Charging circuit for a lead-acid storage battery
First Claim
1. A circuit for charging a lead-acid storage battery (50) with electric power from a d.c. source (12) which varies in voltage by substantially more than 10 volts between minimum and maximum voltage values,said charging circuit having an integrated d.c. to d.c. voltage converter circuit (14) including a pulse width modulator portion (19) and a voltage regulator portion (20) for regulating the voltage of the charging power,said charging circuit having an output (53) for connection to said lead-acid storage battery (50) to be charged,said pulse width modulator portion (19) of said integrated circuit (14) having a control input (A5);
- a supplementary circuit branch connected between said output (53) and said control input (A5) for regulation of the current (IL) of the charging power,said supplementary circuit branch includinga first resistor (45) having a resistance of less than 1 ohm connected to said output (53) for producing a voltage drop in said circuit branch which is subject to voltage variations;
a resistance network comprising a plurality of resistances (56, 57, 47,
48) in said circuit branch connected to said first resistor (45) for adding a substantially constant voltage to said voltage drop across said first resistor (45);
a first transistor (46) coupled to said control input (A5) of said pulse width modulator portion (49) of said integrated circuit (14), and supplying a control voltage to said control input; and
wherein said added voltage formed by the voltage drop across said first resistor (45) and said substantially constant voltage derived from said resistance network is coupled to and applied to said first transistor (46) to control the current flow therethrough.
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Accused Products
Abstract
A charging circuit for a lead-acid storage battery for a mobile radio transceiver which operates effectively with an input from a vehicular battery terminal that may vary over a range of 25 volts in output voltage has a control circuit for regulating the charging current connected between the charging current output and the same control input of the same pulse width modulator that is used for output voltage control. The pulse width modulator is part of an integrated circuit which includes also a d.c. to d.c. voltage converter and an output voltage regulator. A branch circuit includes a current sensing resistor (45) of less than 1 ohm. The voltage drop across said sensing resistor is too small to control a control transistor network (46, 52) and therefore a constant voltage is added thereto by a voltage adding resistor network (56, 57, 47, 48) coupled to said transistor network.
11 Citations
5 Claims
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1. A circuit for charging a lead-acid storage battery (50) with electric power from a d.c. source (12) which varies in voltage by substantially more than 10 volts between minimum and maximum voltage values,
said charging circuit having an integrated d.c. to d.c. voltage converter circuit (14) including a pulse width modulator portion (19) and a voltage regulator portion (20) for regulating the voltage of the charging power, said charging circuit having an output (53) for connection to said lead-acid storage battery (50) to be charged, said pulse width modulator portion (19) of said integrated circuit (14) having a control input (A5); -
a supplementary circuit branch connected between said output (53) and said control input (A5) for regulation of the current (IL) of the charging power, said supplementary circuit branch including a first resistor (45) having a resistance of less than 1 ohm connected to said output (53) for producing a voltage drop in said circuit branch which is subject to voltage variations; a resistance network comprising a plurality of resistances (56, 57, 47,
48) in said circuit branch connected to said first resistor (45) for adding a substantially constant voltage to said voltage drop across said first resistor (45);a first transistor (46) coupled to said control input (A5) of said pulse width modulator portion (49) of said integrated circuit (14), and supplying a control voltage to said control input; and wherein said added voltage formed by the voltage drop across said first resistor (45) and said substantially constant voltage derived from said resistance network is coupled to and applied to said first transistor (46) to control the current flow therethrough. - View Dependent Claims (2, 3, 4, 5)
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Specification