected to the charging terminal 24 by the power supply control circuit 28.
When the converter jack is connected, it is in the ON state, and the voltage applied to the charging terminal 24 is applied to the battery terminal 23. At this time, the current flowing from the charging terminal 24 to the battery terminal 23 is rectified by the rectifying element 31. Here, the voltage detection circuit 26 detects the first voltage applied from the charging terminal 24, and supplies a first voltage signal corresponding to the first voltage to the power supply control circuit 28. Thereafter, the power supply control circuit 28 turns off the disconnection circuit 25, and the voltage detection circuit 26 detects the second voltage of the battery terminal 23 to which no voltage is applied by the charging terminal 24, and this second voltage is detected. A second voltage signal corresponding to the voltage is supplied to the power supply control circuit. Then, the power control circuit 28
Subtracts the second voltage signal from the first voltage signal to calculate the voltage when the voltage of the charging terminal 24 is applied to the battery terminal 23 and the voltage when the voltage of the charging terminal 24 is not applied to the battery terminal 23 Is calculated. When the voltage change amount ΔV is larger than the voltage change amount ΔV _B of the primary battery 21, the power supply control circuit 28 determines that the battery connected to the battery terminal 23 is a primary battery, turns off the disconnection circuit 25, As described above, the primary battery 21 is prevented from being charged. Therefore, when the cutting circuit 25 is off, DC / D
The C converter 27 and the output terminal 29 include a battery terminal 23
The voltage of the primary battery 21 connected to is applied.

The above-described optical disk reproducing apparatus 1 operates as follows when reproducing the information signal recorded on the optical disk 2. That is, when a playback start button constituting the operation unit 19 is pressed, a playback start signal is input to the main controller 18 and the main controller 18
The servo circuit 16 and the drive circuit 17 are controlled based on the reproduction start signal to drive the optical pickup 11. Then, the optical pickup 11 emits a light beam from the semiconductor laser, irradiates the signal recording surface of the optical disk 2 with the light beam, and detects the return light beam reflected by the signal recording surface of the optical disk 2 with the photodetector. Then, an information signal is read. Then, the photodetector of the optical pickup 11 converts the irradiated light beam into an electric signal, and supplies the electric signal to the RF amplifier 12. Then, the RF amplifier 12 generates an RF signal, a focus error signal, and a tracking error signal based on the output signal from the photodetector, supplies the RF signal to the signal processing circuit 13, and outputs the focus error signal and the tracking error signal. Is supplied to the servo circuit 16. The signal processing circuit 13 detects and corrects a code error in the RF signal with the error detection and correction circuit, converts the error-corrected RF signal into an analog signal with an A / D conversion circuit, generates a reproduced signal, and 14. Then, the reproduction signal amplified by the amplifier 14 is amplified by the amplifier 14 and output from the output device 15 such as an earphone, a headphone, and a speaker.

At the same time, the servo circuit 16 to which the focus error signal and the tracking error signal generated by the RF amplifier 12 are supplied, sets the focusing servo signal and the tracking servo signal so that the focus error signal and the tracking error signal become zero. Produces
It is supplied to the drive circuit 17. The drive circuit 17 drives the biaxial actuator based on the focusing servo signal, and the objective lens is driven and displaced by the biaxial actuator in a focusing direction parallel to the optical axis of the objective lens. The drive circuit 17 drives the biaxial actuator based on the tracking servo signal, and the objective lens is driven and displaced by the biaxial actuator in a tracking direction orthogonal to the optical axis of the objective lens. As a result, the optical pickup 11 performs focusing and tracking control, and can reliably read out information signals.

When the information signal recorded on the optical disk 10 is reproduced as described above, the power supply circuit 26 operates as follows, and supplies power to each circuit for reproducing the optical disk 10. I do. First, the primary battery 21 or the secondary battery 22 is connected to the battery terminal 23, and the jack of the AC / DC converter is not connected to the charging terminal 24, for example, when the user uses the optical disc reproducing apparatus 1 while carrying it. At this time, as shown in FIG.
Detects that the jack of the AC / DC converter is not connected to the charging terminal 24, and turns off the switching circuit 25. Therefore, the primary battery 21 or the secondary battery 22
Is connected to the output terminal 29 connected to the positive terminal 23a of the battery terminal 23 and the DC / D
It is applied to the C converter 27. Then, DC / DC converter 27 converts the input voltage applied from the battery terminal 23 to a predetermined voltage V _CC2, voltage V _CC2 to the output terminal 32
Is applied. Thus the output terminal 29 and 32 by a predetermined voltage V _cc1, V _cc2 is applied, the reproduction system circuit described above is driven.

When the primary battery 21 or the secondary battery 22 is not connected to the battery terminal 23 and the jack of the AC / DC converter is connected to the charging terminal 24, as shown in FIG. The voltage is applied to the power supply control circuit 28, and the power supply control circuit 28
The connection of the jack of the C converter is detected, and the disconnection circuit 25 is turned on so that a voltage can be applied from the charging terminal 24 to the DC / DC converter 27 and the output terminal 29. Then, the voltage of the charging terminal 24 becomes DC / DC
The current applied to the converter 27 and the output terminal 29 and flowing from the charging terminal 24 is rectified by the rectifying element 31 so that the DC / D
It is supplied to the C converter 27 and the output terminal 29. Then, DC / DC converter 27 converts the input voltage applied from the battery terminal 23 to a predetermined voltage V _CC2, applies a voltage V _CC2 to the output terminal 32. And the output terminal 2
9, 32 in that the predetermined voltage V _cc1, V _cc2 is applied,
Each of the above-described reproduction system circuits is driven.

The secondary battery 22 is connected to the battery terminal 23 when the secondary battery 22 is charged.
When the jack of the AC / DC converter is also connected to the power supply 4, the power supply control circuit 28 determines the battery connected to the battery terminal 23 as shown in FIG. 7, and the primary battery 21 is connected to the battery terminal 23. In this case, a voltage for charging is not applied to the primary battery 21 from the charging terminal 24.

That is, in step S1, when the power supply control circuit 28 detects that the jack of the AC / DC converter is connected to the charging terminal 24, the power supply control circuit 28 turns on the disconnecting circuit 25 and connects the charging terminal 24 to the battery terminal 23. Charging is started by applying a voltage.

In step S2, when the charging current rectified by the rectifying element 31 is supplied to the battery terminal 23, the power supply control circuit 28 determines in step S3 from the start of charging to the maximum voltage of the battery terminal 23. Determine if time has elapsed. Then, when the predetermined time has elapsed, the power control circuit 28 proceeds to step S4, and when the predetermined time has not elapsed, returns to step S2.

In step S4, the power supply control circuit 28
Determines whether the voltage of the battery terminal 23 detected by the voltage detection circuit 26 is greater than 1.55V. That is, the initial voltage of the unused primary battery 21 is 1.55 V as described above, and the power supply control circuit 28
In the above case, it is determined that the primary battery 21 is connected to the battery contact 23, the process proceeds to step S18 shown in FIG. 8, and charging is stopped. If the voltage is less than 1.55V, the process proceeds to step S5.

In step S5, the power supply control circuit 28
Calculates the voltage increase rate Y of the battery terminal 23 until the predetermined time elapses in step S3, and proceeds to step S6.

In step S6, the power supply control circuit 28
Is the voltage rise rate X for the primary battery 21 in which the voltage rise rate Y calculated in step S6 is stored in advance as a threshold.
Determine if it is less than. Then, the voltage control circuit 28
When the detected voltage rise rate Y is smaller than the voltage rise rate X of the primary battery 21, the process proceeds to step S11 shown in FIG. 8, and when the detected voltage rise rate Y is larger than the voltage rise rate X of the primary battery 21. Then, the process proceeds to step S19 shown in FIG. 7, and charging is stopped.

As described above, the power supply control circuit 28 determines whether the voltage increase rate Y between the terminals of the secondary battery 22 when the charging voltage is applied to the secondary battery 22 is the same as when the voltage is applied to the primary battery 21. The type of the battery connected to the battery terminal 23 is determined on the basis of the smaller voltage increase rate X of the primary battery 21. Incidentally, in addition to a small difference between the voltage rise rate X of the primary battery 21 and the voltage rise rate Y of the secondary battery 22, the primary battery 21 includes a plurality of types such as a manganese battery and an alkaline battery. As shown in FIG. 5, the voltage characteristics between terminals when a voltage is applied when not used and when used are greatly different, so that it is possible to accurately determine the type of the battery connected to the battery terminal 23. There are things you can't do. Therefore, the power supply control circuit 28 further determines the type of the battery connected to the battery terminal 23 as follows.

As shown in FIG. 8, following step S6, the power supply control circuit 28 turns on the disconnection circuit 25 detected by the voltage detection circuit 26 in step S11 after a predetermined time has elapsed in step S3. At this time, a first voltage signal indicating the first voltage of the battery terminal 23 is supplied, and the first voltage signal V (1) is stored and held.

In step S12, the power supply control circuit 2
8 is a time period from the start of charging to the stop of charging, for example, it is determined whether 1 minute has elapsed, and when a predetermined time has elapsed,
The process proceeds to step S13, and if the predetermined time has not elapsed, the process returns to step S11.

In step S13, the power supply control circuit 2
8 stops charging. That is, the power supply control circuit 28
Turns off the disconnection circuit 25 so that the voltage of the charging terminal 24 is not applied to the battery terminal 23.

In step S14, the power supply control circuit 2
8 is from 5 seconds to 10 seconds until the voltage of the battery terminal 23 is stabilized after the application of the voltage to the battery terminal 23 is stopped.
The state where the disconnection circuit 25 is turned off for a second, that is, the charging stop state is maintained.

In step S15, the power supply control circuit 2
8, a second voltage signal indicating the second voltage of the battery terminal 23 when the disconnection circuit 25 detected by the voltage detection circuit 26 is off is supplied, and the second voltage signal V (2) is Remember.

In step S16, the power supply control circuit 2
8 is a first voltage signal V (1) indicating the first voltage of the battery terminal 23 when the disconnection circuit 25 stored in step S11 is on, and a battery when the disconnection circuit 25 stored in step S15 is off. The second voltage signal V (2) indicating the second voltage at the terminal 23 is subtracted to calculate a voltage change amount ΔV.
Here, the secondary battery 22, the voltage variation [Delta] V _R primary battery 21 is less than. Therefore, after the voltage has risen most in step S3, the voltage control circuit 28 executes step S1.
By detecting the first voltage of the battery terminal 23 when the disconnection circuit 25 in 1 is on, and detecting the second voltage at which the disconnection circuit 25 is turned off and the voltage of the battery terminal 23 becomes the lowest in step S14, The voltage change amount ΔV which appears most greatly is calculated, and the voltage change amount ΔV is accurately calculated even when the secondary battery 22 having the small voltage change amount is connected to the battery terminal 23.

In step S17, power supply control circuit 2
Reference numeral 8 denotes a voltage change between a terminal voltage when a voltage is applied so as to charge the primary battery 21 stored in advance and a terminal voltage when a voltage for charging is not applied. ΔV voltage change amount ΔV calculated at step S16 from the _B Do the judges large. And the power control circuit 2
In step 8, when the voltage change amount ΔV is larger than the voltage change amount ΔV _B , the process proceeds to step S18. When the voltage change amount ΔV is smaller than the voltage change amount ΔV _B , the process proceeds to step S19.

In step S18, the power supply control circuit 2
8 indicates that the battery connected to the battery terminal 23 is the primary battery 2
It is determined to be 1, and the disconnecting circuit 25 is kept off, so that the state where the voltage of the charging terminal 24 is not applied to the battery terminal 23, that is, the charging stop state. At this time, the power source of the optical disk reproducing apparatus is the primary battery 21 or the secondary battery 22 connected to the battery terminal 23, and the DC / DC converter 27 and the output terminal 29 are connected to the primary battery 21 connected to the battery terminal 23. Is applied. Then, a predetermined voltage V _CC1 is applied to the output terminal 29 and D
By applying the predetermined voltage V _cc2 converted by the C / DC converter 27, each of the above-mentioned reproduction system circuits is driven.

In step S19, the power supply control circuit 28 determines that the battery connected to the battery terminal 23 is the secondary battery 22, turns on the disconnection circuit 25, and continues charging the secondary battery 22. I do. At the same time, the voltage of the charging terminal 24 is applied to the DC / DC converter 27 and the output terminal 29, and the current from the charging terminal 24 is rectified by the rectifying element 31 and supplied to the DC / DC converter 27 and the output terminal 29. Is done. Then, DC / DC converter 27 converts the input voltage applied from the battery terminal 23 to a predetermined voltage V _CC2, applies a voltage V _CC2 to the output terminal 32. Then, the output terminal 29 and 32 by a predetermined voltage V _cc1, V _cc2 is applied, the reproduction system circuit described above is driven.

As described above, the power supply control circuit 28 first determines that the voltage increase rate when the primary battery 21 is connected to the battery terminal 23 is different from that when the secondary battery 22 is connected to the battery terminal 23. It is determined whether the battery connected to the battery terminal 23 is the primary battery 21 or the secondary battery 22 based on whether the primary battery 21 is connected to the battery terminal 23 or the secondary battery 22 It is determined whether the battery connected to the battery terminal 23 is the primary battery 21 or the secondary battery 22 based on the difference in voltage change when the battery is connected to the terminal 23. Since the identification is performed, the type of the battery connected to the battery terminal 23 can be reliably determined. The power supply control circuit 28
Uses the voltage increase rate X of the primary battery 21 as a threshold when determining the difference between the voltage increase rates of the primary battery 21 and the secondary battery 22 shown in FIG. When the difference in the voltage change amount of the battery 22 is determined, since the voltage change amount ΔV _B of the primary battery 21 is used as a threshold, it is possible to reliably prevent the primary battery 21 from being charged. Further, based on the difference in voltage change between the primary battery 21 and the secondary battery 22 shown in FIG.
In the step of determining the type of the connected battery 3, since the difference between the voltage variation [Delta] V _R of voltage change amount in the case of a primary battery 21 [Delta] V _B and the secondary battery 22 is large, the kind of reliable battery Can be determined. Thus, battery terminal 2
In the optical disc reproducing apparatus 1 including the power supply circuit 20 that can reliably identify the type of the battery connected to the primary battery 3, the primary battery 12 can be reliably prevented from being charged. It is possible to prevent the primary battery 21 from leaking due to erroneous charging of the battery 21.

The step of determining the type of the battery connected to the battery terminal 23 based on the difference in the voltage change between the primary battery 21 and the secondary battery 22 shown in FIG. 8 can also be performed as follows. . That is, following step S6 described above, as shown in FIG. 9, in step S21, the power supply control circuit 28 stops charging. That is, the power supply control circuit 28 turns off the disconnection circuit 25 and
Is not applied to the battery terminal 23.

In step S22, the power supply control circuit 2
8 is from 5 seconds to 10 seconds until the voltage of the battery terminal 23 is stabilized after the application of the voltage to the battery terminal 23 is stopped.
The state where the disconnection circuit 25 is turned off for a second, that is, the charging stop state is maintained.

In step S23, the power supply control circuit 2
8 is supplied with a third voltage signal indicating the third voltage of the battery terminal 23 when the disconnection circuit 25 detected by the voltage detection circuit 26 is off, and this third voltage signal V (3) is Remember.

In step S24, the power supply control circuit 2
8 turns on the cutting circuit 25 and applies the voltage of the charging terminal 24 to the battery terminal 23 to restart charging.

In step S25, the power supply control circuit 2
8 is supplied with a fourth voltage signal indicating the fourth voltage of the battery terminal 23 when the disconnection circuit 25 detected by the voltage detection circuit 26 is on, and the fourth voltage signal V (4) is Remember.

In step S26, power supply control circuit 2
8 is the fourth terminal of the battery terminal 23 when the disconnection circuit 25 is on.
Circuit 25 from the fourth voltage signal V (4)
The third voltage signal V (3) indicating the third voltage of the battery terminal 23 when is turned off is subtracted to calculate a voltage change amount ΔV.

In step S27, the power supply control circuit 2
Reference numeral 8 denotes a voltage change between a terminal voltage when a voltage is applied so as to charge the primary battery 21 stored in advance and a terminal voltage when a voltage for charging is not applied. ΔV voltage change amount ΔV calculated in step S26 from the _B Do the judges large. And the power control circuit 2
8, when the voltage change amount ΔV is larger than the voltage change amount ΔV _B , the process proceeds to step S28, and when the voltage change amount ΔV is smaller than the voltage change amount ΔV _B , the process proceeds to step S29.

In step S28, the power supply control circuit 2
8 indicates that the battery connected to the battery terminal 23 is the primary battery 2
It is determined that the value is 1, the disconnection circuit 25 is turned off, and the state where the voltage of the charging terminal 24 is not applied to the battery terminal 23, that is, the charging stop state is set. The primary battery 21 connected to the battery terminal 23 applies a predetermined voltage V _CC1 to the output terminal 29 and applies DC / DC to the output terminal 32.
By applying the predetermined voltage V _cc2 converted by the converter 27, each of the above-described reproduction circuits is driven.

In step S29, power supply control circuit 2
8 indicates that the battery connected to the battery terminal 23 is the secondary battery 2
2, the disconnection circuit 25 is kept on, and the charging of the secondary battery 22 is continued. At the same time, the AC / DC converter connected to the charging terminal 24
When the predetermined voltage V _CC1 is applied to the output terminal 29 and the predetermined voltage V _CC2 converted by the DC / DC converter 27 is applied to the output terminal 32, each of the above-described reproduction circuits is driven.

That is, in the step of judging the type of the battery connected to the battery terminal 23 based on the difference in the voltage change between the primary battery 21 and the secondary battery 22 shown in FIG. By detecting the third voltage, and then detecting the fourth voltage of the battery terminal 24 when charging is resumed, the voltage change amount ΔV of the battery connected to the battery terminal 23 is calculated, and this voltage change is calculated. It is determined whether the amount ΔV is greater than the voltage change amount ΔV _B of the primary battery 21 that is a threshold, and the type of the battery connected to the battery terminal 23 is determined. Also in this step, as in the step shown in FIG. 8, the voltage change amount ΔV _{B in} the case of the primary battery 21 is used.
When since the difference between the voltage variation [Delta] V _R of the secondary battery 22 is large, it is possible to determine the type of reliably battery.

As described above, the power supply circuit 2 of the optical disc reproducing apparatus 1
0 describes a case where the voltage increase rate and the amount of voltage change of the primary battery 21 are used as thresholds when determining whether the battery connected to the battery terminal 23 is the primary battery 21 or the secondary battery 22. However, the present invention may use the rate of voltage rise and the amount of voltage change of the secondary battery 22 as the threshold.
In this case, the power supply control circuit 28 stores the voltage increase rate of the secondary battery 22 in which the voltage increase rate of the battery terminal 23 generated by the power supply control circuit 28 based on the voltage signal detected by the voltage detection circuit 26 is stored in advance. If it is larger, it is determined that the battery connected to the battery terminal 23 is the primary battery 21, and the voltage of the battery terminal 23 generated by the power control circuit 28 based on the voltage signal detected by the voltage detection circuit 26 When the change is larger than the previously stored voltage change of the secondary battery 22, it is determined that the battery connected to the battery terminal 23 is the primary battery 21.

In the above, the case where the power supply control circuit 28 detects the type of battery based on the rate of voltage increase and further determines the type of battery based on the amount of change in voltage has been described. Instead of detecting the difference, the type of the battery may be determined based only on the difference in the amount of voltage change as shown in FIGS.

The case where the present invention is applied to the power supply circuit 20 of the optical disk reproducing apparatus 1 has been described above. However, the present invention is not limited to this, and the present invention is not limited to this. The present invention can be applied to a power supply circuit of a portable electronic device such as a recording and / or reproducing device of a type or a portable video camera device.

[0066]

According to the present invention, the power supply control circuit turns on the disconnection circuit, and when the voltage from the second terminal is applied, the first voltage detected by the voltage detection circuit of the first terminal. A voltage change between the voltage and the second voltage at the first terminal when the voltage from the second terminal is not applied to the first terminal is calculated, and the first terminal is connected to the first terminal based on the voltage change. When the type of the connected battery is determined and the battery connected to the first terminal is determined to be a primary battery, the disconnection circuit is turned off, thereby applying a charging voltage to the primary battery. This can be reliably prevented.

[Brief description of the drawings]

FIG. 1 is a block diagram of an optical disk reproducing device.

FIG. 2 is a block diagram of a power supply circuit.

FIG. 3 is a diagram for explaining a voltage change amount when a charging voltage is applied to a primary battery and when a charging voltage is not applied.

FIG. 4 is a diagram for explaining voltage change amounts when a charging voltage is applied to a secondary battery and when a charging voltage is not applied.

FIG. 5 is a diagram for explaining an amount of voltage change between an unused primary battery and a used primary battery.

FIG. 6 is a diagram for explaining a voltage change amount of a primary battery when a charging current is varied.

FIG. 7 is a flowchart for explaining a step of detecting a voltage rise rate of a battery terminal and determining a type of a battery connected to the battery terminal.

FIG. 8 is a flowchart illustrating a step of detecting a voltage change amount of a battery terminal and determining a type of a battery connected to the battery terminal.

FIG. 9 is a flowchart for explaining another example of a step of detecting a voltage change amount of a battery terminal and determining a type of a battery connected to the battery terminal.

[Explanation of symbols]

1 optical disk reproducing device, 10 optical disks, 12 R
F amplifier, 13 signal processing circuit, 14 amplifier, 15
Output device, 16 servo circuit, 17 drive circuit, 18
Main controller, 20 power supply circuit, 21 primary battery, 22 secondary battery, 23 battery terminal, 24 charging terminal, 25 disconnection circuit, 26 voltage detection circuit, 27 DC
/ DC converter, 28 power control circuit, 29 output terminals, 31 rectifier, 32 output terminals

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2G016 CA00 CB11 CB12 CB33 CC01 CC03 CC04 CC12 CC23 CC27 CC28 CD09 5G003 AA01 BA02 CA14 CC02 DA04 GC04 5H030 AA03 AA06 BB01 FF43 FF52

Claims (8)

[Claims] 1. A first battery to which a primary battery or a secondary battery is connected.
A second terminal connected to the first terminal and a voltage applied from the outside, and provided between the first terminal and the second terminal; A disconnection circuit that disconnects the terminal and the second terminal; a voltage detection circuit that detects a voltage of the first terminal to which the primary battery or the secondary battery is connected; and a voltage detection circuit that detects when the disconnection circuit is on. The amount of voltage change between the first voltage of the first terminal detected by the voltage detection circuit and the second voltage of the first terminal detected by the voltage detection circuit when the disconnection circuit is off is calculated. A power supply control circuit for calculating, wherein the power supply control circuit determines a type of a battery connected to the first terminal based on the amount of voltage change, and the battery connected to the first terminal When the primary battery is determined, turn off the disconnection circuit. Charging device according to claim. 2. The power supply control circuit according to claim 1, wherein the voltage change amount is a voltage between terminals when a voltage from the second terminal is applied to the primary battery, and a voltage from the second terminal to the primary battery. When the voltage is larger than the voltage change between the terminals when no voltage is applied, the battery connected to the first terminal is determined to be the primary battery, and the disconnection circuit is turned off. Item 7. The charging device according to Item 1. 3. The charging device according to claim 1, wherein a rectifying element is provided between the first terminal and the disconnection circuit. 4. A first battery connected to a primary battery or a secondary battery.
Applying a voltage from outside to a terminal of the first terminal or the first terminal to which the primary battery or the secondary battery to which the external voltage is applied is connected. Detecting and storing a voltage; disconnecting the first terminal and the second terminal; disconnecting the first terminal and the second terminal; and then disconnecting the primary battery or the secondary battery. The second of the first terminals connected
Detecting and storing the voltage of the battery; calculating the voltage change of the first voltage and the second voltage; and detecting the voltage of the battery connected to the first terminal based on the voltage change. A charging method comprising: determining a type; and disconnecting the first terminal and the second terminal when determining that the primary battery is connected to the first terminal. 5. The voltage change between the first voltage and the second voltage is determined by determining a voltage between terminals when the voltage from the second terminal is applied to the primary battery and the second voltage applied to the primary battery. The battery connected to the first terminal is determined to be the primary battery when the voltage difference between the terminal and the voltage between terminals when no voltage is applied from the terminal is larger than the primary battery. The charging method described. 6. A first battery to which a primary battery or a secondary battery is connected.
A second terminal connected to the first terminal and a voltage applied from the outside, and provided between the first terminal and the second terminal; A disconnection circuit that disconnects the terminal and the second terminal; a voltage detection circuit that detects a voltage of the first terminal to which the primary battery or the secondary battery is connected; a first terminal and the second terminal An output circuit for making different voltages applied by the terminals constant and outputting the same to each circuit; a first voltage of the first terminal detected by the voltage detection circuit when the disconnection circuit is on; and the disconnection circuit And a power supply control circuit for calculating a voltage change amount between the first terminal and the second voltage detected by the voltage detection circuit when the power supply is off, wherein the power supply control circuit calculates a voltage change amount based on the voltage change amount. To determine the type of battery connected to the first terminal, When serial connected to the first terminal battery is determined to be a primary battery the power supply device, characterized in that to turn off the cutting circuit. 7. The power supply control circuit, wherein the voltage change amount is a voltage between terminals when a voltage from the second terminal is applied to the primary battery and a voltage from the second terminal to the primary battery. When the voltage is larger than the voltage change between the terminals when no voltage is applied, the battery connected to the first terminal is determined to be the primary battery, and the disconnection circuit is turned off. Item 7. The power supply device according to Item 6. 8. The power supply device according to claim 6, wherein a rectifying element is provided between the first terminal and the disconnection circuit.