JP2000312439A - Secondary battery protection circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a secondary battery protection circuit, having simple constitution and being stably operated with high accuracy. SOLUTION: In this protection circuit for secondary batteries, in which a plurality of the secondary batteries are connected in series and high battery voltage corresponding to a plurality of the secondary batteries is formed, a plurality of MOSFETs are connected in series, and voltage applied to each gate insulating film is shared mutually in a current-voltage conversion circuit, a current signal corresponding to the battery voltage is formed, the plurality of the MOSFETs in which voltage at the interconnecting points of a plurality of the MOSFETs connected in series is applied to gates are used in a voltage relaxing circuit, a current formed in the current-voltage conversion circuit is transmitted, sharing the voltage applied to each gate insulating film mutually, the current signal is converted into the voltage signal of the low voltage of the gate breakdown voltage or smaller of the MOSFETs in the current-voltage conversion circuit, and voltage passed through the current-voltage conversion circuit is measured, and at least one of either of the overvoltage state or overdischarged state of the secondary battery is detected.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a secondary battery protection circuit, and more particularly to a technique effective as a protection circuit for overcharge and overdischarge, which is used in a battery mounted together with a lithium (Li) ion battery in a battery pack. It is.

[0002]

2. Description of the Related Art As a secondary battery used in portable electronic equipment, there is a Li-ion secondary battery. It is said that the charging voltage of this Li-ion secondary battery must not be higher than 4.1 V or 4.2 V, and if overcharging is performed more than this, metal Li will precipitate and lead to an accident. Further, when overdischarge is performed, the number of times of repeated charge / discharge use becomes extremely poor. Therefore, when overcharge or overdischarge is detected, a protection switch including a power MOSFET or the like for separating the battery from the device body is provided. Such a Li-ion secondary battery is described in Nikkei McGraw-Hill, “Nikkei Electronics”, Nov. 20, 1995, pp. 100-117.

[0003]

As the technology of Li-ion secondary batteries advances, it has become possible to increase the upper limit charging voltage to about 4.5V. Further, it is presumed that the voltage can be increased to about 5V. For example, if four secondary batteries (cells) are connected in series, the voltage can be as high as about 20 V during charging. When such a battery voltage is increased, it is necessary to use a MOSFET whose breakdown voltage is higher than that of a MOSFET that operates with a 5V power supply voltage. Such high voltage MOSFET
In the case of using the device, the size of the element itself increases, and the layout area of the semiconductor integrated circuit increases. As described above, in addition to the increase in size, when an operational amplifier for a voltage comparison operation is constituted by a high-breakdown-voltage MOSFET, the high-breakdown-voltage M
It is difficult to ensure the pair property of the OSFET, and the offset of the operational amplifier itself becomes large, which causes a problem that the measurement accuracy is deteriorated.

An object of the present invention is to provide a secondary battery protection circuit which has a simple structure and operates stably with high accuracy. The above and other objects and novel features of the present invention will become apparent from the description of the present specification and the accompanying drawings.

[0005]

The following is a brief description of an outline of a typical invention among the inventions disclosed in the present application. That is, a secondary battery protection circuit that connects a plurality of secondary batteries in series to form a high battery voltage corresponding to the plurality of secondary batteries, and includes a plurality of MOSFETs in a current-voltage conversion circuit. By connecting in series, the voltage applied to each gate insulating film is mutually shared,
A current signal corresponding to the battery voltage is formed, and the plurality of MOSFEs connected in series in the voltage alleviation circuit.
By using a plurality of MOSFETs each having a gate applied with a voltage at the interconnection point of T, the voltage formed by the voltage-current conversion circuit is transmitted while sharing the voltage applied to each gate insulating film with each other. In the voltage conversion circuit, the current signal is converted into a low-voltage signal equal to or lower than the gate withstand voltage of the MOSFET, and the voltage passed through the current-voltage conversion circuit is measured to determine whether the secondary battery is in the overvoltage state or the overdischarge state. Or at least one is detected.

[0006]

FIG. 1 is a basic circuit diagram of an embodiment of a battery voltage detecting circuit provided in a secondary battery protection circuit according to the present invention. Each circuit element shown in the figure is formed on a single semiconductor substrate such as single crystal silicon together with other circuit elements (not shown) constituting a secondary voltage protection circuit by a known MOS integrated circuit manufacturing technique. In the drawings attached to the present application, a P-channel type MOSF
The ET is distinguished from the N-channel MOSFET by adding an arrow to its channel portion.

The secondary battery in this embodiment is configured to connect four Li-ion batteries in series to obtain a voltage four times higher than the terminal voltage per cell. For each of the terminal voltages V1 to V4 of the cells in the series configuration, two or more cells may be connected in parallel in order to increase the battery capacity.
In this embodiment, the following high voltage of the high battery voltage BAT (+) to BAT (-) including the time of charging is detected while using a so-called normal MOSFET which operates at a power supply voltage of 5V system. Such a contrivance is performed.

The terminal voltages V1 to V4 of the cells are supplied to a semiconductor integrated circuit constituting a secondary battery protection circuit through external terminals P1 to P5, respectively. That is, the terminal P1
Supplies the Masunas voltage BAT (−) of the secondary battery and is input as the reference voltage VSS of the protection circuit. The terminal P5 is connected to the positive voltage BAT of the secondary battery.
(+), And a voltage V added by connecting the above four cells in series between the terminals P1 and P5.
A high voltage such as 1 + V2 + V3 + V4 is applied.

In this embodiment, in addition to the high voltage as described above, each cell voltage is inputted through terminals P2 to P4, and each of the voltages V1, V2, V3 and V4 of each cell is charged. Sometimes only up to 5V. That is,
In the case of individual cells, voltage detection can be performed using a MOSFET that operates with the 5V power supply voltage. Therefore, in this embodiment, voltage detection is performed for each individual cell.

At terminals P5 and P4, a voltage-current conversion circuit for a cell corresponding to voltage V4 is provided. This voltage-current conversion circuit includes a series circuit of diode-type P-channel MOSFETs Q1 and Q2 having a gate and a drain connected to each other, and a source and a gate connected to the positive voltage MOSFET Q1 of the two MOSFETs Q1 and Q2. And a P-channel type current output MOSFET Q3. Each of the MOSFETs Q1 to Q3 is formed in an electrically independent well region.
Each well region (substrate gate) is connected to the source so that it is not affected by the substrate effect. .

The above two MOSFETs Q1 and Q2 are:
It is composed of MOSFETs of the same size. Therefore,
In the series circuit of the MOSFETs Q1 and Q2, the same current flows by forming a voltage obtained by dividing the voltage V4 by ず つ. The MOSFET Q3 is also formed of the same size MOSFET as the MOSFETs Q1 and Q2. This M
The source and gate of OSFET Q3 are
Q1 is connected to the source and the gate, respectively,
Since the ETQ1 is in the form of a current mirror, the same current as the current flowing through the MOSFET Q1 is output from the drain.

The drain voltage of the MOSFET Q3 is
As seen from the terminal P4, the voltage becomes as small as V4 / 2 as described above. However, the negative voltage BAT of the secondary battery is used as a reference voltage for a circuit receiving the drain current.
If (-) is set, there is no change in the high voltage obtained by adding the voltages V1 to V3. Therefore, the MOSFET Q3 is also
The following voltage mitigation circuit is provided in order to prevent the gate insulation breakdown while using a standard MOSFET equivalent to the SFETs Q1 and Q2.

The voltage relaxation circuit utilizes the cell voltages V3 to V1 supplied from the terminals P4 to P2. That is, MOSFETs Q4, Q5, and Q6 to which the voltages of the terminals P4, P3, and P2 are respectively supplied are provided, and these MOSFETs Q4 to Q6 are connected to the output MOSFETs.
Connected in series to FET Q3. Thereby, MOSFET
The drain voltage of Q3 is substantially equal to the drain voltage of MOSFET Q1,
The cell voltage V3,
Only voltages obtained by subtracting the respective threshold voltages from V2 and V1 are applied, and the normal MOSFET as described above is applied.
Does not damage the gate insulating film.

The above operation will be described quantitatively as follows. The MOS size (W) of the MOSFETs Q1 and Q2
/ L), and each source-drain current I
Since DS is the same, the respective gate-source voltages VGS are also equal. Therefore, MOSFET Q3
Is V1 + V2 + V3 + V4 / 2,
The gate-source voltage VGS (VgsQ3) is V4 /
It becomes 2.

When the voltage of the voltage V4 / 2 is equal to the voltage of the MOSFET Q
1. When the voltage is larger than the threshold voltage of Q2, MOSFE
The drain current of TQ3 is equal to the source of MOSFET Q3.
It is determined by the drain current IDS (IdsQ3) and is obtained by the following equation (1) when operating in the saturation region. IdsQ3 = 1/2 · μCox (W / L) (VgsQ3−VthQ3) ² (1)

Assuming that the MOSFET Q4 of the voltage relaxation circuit operates in the saturation region, the current I
dsQ4 is obtained by the following equation (2). Similarly, MOS
FETs Q5 and Q6 are also obtained by the following equations (3) and (4). IdsQ4 = IdsQ3 = 1 / 2.mu.Cox (W / L) (VgsQ4-VthQ4) ^2. (2) IdsQ5 = IdsQ3 = 1 / 2.mu.Cox (W / L) (VgsQ5-VthQ5) ^2. (3) IdsQ3 = 1 / 2.mu.Cox (W / L) (VgsQ6-VthQ6) ^2. (4)

From the above equation (2), Vgs of MOSFET 4 is obtained.
Q4 is given by the following equation (5). From this equation (5), VgsQ4 ≒ VthQ4 is obtained by increasing W / L. The same applies to VgsQ5 and VthQ5, and VgsQ6 and VthQ6. VgsQ4 = √ [(2 · IdsQ3) / (μCox (W / L))] + VthQ4 (5)

Therefore, in the voltage relaxation circuit, MOSF
The drain voltages of ETQ4 to ETQ6 are cell voltages V3 and V3.
2. Since the voltages correspond to V1 and the voltages are shared, the gate dielectric breakdown can be prevented as described above.

The drain of the terminal MOSFET Q6 is connected to the source of a MOSFET Q7 constituting a voltage-current conversion circuit. A gate and a drain of the MOSFET Q7 are supplied with a reference voltage from a terminal P1 to which a minus voltage BAT (−) of the secondary battery is connected. MOS above
The FET Q7 has the same size as the MOSFET Q1.
An OSFET is formed, and a gate and a drain are connected to the reference voltage. Therefore, the output MOS
The current formed by the FET Q3 is a MOSFET for voltage relaxation.
It is supplied to MOSFET Q7 through TQ4 to Q6.

Since the currents flowing through the MOSFETs Q1 and Q3 are equal as described above, the same current flows through the MOSFET Q7 as the MOSFET Q1 and a voltage of V4 / 2 is formed at both ends of the MOSFET Q7. That is, the voltage V4 at the terminals P5 and P4 is converted to a low voltage such as V4 / 2 with respect to the reference voltage.

For the cell voltage V3 between the terminals P4 and P3, the cell voltage V2 between the terminals P3 and P2, and the cell voltage V1 between the terminals P2 and P1, the MOSFETs Q to Q3 are also used.
A voltage-current conversion circuit similar to that described above is provided. Since the voltage V1 is based on the minus voltage BAT (−) of the secondary battery as a reference voltage, M
The OSFET is directly connected to a MOSFET similar to the MOSFET Q7 constituting the current-voltage conversion circuit.
The output MOSFETs of the other voltage-to-current conversion circuits are respectively connected to the same MOSFETs as the MOSFET Q7 constituting the current-to-voltage conversion circuit via two or one similar voltage-reducing MOSFETs corresponding to the respective voltages. Connected.

In the above current-voltage conversion circuit, each cell voltage V
A voltage V1 / 2 to V4 / 2 of 1/2 of V1 to V4 is formed, one of which is selected by a battery selection circuit and supplied to a voltage doubling circuit, and an analog voltage corresponding to the above voltages V1 to V4 Is output as The battery selection circuit is for sequentially switching and outputting each of the voltages V1 / 2 to V4 / 2, and the voltage doubling circuit doubles and outputs the sequentially switched voltage. The output analog voltage is compared with a predetermined voltage by a voltage comparison circuit, which will be described later, to form a control signal for a protection circuit so as not to be in an overcharged state or an overdischarged state.

The voltage doubling circuit is for making each voltage correspond to the cell voltages V1 to V4, taking into consideration the improvement of usability, and is not essential. Although the protection circuit including the voltage doubling circuit is not particularly limited, the protection circuit can be configured by an amplifier circuit using an operational amplifier with a voltage gain set to double. The operating voltage of such a battery selection circuit and a voltage doubling circuit is a low voltage such as about 5V. The voltage of the plus voltage BAT (+) is supplied to an internal step-down circuit.
A low voltage internally reduced like the above-mentioned about 5V is formed.

In this embodiment, since an overcharge state or an overdischarge state is detected for each cell in the series form, a highly reliable protection operation can be realized. That is, when a plurality of secondary battery cells are connected in series, charging and discharging are not performed uniformly for each cell. For example, in a discharging operation, the negative voltage BAT of the secondary battery is used.
It is known that the decrease is larger in the order of cells V1 to V4 closer to (−). By detecting such a voltage of each cell, a highly reliable protection operation can be realized.

In this embodiment, three parallel-connected MOSFETs Q10 to Q12 are connected as dummy loads between terminals P5 and P4 corresponding to the cell forming the voltage V4 as a circuit for reducing battery depletion as described above. , Two parallel-connected MOSFETs Q20 and Q21 are connected as dummy loads between the terminals P4 and P3 corresponding to the cell forming the voltage V3, and a dummy load is connected between the terminals P3 and P2 corresponding to the cell forming the voltage V2. One MOSFET Q30 is connected so as to match the discharge of cells forming the voltages V1 to V4.

FIG. 2 is a specific circuit diagram of one embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention. In this embodiment, each of the terminals P1 to P1 is considered in consideration of the battery voltage detection operation in an actual semiconductor integrated circuit.
Resistors R5 to R1 for preventing electrostatic breakdown of the MOSFET connected to P5 are connected to P5. An activation circuit is provided for controlling the validity / invalidity of the operation of the battery voltage detection circuit. Then, there are provided resistors R6 to R9 for flowing a leak current so as to operate stably even when the cell voltages V1 to V4 decrease. Another configuration is shown in FIG.
Is omitted because it is the same as the circuit shown in FIG.

Each of the protection resistors R1 to R5 is formed of a diffusion resistor or a polysilicon resistor and has a resistance value of about 1 KΩ, and the secondary battery protection circuit is formed together with its parasitic diode in the semiconductor integrated circuit device. This is to form a discharge path of static electricity due to assembling on a mounting board or handling during transportation or the like.

The above-mentioned activating circuit comprises a high-voltage MOSFET.
MOSF composed of Q8 and Q9 and constituting a voltage dividing circuit
The voltage supplied to the gate of ETQ2 is switched. That is, M is determined by the low level (BAT (−)) of the signal / C1.
When OSFET Q8 is turned on, MOSFET Q
The gate of No. 2 is supplied with a drain-side voltage, is in the form of a diode as described above, and operates as a voltage dividing circuit. On the other hand, the high level of the signal / C (BAT)
When the MOSFET Q8 is turned off by (+)) and the MOSFET Q9 is turned on by the low level of the signal C, the gate voltage of the MOSFET Q2 becomes MOS
The MOS becomes equal to the source voltage of the FET Q1,
The FET Q2 is turned off.

As a result, the above cell voltage V4 is set to 1
The voltage dividing operation of dividing the voltage by 2 is stopped, and the current consumption from the terminal P5 including the output MOSFET Q3 is stopped. Similarly, the leakage current in the one-side reduction countermeasure circuit is also stopped. Although this activation circuit is a high-voltage MOSFET operated by the control signals / C and C of BAT (+) to BAT (-) as described above, since it is used as a simple switch, it has the above-mentioned pair characteristics. There is no problem even if there is a variation.

The resistors R6 to R9 are connected to the voltages V4 to V
1 to reduce the voltage applied between the gate and the source of the MOSFET Q7 and the like, thereby preventing the operation of the circuit from becoming unstable. The operation of the voltage relaxation circuit, the current-voltage conversion circuit, and the like is stabilized, and the resistance value is set to a high value that does not affect the accuracy. A detection resistor having a small resistance value of about 20 mΩ is inserted into the negative voltage BAT (−) of the secondary battery, and is used for detecting a discharge current or a charge current. Due to the current flowing through the detection resistor, the voltages V1 to V4 viewed from the BAT (-) appear to fluctuate. However, if the fluctuation width is within the threshold voltage (Vf) of the PN junction, the measurement accuracy is not affected. No problem without giving.

FIG. 3 is a specific circuit diagram of another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention. This embodiment is a modification of the circuit of the embodiment shown in FIG. 2, and each of the MOSFETs constituting the voltage-current conversion circuit, the current relaxation circuit, the current-voltage conversion circuit, and the battery reduction circuit has a low threshold. A value voltage is used. The circuit itself is the same as that of the embodiment of FIG. 2, and a description thereof will be omitted. In this embodiment, since the threshold voltage of the MOSFET to be used is lowered, it is possible to perform highly accurate measurement even when the battery voltages V1 to V4 are low.

FIG. 4 is a specific circuit diagram of another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention. This embodiment is a modification of the circuit of the embodiment shown in FIG. 2, and differs from the first embodiment in a voltage-current conversion circuit, a current relaxation circuit, and a current-voltage conversion circuit.

The voltage-current conversion circuit of this embodiment is composed of two MOSFETs Q1 and Q2. That is, the MOSFET Q3 of the embodiment of FIG. 2 is omitted. It is designed to take out the current flowing through the MOSFETs Q1 and Q2 directly as a detection current. In order to take out the current flowing through the MOSFETs Q1 and Q2 constituting the voltage dividing circuit, the MOSFET of the voltage relaxation circuit
4 are combined. The MOSFET Q4 is a MOSFET with a low threshold voltage, a voltage corresponding to the terminal P4 is applied to its gate, and its source is
Connected to the drain of OSFET Q2.

In the embodiment of FIG. 2, when the voltage-current conversion circuit is activated by the activation circuit, the MOS
The voltage from the terminal P4 is supplied to both the gate and the drain of the FET Q2.
The voltage of the terminal P4 is supplied to the gate of the MOSF, and the voltage of the terminal P4 is supplied to the drain of the MOSF which constitutes the voltage relaxation circuit.
ETQ4 is supplied after being level-shifted by a low threshold voltage between the gate and source of ETQ4. By setting the MOSFET Q4 to a low threshold voltage, a decrease in the source-drain voltage of the MOSFET can be suppressed to a small value.
As a result, the same operation as the MOSFETs Q1 and Q2 in FIG. 2 can be performed. Thereby, MOSFET
The current formed by the series circuit of Q1 and Q2 is MOSFE
Through TQ4, another MOSFET Q5 for voltage relaxation,
It is transmitted to the current-voltage conversion circuit described below through Q6.

The voltage-current conversion circuits provided corresponding to the other cell voltages V3, V2, etc. are also provided with the MOSFETs Q1 and Q2 provided for the cell voltage V4 and the MOSFET Q for voltage relaxation.
4 is used. Since the cell voltage V1 does not require the voltage relaxation MOSFET as described above, it is directly transmitted to the next current-voltage conversion circuit.

The current-to-voltage converter of this embodiment is a MOSF as a circuit for forming a voltage corresponding to the voltage V4.
It comprises ETQ40-Q45. MOSFET Q4
0 and Q41 are N-channel MOSFETs, and constitute a current mirror circuit. The MOSFETs Q1 and Q2
And the current i formed by the internal voltage down converter through the current mirror circuit.
Is supplied to MOSFETs Q42 and Q43 of a P-channel type current mirror circuit whose source is applied to the P-channel type MOSFETs Q44 and Q45 through the current mirror MOSFETs Q42 and Q43. . These MOSFET Q4
4 and Q45 have the same size as the MOSFETs Q1 and Q2, and the gate and drain are also connected, respectively. As a result, the same voltage V4 as the cell voltage V4 can be obtained by the MOSFETs Q44 and Q45.

The currents corresponding to the other cell voltages V3, V2, and V1 can also form the same voltages V3, V2, and V1 by the same current-voltage conversion circuit as the MOSFETs Q40 to Q45. These conversion voltages V1
To V4 are analog output through a battery selection circuit. In this embodiment, the voltage doubling circuit as shown in FIG. 2 or 3 can be omitted.

FIG. 5 is a specific circuit diagram of another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention. This embodiment is a modification of the circuit of the embodiment shown in FIG. 4 and differs from the circuit of FIG.

The voltage-current converter of this embodiment is constituted by one MOSFET Q2. That is, FIG.
In this embodiment, the MOSFET Q1 is omitted. MOS above
The voltage corresponding to the terminal P5 is applied to the source of the MOSFET Q2 by omitting the FET Q1, and the voltage corresponding to the cell voltage V1 is applied to the source-drain of the MOSFET Q2 by combining the MOSFET of the voltage relaxation circuit with Q4 in the same manner as described above. A current signal is formed. The above MOSFET Q
Reference numeral 4 denotes a MOSFET having a low threshold voltage in the same manner as described above, a voltage corresponding to the terminal P4 is applied to its gate, and its source is connected to the drain of the MOSFET Q2.

In this embodiment, a voltage is supplied between the gate and the source of the MOSFET Q2 by subtracting the cell voltage V4 between the terminals P5 and P4 by the low threshold voltage between the gate and the source of the MOSFET Q4 that constitutes the voltage relaxation circuit. And
Since the low threshold voltage of the MOSFET Q4 can be regarded as a constant voltage, a current corresponding to the cell voltage V4 flows through the MOSFET Q2. Thereby, MOSFET
The current formed by Q2 passes through MOSFET Q4
The voltage is transmitted to the current-to-voltage conversion circuit through other voltage relaxation MOSFETs Q5 and Q6.

The voltage-current conversion circuits provided corresponding to the other cell voltages V3, V2, etc. are also provided with the MOSFETs Q1 and Q2 provided for the cell voltage V4 and the MOSFET Q for voltage relaxation.
4 is used. Since the cell voltage V1 does not require the voltage relaxation MOSFET as described above, it is directly transmitted to the next current-voltage conversion circuit.

The current-voltage conversion circuit of this embodiment is basically the same as the circuit shown in FIG. 4 except that a P-channel MOSFET Q4 through which a current i flows through a current mirror circuit.
5 is provided corresponding to the MOSFET Q2 of the voltage-current conversion circuit. Since the MOSFET Q45 has the same size as the MOSFET Q2, a voltage substantially equal to the cell voltage V4 can be obtained. Strictly, a voltage v4 (V4-Vth) obtained by subtracting the cell voltage V4 from the cell voltage V4 by the low threshold voltage Vth of the MOSFET Q4 of the voltage relaxation circuit is supplied to the MOSFET Q2. Becomes

The currents corresponding to the other cell voltages V3, V2 and V1 are also converted to the same voltage v3 as the cell voltages V3, V2 and V1 by the current / voltage conversion circuit having the same circuit configuration as the MOSFETs Q40 to Q45. , V2 and v1
Can be formed. These converted voltages are
Analog output is made through the battery selection circuit.

FIG. 6 is a specific circuit diagram of another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention. This embodiment is a modification of the circuit of the embodiment shown in FIG. 5, and each of the MOSFETs constituting the voltage-current conversion circuit, the current relaxation circuit, the current-voltage conversion circuit and the battery reduction circuit has a low threshold. A value voltage is used. However, since the N-channel type current mirror circuit and the P-channel type current mirror circuit constituting the current-voltage conversion circuit operate stably at the stepped down voltage of 5 V, the MOSFET having the normal threshold voltage is used.
Is used. Since the circuit itself is the same as that of the embodiment of FIG. 5, its description is omitted. In this example,
Since the threshold voltage of the MOSFET to be used is lowered, it is possible to perform highly accurate measurement even when the battery voltages V1 to V4 are low.

FIG. 7 is a specific circuit diagram of another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention. In this embodiment, a terminal P1 for supplying the mass-nasal voltage BAT (-) of the secondary battery and a positive voltage BAT (+) for the secondary battery are supplied instead of the above-described voltage input for each cell. A terminal P5 is provided, and the four cells between the terminals P1 and P5 are connected in series to directly determine a high voltage such as the added voltage V1 + V2 + V3 + V4. In this embodiment, it should be noted that the circuit symbols attached to the MOSFETs are used in duplicate with those used in the above embodiment in order to prevent the drawing from becoming complicated. Each of the MOSFETs shown in the figure has a circuit function different from that of the MOSFET of the above-described embodiment to which the same circuit symbols are given.

The terminals P1 and P5 are provided with protective resistors R5 and R1, respectively, and the voltage from the terminal P5 is transmitted to the voltage-current conversion circuit via the switch MOSFET constituting the activation circuit. In the voltage-to-current converter, MOSFETs Q1 to Q10 each having a gate and a drain connected to each other are connected in series in order to prevent the gate insulating film of each MOSFET from being damaged by the high voltage as described above. Thereby, the terminal voltage V1 + V2 + V3
+ V4 is shared by the eight MOSFETs, and even if the voltage during charging rises to the upper limit of 20V as described above,
Only about 1/8 of 2.5V is applied to one MOSFET.

In this embodiment, the same current as the current flowing through the MOSFET Q1 flows through the MOSFET Q3 in a current mirror configuration with the MOSFET Q1 and the MOSFET Q3 whose gate and source are connected. Similarly,
By connecting MOSFETs Q2 and Q4,
A divided voltage corresponding to two cell voltages of 1 and Q2, in other words, a current corresponding to a voltage corresponding to each cell voltage obtained by reducing V1 + V2 + V3 + V4 (= V) to １ ／
It is formed by FETs Q3 and Q4.

The current signal formed by the MOSFET Q4 is applied to a MOSFET Q1 constituting a voltage relaxation circuit in which the voltage at the interconnection point of the MOSFETs Q5 to Q10 provided for preventing the gate insulation breakdown is applied to the gate.
It is transmitted to the current-voltage conversion conversion circuit through 1 to Q14.
The current-voltage conversion circuit is provided with two MOSFETs Q15 and Q16 corresponding to the MOSFETs Q1 and Q2,
As described above, the same current is supplied through the voltage relaxation circuit to form the voltage V / 4.

In terms of the circuit form, the MO of the above-described voltage relaxation circuit
The SFETs Q11 to Q14 are also the MOs of the voltage-current conversion circuit.
Like the SFETs Q3 and Q4, they are connected to the MOSFETs Q1, Q2 and Q5 to Q10 forming the voltage dividing circuit, but are connected to the MOSFETs forming the voltage-current converting circuit.
Q1 to Q10 and the MO constituting the current-voltage conversion circuit.
To reduce current consumption, the SFETs Q15 and Q16 have, for example, a long channel length and a small conductance so that only a small current flows. On the other hand, MOSFETs Q11-Q1
In order to transmit the current formed by the MOSFETs Q3 and Q4 without loss, the channel 4 has only a negligible on-resistance, for example, the channel length is shortened. In principle, it is also possible to replace MOSFET Q4 with a MOSFET of a voltage relaxation circuit.

FIG. 8 is a specific circuit diagram of another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention. This embodiment shows a modification of the circuit of the embodiment shown in FIG. 7, and shows only a voltage-current conversion circuit, a current relaxation circuit, and a current-voltage conversion circuit.

In this embodiment, MOSFETs Q1 and Q2
Are paired, and the MOSFET Q1 is a low threshold voltage or depletion type MOSFET. Similarly, MOSFETs Q5 and Q6, Q7 and Q8, Q9 and Q10, MOSFETs Q3 and Q4, Q5 'and Q6' that constitute a voltage-to-current converter, and M that constitutes a current-to-voltage converter.
The same applies to OSFETs Q15 and Q16. In the voltage-current conversion circuit, a circuit for forming a current signal is an MO signal.
In addition to SFETs Q3 and Q4, MOS
FETs Q5 'and Q6' are added. Battery voltage V 1
/ 2 are applied to the MOSFETs Q3, Q4, Q5 ', Q
6 ′ to convert to a current signal.

In this embodiment, the threshold voltage of the MOSFET to be used is lowered, or the depletion MOSFET is used, so that it is possible to perform highly accurate measurement even when the battery voltages V1 to V4 are low. Become. Since the above depletion MOSFETs can be regarded as resistors, these MOSFETs can be replaced with resistance elements. As described above, the battery voltage V
Since the voltage corresponding to / 2 is converted into a current signal, the voltage relaxation circuit can be constituted by one MOSFET Q11.

FIG. 9 is a specific circuit diagram of still another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention. In this embodiment, the voltage of the terminal P4 is applied to the gate of the P-channel MOSFET Q1, and the voltage of the terminal P5 is applied to the source via a high resistance such as about 100 MΩ. As a result, the threshold voltage of the P-channel MOSFET Q1 is used as the reference voltage, and when the cell voltage V4 becomes lower than that, the MOSFET Q1
Is turned off, and no current flows.

The detection current of the MOSFET Q1 as described above is supplied to the current-to-voltage conversion circuit via the voltage relaxation circuit composed of the MOSFETs Q2 and Q3 whose cell voltages lower than the voltage applied to the gate are applied to the gate. . In the current-voltage conversion circuit, the current detected by the MOSFET Q1 is formed by a current mirror circuit comprising MOSFETs Q4 and Q5, and the current is formed by a depletion-type N-channel MOSFET.
The current flows through the ETQ6, and the voltage drop therefrom is applied between the gate and the source of the P-channel MOSFET Q7 to reduce the current value and supply it to the MOSFET Q8 as a constant current source.

The MOSFET Q8 has a constant voltage VB
Is applied, a constant current flows as described above, and the MOSFETs Q6 and Q7
Reduces the detection current by acting as a depletion type MOSFET, in other words, as a resistor. That is, in order to reduce the current consumption, the MOSFET Q
After reducing the current flowing through the MOSFET 1 from the high resistance R6, the current is further reduced by the MOSFETs Q6 and Q7.
The current flowing between Q8 and the transistor Q8 is made extremely small.

As the cell voltage V4 decreases, the MOS
The current of the FET Q1 is reduced, and the MOSFETs Q7 and Q
When the current difference of 8 reverses, a low-level output voltage is formed and transmitted to the NAND gate circuit G. The other cell voltages are also converted into the above-described voltage signals by the same voltage-current conversion circuit, voltage relaxation circuit, and current-voltage conversion circuit as described above, and input to the gate circuit G. Therefore, when any one of the four cell voltages V1 to V4 becomes equal to or lower than the reference voltage corresponding to the threshold voltage of the P-channel MOSFET, a high-level detection signal OUT is generated from the gate circuit G. .

The countermeasure circuit for battery depletion also includes a dummy load circuit including a MOSFET Q7 and a high resistance R7 provided at the source corresponding to the voltage-current conversion circuit. , Two and one.

FIG. 10 is an overall circuit diagram of one embodiment of the secondary battery protection circuit according to the present invention. In the figure, each circuit formed in a portion surrounded by a dotted line is formed on one semiconductor substrate such as single crystal silicon by a known semiconductor integrated circuit manufacturing technique.

Although not particularly limited, the battery is a Li-ion secondary battery. The voltage V1 of each cell constituting such a battery
To V4 are supplied to the semiconductor integrated circuit device IC constituting the protection circuit via the terminals P1 to P5.
And a voltage obtained by stepping down the battery voltage supplied from P5 is used as the operating voltage. The positive electrode of the secondary battery corresponding to the cell voltage V4 is directly connected to the positive battery pack terminal +.

Between the negative electrode corresponding to the cell voltage V1 and the negative battery pack terminal-, protection switch MOSFETs Q1 and Q2 are connected in series.
The switch MOSFET Q1 is a switch for discharge protection, and the switch MOSFET Q2 is a switch for charge protection. The sources of the switch MOSFETs Q1 and Q2 are connected to a substrate (channel). Therefore, a PN junction between the drain and the channel is formed by the parasitic diodes D1 and D1.
2, the switch MOSFETs Q1 and Q2 are provided in parallel with each other. These MOSFETs
Each is constituted by a single element.

In the semiconductor integrated circuit device IC, the cell voltages V1 to V4 supplied via the terminals P1 to P5
Is supplied to the battery voltage detection circuit as in the above-described embodiment, and the above-described voltage conversion is performed. The converted voltage is converted to an analog output, and is output by a voltage comparison circuit COMP.
1 is supplied to one input terminal +. A reference voltage V1 formed by a reference voltage generation circuit (not shown) is supplied to the other input terminal − of the voltage comparison circuit COMP1.
The detection signal of the voltage detection circuit COMP1 is supplied to the reset terminal R of the latch circuit LT1. The output signal Q of the latch circuit LT1 is at a high level in the set state, and is at a low level in the reset state. This output signal Q is supplied to the gate of the MOSFET Q2, which is the charge protection switch, via the terminal P7.

Although not particularly limited, an analog output formed by the battery voltage detection circuit is connected to a voltage comparison circuit COMP.
2 to one input terminal-. The other input terminal + of the voltage comparison circuit COMP2 is supplied with a reference voltage V2 formed by a reference voltage generation circuit (not shown).
The output signal of the voltage comparison circuit COMP2 is supplied to the set terminal S of the latch circuit LT1 through the OR (logical sum) gate circuit G1. The reference voltage V2 corresponds to a specified voltage that instructs a battery charging operation. That is, when the cell voltage falls below the prescribed reference voltage V2, the output signal of the voltage comparison circuit COMP2 changes to a high level to set the latch circuit LT1, and the overcharge protection is performed by the output signal Q of the latch circuit LT1. Switch MOSFET Q2 is turned on.

In this embodiment, when an overvoltage is erroneously made, the voltage comparator COMP1 detects this and resets the latch circuit LT1 to turn off the overcharge protection switch MOSFET Q2. In the present invention, the switch MOSFET Q2 is used to prevent accidents due to overheating and the like due to the deposition of Li due to overcharging. Focusing on the fact that it is desirable to return to a normal state, the following function of detecting a load connection is added.

The output side of the switch MOSFET Q2,
In other words, the potential of the battery pack terminal-is taken into the inside of the semiconductor integrated circuit IC via the terminal P8, and is supplied to the input terminal + of the voltage comparison circuit COMP3. A reference voltage V3 is supplied to the other input terminal-of the voltage comparison circuit COMP3. This reference voltage V3 is
The potential is set to a relatively low potential for detecting the forward voltage Vf of the parasitic diode D2.

When a load (electric device) is connected between the battery pack terminals + and-in a state where the latch circuit LT1 is reset due to the overcharging and as a result the MOSFET Q2 is turned off, In such an overvoltage state, for the overdischarge protection connected in series with the MOSFET Q2, since the switch MOSFET Q1 is in the ON state, the battery is connected via the parasitic diode D2 to the ground potential of the circuit with respect to the terminal T2. A current flows into the negative electrode side, and the potential of the battery pack terminal-rises by the forward voltage Vf of the parasitic diode D2.

In the voltage comparison circuit COMP3, an electronic device as a load is connected between the battery pack terminals + and-in which the above-described discharge path is formed, in other words, the battery pack terminal- Is detected by the voltage VM from the terminal P8, and the output signal is changed from the low level to the high level. As a result, the latch circuit LT1 in the reset state is inverted to the set state via the OR gate circuit G1, so that the output signal Q changes from low level to high level and
The OSFET Q2 is turned on again, and current can be supplied to the load. By such a discharging operation by connecting the load, the overcharge state is automatically released, and the output of the voltage comparison circuit COMP1 returns to the low level. The resistor R7 is added for preventing electrostatic breakdown at the terminal P5, but may be omitted.

The functions and effects obtained from the above embodiment are as follows. That is, (1) a protection circuit for a secondary battery in which a plurality of secondary batteries are connected in series to form a high battery voltage corresponding to the plurality of secondary batteries; Are connected in series to share the voltage applied to each gate insulating film, and form a current signal corresponding to the battery voltage. By using a plurality of MOSFETs whose voltage at the interconnection point is applied to the gate and sharing the voltages applied to the respective gate insulating films with each other, the gate insulation breakdown can be prevented without applying a special high withstand voltage. A current-to-voltage conversion circuit that receives the current converts the current signal into a low-voltage signal that is equal to or lower than the gate withstand voltage of the MOSFET. By measuring the voltage across the effect is obtained that can be detected by at least any one of the simple circuit of overvoltage or over-discharge state of the secondary battery.

(2) As the voltage-current conversion circuit, two battery voltages of a plurality of secondary batteries are applied to both ends, and a gate and a drain are connected so that a current corresponding to the battery voltage flows. MOSFET and the above two MOs
By using any one of the SFETs and a current output MOSFET whose gate and source are connected in common, a MOSF with an exceptionally high withstand voltage is provided.
The effect is obtained that a current signal corresponding to each battery voltage can be formed without using ET.

(3) As the voltage moderating circuit, a potential at an interconnection point of each of the secondary batteries is applied to a gate, and a MOS is connected in series with the current output MOSFET.
By using an FET, an effect is obtained in that the formed current signal can be extracted by a simple circuit without using a MOSFET with a particularly high withstand voltage.

(4) The voltage / current conversion circuit is provided with a plurality of current output MOSFETs corresponding to each battery voltage connected in the series form, and the voltage moderating circuit is provided with two or more batteries out of the plurality of battery voltages. By using a MOSFET with an exceptionally high withstand voltage by providing a voltage-added circuit and providing the current-voltage conversion circuit with a plurality of current output MOSFETs corresponding to the respective battery voltages. The effect that voltage detection corresponding to each battery voltage (cell) can be performed with a simple and simple circuit is obtained.

(5) By selecting and outputting one of the output voltages of the plurality of current-voltage conversion circuits through the battery selection circuit, the effect that the determination circuit can be simplified can be obtained.

(6) As the voltage-current conversion circuit, one of the battery voltages of the plurality of secondary batteries is applied to the source side, and the first MOSFE having a gate and a drain connected thereto.
T and the other voltage of each of the battery voltages is applied to the gate, and the source of the second MOSFET is connected to the drain of the MOSFET.
Is also used as the above-mentioned voltage relaxation circuit, whereby the effect that the circuit can be simplified can be obtained.

(7) A voltage applied to each MOSFET is shared by の of the cell voltage by further connecting in series a MOSFET having the same size and a gate and a drain connected to the first MOSFET. Therefore, the effect that the reliability against element destruction can be increased can be obtained.

(8) Among the MOSFETs constituting the voltage-to-current conversion circuit, the MOSFET whose gate and drain are supplied to one of the battery voltages is a MOSFET that is switch-controlled by an activation signal. Selectively applying one of the voltages and the other voltage,
Since the operation of the voltage-current conversion circuit can be switched between an operation state and a non-operation state in response to the activation signal, the circuit can be operated only when a protection operation is required, thereby reducing current consumption. The effect is obtained.

(9) The above-mentioned battery voltage is obtained by providing a dummy load circuit for supplying a current so that a plurality of rechargeable batteries are evenly consumed and a rechargeable battery countermeasure circuit. The effect that the protection operation can be performed effectively can be obtained.

(10) The voltage dividing circuit includes a MOSFET having a first threshold voltage and a MOSFET having a second threshold voltage lower than the first threshold voltage as a pair. Voltage for forming a voltage and the current output MOSF
The ET also can operate up to a low voltage region of each cell voltage by forming a pair of MOSFETs having the first and second threshold voltages corresponding to the voltage dividing circuit. The effect is obtained.

(11) As the voltage-current conversion circuit,
A high battery voltage corresponding to a plurality of secondary batteries is applied to both ends, and a voltage dividing circuit including a plurality of MOSFETs diode-connected by connecting a gate and a drain, and the divided voltage is applied to a gate and a source. A series-type MOSFET in which a divided voltage formed by the voltage dividing circuit is applied to a gate as the voltage relaxation circuit, using a current output MOSFET that is applied in between to convert to a current signal and output.
Is used, it is possible to form a current signal corresponding to the battery voltage without using a MOSFET having a particularly high withstand voltage while reducing the number of external terminals.

(12) As the voltage-current conversion circuit,
One of the battery voltages of the plurality of secondary batteries is applied to the source via a resistor, and the other of the battery voltages is applied to the gate so that a current corresponding to each battery voltage flows. Using a MOSFET, as the voltage relaxation circuit, a MOSFET connected to the current output MOSFET in series with the current output MOSFET in which the potential of the interconnection point of each secondary battery lower than the voltage at which the gate is connected is applied to the gate. By using such a circuit, the circuit can be simplified and the threshold voltage of the MOSFET can be used as the detection voltage, so that the voltage comparison circuit can be eliminated.

(13) A first voltage detection circuit for detecting the overvoltage state based on the voltage passed through the current-voltage conversion circuit, and receiving the potential of the negative electrode terminal side on the load side of the secondary battery and lifting the same. And a latch circuit that is stabilized at one level by the detection signal of the first voltage detection circuit and is inverted to the other level by the detection signal of the second voltage detection circuit. The latch circuit is turned off by an output signal in a stable state at one level, is turned on by an output signal in a stable state at the other level, and is connected to a current path on the negative electrode side of the secondary battery. An overcharge protection switch inserted in series, and a unidirectional element provided at both ends of the overcharge protection switch and configured to flow a current in a direction opposite to a current direction during a charging operation. Is provided, it is possible to form an easy-to-use protection circuit without using a MOSFET with a high breakdown voltage.

(14) By integrating the secondary battery protection circuit integrally with a lithium ion battery as a battery pack, it is possible to obtain a highly reliable and easy-to-use secondary battery.

Although the invention made by the present inventors has been specifically described based on the embodiments, the invention of the present application is not limited to the above embodiments, and various modifications can be made without departing from the gist of the invention. Needless to say. For example, the number of battery cells connected in series may be set according to the load circuit in which the battery cell is used, such as a portable electronic device. Each cell voltage for preventing the overcharge state may be a voltage having a margin for enhancing safety, such as limiting to about 4.3V. The switch element constituting the protection circuit provided in the battery current path is a MOSFET.
Alternatively, a bipolar transistor or another switch element may be used. In the case of the above-mentioned MOSFET, a parasitic diode between the drain and the source can be used. However, when there is no such a parasitic diode, a diode that allows a current equivalent to that to flow is provided in each switch in parallel. do it.

A terminal may be provided for detecting that the voltage formed by the voltage conversion circuit has dropped to the voltage to be charged, and transmitting the detected signal to a portable electronic device or the like as a warning signal. . The present invention can be widely used as a secondary battery protection circuit.

[0083]

The effects obtained by typical ones of the inventions disclosed in the present application will be briefly described as follows. That is, a secondary battery protection circuit that connects a plurality of secondary batteries in series to form a high battery voltage corresponding to the plurality of secondary batteries, and includes a plurality of MOSFETs in a current-voltage conversion circuit. By connecting in series, the voltage applied to each gate insulating film is mutually shared,
A current signal corresponding to the battery voltage is formed, and the plurality of MOSFEs connected in series in the voltage alleviation circuit.
By using a plurality of MOSFETs in which the voltage at the interconnection point of T is applied to the gate and sharing the voltages applied to the respective gate insulating films with each other, the gate insulation breakdown can be prevented without specially increasing the breakdown voltage. In the current-voltage conversion circuit receiving the current,
A simple circuit that converts the voltage into a low-voltage signal equal to or lower than the gate withstand voltage of the SFET, measures the voltage passed through the current-voltage conversion circuit, and determines at least one of the overvoltage state and the overdischarge state of the secondary battery Can be detected.

[Brief description of the drawings]

FIG. 1 is a basic circuit diagram showing one embodiment of a battery voltage detection circuit provided in a secondary battery protection circuit according to the present invention according to the present invention.

FIG. 2 is a specific circuit diagram showing one embodiment of a battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention.

FIG. 3 is a specific circuit diagram showing another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention.

FIG. 4 is a specific circuit diagram showing another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention.

FIG. 5 is a specific circuit diagram showing another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention.

FIG. 6 is a specific circuit diagram showing another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention.

FIG. 7 is a specific circuit diagram showing another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention.

FIG. 8 is a specific circuit diagram showing another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention.

FIG. 9 is a specific circuit diagram showing still another embodiment of the battery voltage detection circuit provided in the secondary battery protection circuit according to the present invention.

FIG. 10 is an overall circuit diagram showing one embodiment of a secondary battery protection circuit according to the present invention.

[Explanation of symbols]

Q1 to Q30: MOSFET, R1 to R7: Resistance, LT
1, LT2 latch circuit, G1 to G3 logic gate circuit, IV1 inverter circuit, COMP1 to CPMP4
... voltage comparison circuit, D1, D2 ... diodes.

Claims (14)

[Claims] 1. A secondary battery protection circuit provided in a secondary battery that forms a high battery voltage corresponding to the plurality of secondary batteries by connecting a plurality of secondary batteries in series. MOSFETs are connected in series,
A voltage-current conversion circuit for mutually sharing the voltage applied to each gate insulating film and forming a current signal corresponding to the battery voltage; and a voltage at an interconnection point of the plurality of MOSFETs connected in series. A plurality of MOSFETs applied to a gate, a voltage relaxation circuit that transmits a current formed by the voltage-current conversion circuit while mutually sharing a voltage applied to each gate insulating film; A current-to-voltage conversion circuit that receives the passed current and converts the voltage into a low-voltage signal that is equal to or lower than the gate withstand voltage of the MOSFET; At least one of the states
A secondary battery protection circuit, comprising: a voltage measurement circuit for detecting a voltage. 2. The voltage-current conversion circuit according to claim 1, wherein each of the battery voltages of the plurality of secondary batteries is applied to both ends, and a gate and a drain are connected to flow a current corresponding to the battery voltage. Two MOSFETs and one of the two MOSFETs
A secondary battery protection circuit comprising a current output MOSFET having an FET, a gate and a source commonly connected. 3. The voltage mitigation circuit according to claim 1, wherein a potential of an interconnection point of each of the secondary batteries is applied to a gate, and the voltage mitigation circuit comprises a MOSFET connected in series with the current output MOSFET. Characteristic secondary battery protection circuit. 4. The voltage-current conversion circuit according to claim 3, wherein the voltage-current conversion circuit includes a plurality of current output MOSFETs corresponding to the respective battery voltages connected in the series configuration. The current-to-voltage converter is provided with a plurality of current output MOSFETs corresponding to the respective battery voltages. A secondary battery protection circuit, comprising: 5. The secondary battery protection circuit according to claim 4, wherein one of the output voltages of the plurality of current-voltage conversion circuits is selected and output through a battery selection circuit. 6. The voltage-current conversion circuit according to claim 2, wherein one of the battery voltages of the plurality of secondary batteries is applied to a source side, and the first MOSF having a gate and a drain connected thereto.
ET, and the other of the battery voltages is applied to the gate, and the second is connected to the drain of the MOSFET.
A secondary battery protection circuit, comprising a MOSFET, wherein the second MOSFET also serves as the voltage relaxation circuit. 7. The secondary battery protection circuit according to claim 6, wherein a MOSFET having the same size and a gate and a drain connected to the first MOSFET is further connected in series. 8. The MOSFET according to claim 2, wherein:
The MOSFET whose gate and drain are supplied to one voltage of each battery voltage is selectively applied with one voltage and the other voltage of each battery voltage by a MOSFET that is switch-controlled by an activation signal. A secondary battery protection circuit, wherein an operation of the voltage-current conversion circuit can be switched between an operation state and a non-operation state in response to the activation signal. 9. The battery according to claim 8, wherein each of the battery voltages is provided with a battery load reduction circuit including a dummy load circuit for supplying a current so that the plurality of secondary batteries are consumed evenly. Rechargeable battery protection circuit. 10. The MOSFET according to claim 2, wherein the voltage dividing circuit has a MOSFE having a first threshold voltage.
T and a MOSFET having a second threshold voltage lower than the first threshold voltage are paired to form a divided voltage, and the current output MOSFET is also a voltage dividing circuit. A secondary battery protection circuit comprising a pair of the MOSFETs having the first and second threshold voltages. 11. The voltage-current conversion circuit according to claim 1, wherein a high battery voltage corresponding to the plurality of secondary batteries is applied to both ends, and the gate and the drain are connected to each other. And a current output MOSFET for applying the divided voltage between a gate and a source to convert the voltage into a current signal and outputting the current signal. The voltage moderating circuit is formed by the voltage dividing circuit. A secondary battery protection circuit comprising a series-type MOSFET having a divided voltage applied to a gate. 12. The voltage-current conversion circuit according to claim 1, wherein one of the battery voltages of the plurality of secondary batteries is applied to a source via a resistor, and the other voltage of the battery voltages is applied to a gate. Is applied so that a current corresponding to each battery voltage flows. The voltage mitigation circuit is configured such that the potential of the interconnection point of each secondary battery lower than the voltage to which the gate is connected is applied to the gate. Applied and the current output M
A secondary battery protection circuit comprising a MOSFET connected in series with an OSFET. 13. The secondary battery according to claim 1, wherein the first voltage detection circuit detects the overvoltage state based on a voltage passed through the current-to-voltage conversion circuit. A second voltage detection circuit for receiving the potential on the negative terminal side of the second voltage detection circuit, and detecting the rising of the second voltage detection circuit, and the detection signal of the first voltage detection circuit stabilizes at one level, and the detection signal of the second voltage detection circuit A latch circuit that is inverted to the other level by the output signal in a stable state at one level of the latch circuit, and is turned on by an output signal in the stable state at the other level; and An overcharge protection switch inserted in series in the current path on the negative electrode side of the secondary battery; provided at both ends of the overcharge protection switch, opposite to the current direction during the charging operation. The rechargeable battery protection circuit according to claim, further comprising a unidirectional element which is adapted to flow a current to the direction. 14. The secondary battery protection circuit according to claim 13, wherein the secondary battery protection circuit is integrated with a lithium ion battery as a battery pack.