CN204256136U - Discharge and recharge integral type for computing machine can remember battery-detecting instrument - Google Patents

Abstract

The discharge and recharge integral type that the utility model discloses for computing machine can remember battery-detecting instrument, the signal input part of central controller is connected with the signal output part of condition tester for battery and the signal output part of charging voltage collector respectively, the control signal output terminal of central controller is connected with the control signal input end of state controller and the control signal input end of charge and discharge mode controller with charge type respectively, power supply is that central controller is powered, and the data output end of central controller is connected with the data input pin of real-time memory.The electric energy of detected accumulator is used for accumulators detector and powers by the utility model, both economize energy, solve again the inconvenience that the problem because of power supply causes, and the utility model adds real-time memory, avoid the problems such as the loss of data caused because of unexpected power-off because of battery-detecting instrument.

Description

Discharge and recharge integral type for computing machine can remember battery-detecting instrument

Technical field

The utility model relates to a kind of battery-detecting instrument, and particularly relating to a kind of discharge and recharge integral type for computing machine can remember battery-detecting instrument.

Background technology

Common battery-detecting instrument needs external power supply normally to work, then a lot of inconvenience can be caused because of the problem of power supply when detecting different accumulators, some battery-detecting instruments are also had to store data, once there is the situation such as loose contact or power-off suddenly, will cause loss of data, testing will start anew to do, the waste duration of charging, reduce charge efficiency, covert improves use cost.

Utility model content

The purpose of this utility model is just to provide a kind of discharge and recharge integral type for computing machine to remember battery-detecting instrument to solve the problem.

In order to achieve the above object, the utility model have employed following technical scheme:

A kind of discharge and recharge integral type for computing machine can remember battery-detecting instrument, comprise central controller, Man Machine Interface, power supply, condition tester for battery, charging voltage collector, charge type and state controller, charge and discharge mode controller and real-time memory, the signal input part of described central controller is connected with the signal output part of described condition tester for battery and the signal output part of described charging voltage collector respectively, the control signal output terminal of described central controller is connected with the control signal input end of state controller and the control signal input end of described charge and discharge mode controller with described charge type respectively, described power supply is that described central controller is powered, the data output end of described central controller is connected with the data input pin of described real-time memory.

Particularly, described power supply comprises the first resistance to the 7th resistance, first potentiometer, second potentiometer, first diode is to the 4th diode, first triode is to the 3rd triode, first potentiometer, second potentiometer and switch, the positive pole of detected accumulator respectively with the negative pole of described 3rd diode, the negative pole of described 4th diode, the collector of described 3rd triode and the first end of described 6th resistance, the negative pole of detected accumulator respectively with the base stage of described first triode, the collector of described first triode, the emitter of described second triode, the collector of described second triode, the base stage of described 3rd triode, the emitter of described 3rd triode, the sliding end of described second potentiometer, the first end of described 4th resistance, the first end of described 5th resistance, second end of described 5th resistance, the negative pole of described first diode is connected with cathode voltage output terminal, second end of described 6th resistance is connected with the first end of described second potentiometer, second end of described second potentiometer is connected with the second end of described 7th resistance, the positive pole of described 3rd diode is connected with the negative pole of described second diode and the first end of described second resistance respectively, the positive pole of described second diode is connected with the first end of described first resistance, the second end of described first resistance respectively with the second end of described second resistance, the first end of described first potentiometer, the sliding end of described first potentiometer, the first end of described switch is connected with cathode voltage output terminal, second end of described switch is connected with the first end of described 3rd resistance, second end of described 3rd resistance is connected with the positive pole of described first diode, second end of the first potentiometer is connected with the second end of described 4th resistance, and the emitter of described first triode is connected with the base stage of described second triode.

The beneficial effects of the utility model are:

The electric energy of detected accumulator is used for accumulators detector and powers by the utility model, both economize energy, solve again the inconvenience that the problem because of power supply causes, and the utility model adds real-time memory, avoid the problems such as the loss of data caused because of unexpected power-off because of battery-detecting instrument, in addition the employing of charge and discharge mode controller in the utility model, effectively can manage charging, still can power for battery-detecting instrument when the utility model can be made to detect dissimilar accumulator.

Accompanying drawing explanation

The structured flowchart of Fig. 1 to be the utility model for the discharge and recharge integral type of computing machine can remember battery-detecting instrument;

Fig. 2 is the circuit diagram of power supply described in the utility model.

Embodiment

Below in conjunction with accompanying drawing, the utility model is described in further detail:

As shown in Figure 1, the discharge and recharge integral type that the utility model is used for computing machine can remember battery-detecting instrument, comprise central controller, Man Machine Interface, power supply, condition tester for battery, charging voltage collector, charge type and state controller, charge and discharge mode controller and real-time memory, the signal input part of described central controller is connected with the signal output part of described condition tester for battery and the signal output part of described charging voltage collector respectively, the control signal output terminal of described central controller is connected with the control signal input end of state controller and the control signal input end of described charge and discharge mode controller with described charge type respectively, described power supply is that described central controller is powered, the data output end of described central controller is connected with the data input pin of described real-time memory.

As shown in Figure 2, power supply comprises the first resistance R1 to the 7th resistance R7, first potentiometer RP1, second potentiometer RP2, first diode D1 is to the 4th diode D4, first triode VT1 is to the 3rd triode VT3, first potentiometer RP1, second potentiometer RP2 and switch S, the positive pole of detected accumulator U respectively with the negative pole of the 3rd diode D3, the negative pole of the 4th diode D4, the collector of the first triode VT1 and the first end of the 6th resistance R6, the negative pole of detected accumulator U respectively with the base stage of the first triode VT1, the collector of the first triode VT1, the emitter of the second triode VT2, the collector of the second triode VT2, the base stage of the 3rd triode VT3, the emitter of the 3rd triode VT3, the sliding end of the second potentiometer RP2, the first end of the 4th resistance R4, the first end of the 5th resistance R5, second end of the 5th resistance R5, the negative pole of the first diode D1 is connected with cathode voltage output terminal, second end of the 6th resistance R6 is connected with the first end of the second potentiometer RP2, second end of the second potentiometer RP2 is connected with second end of the 7th resistance R7, the positive pole of the 3rd diode D3 is connected with the negative pole of the second diode D2 and the first end of the second resistance R2 respectively, the positive pole of the second diode D2 is connected with the first end of the first resistance R1, second end of the first resistance R1 respectively with second end of the second resistance R2, the first end of the first potentiometer RP2, the sliding end of the first potentiometer RP1, the first end of switch S is connected with cathode voltage output terminal, second end of switch S is connected with the first end of the 3rd resistance R3, second end of the 3rd resistance R3 is connected with the positive pole of the first diode D1, second end of the first potentiometer RP1 is connected with second end of the 4th resistance R4, and the emitter of the first triode VT1 is connected with the base stage of the second triode VT2.

The utility model is applicable to the detection of all kinds of accumulator such as 36V, 48V, 60V, 64V, 72V, 80V, can adapt to the battery of more different sizes, applied range.

Claims (2)

1. battery-detecting instrument can be remembered for the discharge and recharge integral type of computing machine for one kind, comprise central controller and Man Machine Interface, it is characterized in that: also comprise power supply, condition tester for battery, charging voltage collector, charge type and state controller, charge and discharge mode controller and real-time memory, the signal input part of described central controller is connected with the signal output part of described condition tester for battery and the signal output part of described charging voltage collector respectively, the control signal output terminal of described central controller is connected with the control signal input end of state controller and the control signal input end of described charge and discharge mode controller with described charge type respectively, described power supply is that described central controller is powered, the data output end of described central controller is connected with the data input pin of described real-time memory.

2. the discharge and recharge integral type for computing machine according to claim 1 can remember battery-detecting instrument, it is characterized in that: described power supply comprises the first resistance to the 7th resistance, first potentiometer, second potentiometer, first diode is to the 4th diode, first triode is to the 3rd triode, first potentiometer, second potentiometer and switch, the positive pole of detected accumulator respectively with the negative pole of described 3rd diode, the negative pole of described 4th diode, the collector of described 3rd triode and the first end of described 6th resistance, the negative pole of detected accumulator respectively with the base stage of described first triode, the collector of described first triode, the emitter of described second triode, the collector of described second triode, the base stage of described 3rd triode, the emitter of described 3rd triode, the sliding end of described second potentiometer, the first end of described 4th resistance, the first end of described 5th resistance, second end of described 5th resistance, the negative pole of described first diode is connected with cathode voltage output terminal, second end of described 6th resistance is connected with the first end of described second potentiometer, second end of described second potentiometer is connected with the second end of described 7th resistance, the positive pole of described 3rd diode is connected with the negative pole of described second diode and the first end of described second resistance respectively, the positive pole of described second diode is connected with the first end of described first resistance, the second end of described first resistance respectively with the second end of described second resistance, the first end of described first potentiometer, the sliding end of described first potentiometer, the first end of described switch is connected with cathode voltage output terminal, second end of described switch is connected with the first end of described 3rd resistance, second end of described 3rd resistance is connected with the positive pole of described first diode, second end of the first potentiometer is connected with the second end of described 4th resistance, and the emitter of described first triode is connected with the base stage of described second triode.