Battery protection circuit employing active regulation of charge and discharge devices
First Claim
1. A battery protection circuit, comprising:
- a pair of back-to-back connected metal-oxide-semiconductor field-effect transistors (MOSFETs) M1 and M2;
a first gate voltage regulating circuit operative in response to a first enable signal EN1 to control the gate voltage VG1 of M1 such that (i) when EN1 is de-asserted, VG1 is sufficient to enable M1 to strongly conduct current in either direction, (ii) when EN1 is asserted, VG1 is a function of the polarity of drain-to-source voltage VDS1 of M1 so as to prevent M1 from conducting when VDS1 has a charging polarity and to allow M1 to conduct when VDS1 has a discharging polarity, the conducting of M1 preventing VDS1 from achieving a value sufficient to forward bias a parasitic diode associated with the source and drain terminals of M1;
a second gate voltage regulating circuit operative in response to a second enable signal EN2 to control the gate voltage VG2 of M2 such that (i) when EN2 is de-asserted, VG2 is sufficient to enable M2 to strongly conduct current in either direction, (ii) when EN2 is asserted, VG2 is a function of the polarity of the drain-to-source voltage VDS2 of M2 so as to prevent M2 from conducting when VDS2 has a discharging polarity and to allow M2 to conduct when VDS2 has a charging polarity, the conducting of M2 preventing VDS2 from achieving a value sufficient to forward bias a parasitic diode associated with the source and drain terminals of M2; and
detection circuitry operative to detect the charge condition of a battery connected to the protection circuit and to generate the signals EN1 and EN2 such that;
(i) in a normal charge condition, both EN1 and EN2 are de-asserted, (ii) in an overcharged condition, EN1 is asserted and EN2 is de-asserted, and (iii) in an over-discharged condition, EN1 is de-asserted and EN2 asserted.
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Accused Products
Abstract
A battery protection circuit includes back-to-back connected metal-oxide-semiconductor field-effect transistors (MOSFETs). Detection circuitry detects whether the battery is in a normal charge condition, an overcharged condition, or an over-discharged condition, and for the overcharged and over-discharged conditions the circuitry asserts a corresponding enable signal. For each MOSFET, a corresponding gate voltage regulating circuit controls the gate voltage such that (i) when the corresponding enable signal is de-asserted, the gate voltage is sufficient to enable the MOSFET to strongly conduct current in either direction, and (ii) when the corresponding enable signal is asserted, the gate voltage is a function of the polarity of drain-to-source voltage of the MOSFET. For each MOSFET, the corresponding gate voltage regulating circuit prevents the MOSFET from conducting when the drain-to-source voltage has an undesired polarity, and allows the MOSFET to conduct when the drain-to-source voltage has a desired polarity. One MOSFET prevents the flow of charge current, and the other prevents the flow of discharge current. When either MOSFET is conducting, its drain-to-source voltage is prevented from achieving a value sufficient to forward bias a parasitic diode associated with the source and drain terminals of the MOSFET. Current of correct polarity flows through the source-to-drain channel of a MOSFET rather than through the parasitic diode during the overcharged and over-discharged conditions.
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Citations
3 Claims
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1. A battery protection circuit, comprising:
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a pair of back-to-back connected metal-oxide-semiconductor field-effect transistors (MOSFETs) M1 and M2;
a first gate voltage regulating circuit operative in response to a first enable signal EN1 to control the gate voltage VG1 of M1 such that (i) when EN1 is de-asserted, VG1 is sufficient to enable M1 to strongly conduct current in either direction, (ii) when EN1 is asserted, VG1 is a function of the polarity of drain-to-source voltage VDS1 of M1 so as to prevent M1 from conducting when VDS1 has a charging polarity and to allow M1 to conduct when VDS1 has a discharging polarity, the conducting of M1 preventing VDS1 from achieving a value sufficient to forward bias a parasitic diode associated with the source and drain terminals of M1;
a second gate voltage regulating circuit operative in response to a second enable signal EN2 to control the gate voltage VG2 of M2 such that (i) when EN2 is de-asserted, VG2 is sufficient to enable M2 to strongly conduct current in either direction, (ii) when EN2 is asserted, VG2 is a function of the polarity of the drain-to-source voltage VDS2 of M2 so as to prevent M2 from conducting when VDS2 has a discharging polarity and to allow M2 to conduct when VDS2 has a charging polarity, the conducting of M2 preventing VDS2 from achieving a value sufficient to forward bias a parasitic diode associated with the source and drain terminals of M2; and
detection circuitry operative to detect the charge condition of a battery connected to the protection circuit and to generate the signals EN1 and EN2 such that;
(i) in a normal charge condition, both EN1 and EN2 are de-asserted, (ii) in an overcharged condition, EN1 is asserted and EN2 is de-asserted, and (iii) in an over-discharged condition, EN1 is de-asserted and EN2 asserted.- View Dependent Claims (2, 3)
a first resistor connected between the gate of the respective transistor and a voltage source; and
an operational amplifier having an output connected to the gate of the respective transistor, a first input connected to the drain of the respective transistor, and a second input connected to the source of the respective transistor.
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3. A battery protection circuit according to claim 1, wherein M1 and M2 are n-channel MOSFETs.
Specification