KR101421233B1 - Battery protection system - Google Patents

Abstract

In the present invention, the operation of the engine and the operation of the generator are controlled by using a microprocessor to check the operation of the generator and the state (voltage) of the battery and appropriately control the load (electronic device) This is a battery protection system that keeps the engine running at the best condition by preventing the engine starting and the performance degradation of the battery.

Description

[0001] The present invention relates to a battery protection system,

The present invention relates to a battery protection system. More specifically, the microprocessor is used to check the operation of the generator and the state of the battery (voltage) using the microprocessor so as to appropriately control the load (electronic device) The present invention relates to a battery protection system that prevents engine startup and performance degradation of a battery from occurring.

As automobile technology continues to develop, the battery charging system of a car changes in order to obtain a high efficiency fuel economy. As a result, a generator operates like a starter to produce electricity. However, automobiles boasting high fuel efficiency The generator is not operated and the ECU (engine control unit) controls the fuel consumption according to the output of the engine and the state of the load. Therefore, there is a problem in that all devices using an electric generator, which is a power source of a car, and a battery as an energy source have limitations in protecting the battery by a conventional battery protection system. Therefore, it is necessary to develop battery protection system for high efficiency automobile.
The technology that is the background of the present invention is disclosed in Korean Patent Laid-Open Publication No. 10-1994-0008189 (April 29, 1994).

In addition, the existing battery protection system is designed to measure and control the voltage of the battery separately from whether the engine is running or not. In other words, secondary batteries such as lead accumulators, which are mainly used in automobiles, and lithium batteries, which are currently used, are divided into nominal voltage, overcharge voltage and discharge end voltage. A small secondary battery such as a lithium battery, However, a high-capacity battery such as a lead acid battery can not be built in the battery itself, the battery protection function can be built in, or the power can be supplied from the battery protection device to operate the device and protect the battery There is a problem.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the problems as described above, and it is an object of the present invention to provide a microprocessor which can check the operation of the generator and the state of the battery (voltage) (Electronic equipment) to prevent engine start-up and battery performance degradation caused by overdischarge of the battery.

According to an aspect of the present invention, there is provided a battery protection system comprising: a battery; a battery; a battery; .

According to the present invention, there is provided a control system comprising: a power input part that is an input part of a power source for driving a control system; an input signal processing part that converts an input signal so that a control part (microprocessor) (Microprocessor) for analyzing the current battery state and generating an output control signal for output control by analyzing the current battery state, and a control unit (microprocessor) for converting the output control signal of the control unit (Voltage) of the battery is divided into several stages according to necessity to analyze the state (voltage) of the battery, and the output terminal for the load (device) .

(For example, a set voltage V0, a set voltage V1, a set voltage V2, a set voltage V3, a set voltage Voff, etc.) by dividing the state (voltage) (V1), when the engine is running and the generator is also running (V0), the engine is running only. When the battery is charging well (V1) (Eg, heater, motor, etc.) when the battery is in good condition (V3), the engine is stopped and the battery is poorly charged (Voff) (OUT2) and a low-power output (for example, a control power source) OUT1. The distinction of the state (voltage) of the battery and the output of the output terminal can be adjusted in various stages according to the type and state of the load.

When the battery voltage decreases from the set voltage V0 to the set voltage V1, the large power output OUT2 is stopped after the set delay time t1, and when the battery voltage returns to the set voltage V0 or more, The power output OUT2 is restored (Fig. 3). When the battery voltage decreases from the set voltage V0 to the set voltage V2, the large power output OUT2 is stopped after the set delay time t2, The output of the large power output OUT2 is restored (FIG. 4). When the battery voltage decreases from the set voltage V0 to the set voltage V3, the set delay time t3 ), The large power output OUT2 is restored when the battery voltage returns to the set voltage V0 or more (FIG. 5), and the battery voltage is increased from the set voltage V0 to the set voltage V0 (Voff), the large power output OUT2 is stopped, and the setting When the low voltage output OUT1 is stopped after the delay time t4 and the battery voltage returns to the set voltage V3 or more, the low voltage output OUT1 is restored. When the battery voltage returns to the set voltage V0 or more A battery protection system in which the large power output OUT2 is also restored (FIG. 6) is characterized in that the output of a load (electronic device, etc.) is adjusted to the battery state and the output is adjusted to maintain the battery at its best state at all times.

The battery protection system according to the present invention appropriately adjusts the state of the load before the discharge end voltage of the secondary battery to adjust and stop the operation of the load before the battery reaches the discharge end voltage, To protect the battery by adjusting the output according to the battery condition, thereby preventing engine start-up and battery degradation caused by overdischarge of the battery and maintaining the best condition at all times.

1 is a schematic view showing a configuration of a battery protection system of the present invention.
2 is a diagram showing a change in output according to a change in an input voltage (B +) of a conventional or current battery protection system.
3 is a graph showing the input / output related to recovery of the low power output OUT1 and the large power output OUT2 when the input voltage B + of the battery protection system of the present invention changes from the set voltage V0 to the set voltage V1 As shown in Fig.
4 is a graph showing the input / output related to recovery of the low power output OUT1 and the large power output OUT2 when the input voltage B + of the battery protection system of the present invention changes from the set voltage V0 to the set voltage V2 As shown in Fig.
5 is a graph showing input and output relating to restoration of the low power output OUT1 and the large power output OUT2 when the input voltage B + of the battery protection system of the present invention changes from the set voltage V0 to the set voltage V3 As shown in Fig.
6 is a graph showing the input / output related to recovery of the low power output OUT1 and the large power output OUT2 when the input voltage B + of the battery protection system of the present invention changes from the set voltage V0 to the set voltage Voff As shown in Fig.

Hereinafter, a battery protection system according to the present invention will be described in detail with reference to the drawings.

FIG. 1 is a schematic diagram showing the configuration of a battery protection system according to the present invention. FIG. 2 is a diagram showing a change in output according to a change in an input voltage (B +) of a conventional or current battery protection system, Outlines related to restoration of the low power output OUT1 and the large power output OUT2 when the input voltage B + of the inventive battery protection system changes from the set voltage V0 to the set voltage V1 FIG. 4 is a graph showing the relationship between the input voltage (B +) of the battery protection system of the present invention and the input / output (I / O) related to the recovery of the low power output OUT1 and the large power output OUT2 when the input voltage B + changes from the set voltage V0 to the set voltage V2 And FIG. 5 is a graph showing a relationship between a low power output OUT1 and a high power output OUT2 when the input voltage B + of the battery protection system of the present invention changes from a set voltage V0 to a set voltage V3. ) Related to the recovery of FIG. 6 is a graph showing a relationship between a low-power output OUT1 and a high-power output when the input voltage B + of the battery protection system of the present invention changes from a set voltage V0 to a set voltage Voff OUT2 in FIG. 1 are graphically shown in a graph.

The present invention comprises a power input unit, an input signal processing unit, a control unit (microprocessor), and an output unit. The state (voltage) of the battery is divided into several stages as needed, And the output terminal for the load (device) is classified according to the output.

1, the battery protection system of the present invention includes a power input unit, an input signal processing unit, a control unit (microprocessor), an output unit (a large power output OUT2 or a low power output OUT1) .

The power input unit is an input unit of a power source for driving the control system. The input signal processor is a unit for converting a voltage of the power input unit to an input signal so that a control unit (microprocessor) can receive a signal. (Microprocessor) analyzes the input signal and analyzes the current battery status to generate an output control signal for output control. The output unit outputs the output control signal of the control unit (microprocessor) to a voltage And generates an output by dividing the output into a low-power output OUT1 and a high-power output OUT2. However, the present invention is not limited to the division between the low power output (OUT1) and the high power output (OUT2), and the output may be generated as a single load or a finely divided load if necessary.

As shown in FIG. 2, the current battery protection system controls the output on / off according to whether the battery voltage reaches the discharge end voltage (the set voltage Voff) only in accordance with the change of the input voltage B + The load of the vehicle requiring a lighthave power output causes problems such as failure in starting.

However, according to the present invention, as shown in FIGS. 3 to 6, the state (voltage) of the battery is divided into several stages (for example, set voltage V0, set voltage V1, set voltage V2, (Set voltage V1) when the engine is running and the generator also operates (set voltage V0), only the engine is running and the battery is charged well (voltage V3, set voltage Voff) , When the engine is running and the battery is not charging well (set voltage V2), when the engine is stopped and the battery is good (voltage setting V3), when the engine is stopped and the battery is poorly charged (For example, a heater, a motor, and the like) OUT2 and a low-power output (for example, a control power source, etc.) OUT1 by analyzing the load So that the output is controlled.

However, the distinction of the state of the battery (voltage) and the load of the output terminal for the load (instrument) is not limited to that described here.

More specifically, as shown in FIG. 3, when the battery voltage decreases from the set voltage V0 to the set voltage V1, the large power output OUT2 is stopped after the set delay time t1, When returning to the voltage V0 or more, the large power output OUT2 is recovered. Specifically, when the input voltage B + changes from the set voltage V0 to the set voltage V1, the large power output OUT2 is maintained within the set delay time t1, and when the set delay time t1 is elapsed, The power output OUT2 is stopped and the low power output OUT1 is maintained and the large power output OUT2 is restored when the input voltage B + reaches the set voltage V0.

Next, as shown in FIG. 4, when the battery voltage decreases from the set voltage V0 to the set voltage V2, the large power output OUT2 is stopped after the set delay time t2, (V0), the large power output (OUT2) is recovered. Specifically, when the input voltage B + changes from the set voltage V0 to the set voltage V2, the large power output OUT2 is maintained within the set delay time t2, and when the set delay time t2 is elapsed, The power output OUT2 is stopped and the low power output OUT1 is maintained and the large power output OUT2 is restored when the input voltage B + reaches the set voltage V0.

Next, as shown in FIG. 5, when the battery voltage decreases from the set voltage V0 to the set voltage V3, the large power output OUT2 is stopped after the set delay time t2, (V0), the large power output (OUT2) is recovered. Specifically, when the input voltage B + changes from the set voltage V0 to the set voltage V3, the large power output OUT2 is maintained within the set delay time t3, and when the set delay time t3 is elapsed, The power output OUT2 is stopped and the low power output OUT1 is maintained and the large power output OUT2 is restored when the input voltage B + reaches the set voltage V0.

Next, as shown in FIG. 6, when the battery voltage decreases from the set voltage V0 to the set voltage Voff, the large power output OUT2 is stopped, and after waiting for the set delay time t4, The low power output OUT1 is restored when the battery voltage returns to the set voltage V3 or more. When the battery voltage returns to the set voltage V0 or more, the large power output OUT2 Recovery. More specifically, when the input voltage B + changes from the set voltage V0 to the set voltage Voff, the large power output OUT2 is stopped and the low power output OUT1 is within the set delay time t4 The low power output OUT1 is restored and the input voltage B + is restored when the input voltage B + reaches the set voltage V3 with the low power output OUT1 being stopped when the set delay time t4 has elapsed. When the set voltage V0 is reached, the large power output OUT2 is also restored.

As described above, according to the present invention, the output of a load (electronic device, etc.) is adjusted to the battery state and the output is adjusted to maintain the battery at the best state at all times.

In the above example, the set voltages V0, V1, V2, V3, and Voff of the operating voltage or the return voltage of the input voltage B + can be arbitrarily set and changed.

The present invention can be applied not only to automobiles but also to all secondary batteries (lead accumulators, lithium batteries, etc.) capable of charging and discharging, and also applicable to automobiles, heavy equipment, ships and communication devices Is infinite.

B +: Input voltage
V0: Setting voltage (when the engine is running and the generator is running)
V1: Setting voltage (when engine is running and battery charge is good)
V2: Setting voltage (when only engine is running and battery charge is poor)
V3: Setting voltage (when the engine is stopped and battery charge is good)
Voff: Setting voltage (when the engine is stopped and battery charge is poor)
OUT1: Low power output (for example, control power, etc.)
OUT2: Large power output (for example, heater, motor, etc.)
t1, t2, t3, t4: delay time

Claims (6)

An input signal processing unit for converting an input signal so that a control unit (microprocessor) can receive a voltage change of the power input unit, an input signal processing unit for analyzing the input signal, (Microprocessor) for analyzing a current battery state to generate an output control signal for output control, and an output generating unit for converting an output control signal of the control unit (microprocessor) into a voltage capable of driving the apparatus and generating an output The battery protection system according to claim 1, wherein the battery state (voltage) is divided into a plurality of stages to analyze the battery state (voltage)
An output terminal of the output section is divided into a large power output (OUT2) and a low power output (OUT1)
When the engine is running and the generator is also running (set voltage V0), only the engine is running and the battery is good (set voltage V1), only the engine is running, When the engine is in a stopped state and the battery is poorly charged (set voltage Voff), the engine is in a stopped state (set voltage V2) In addition,
When the battery voltage decreases from the set voltage V0 to the set voltage V1, the large power output OUT2 is stopped after the set delay time t1, and when the battery voltage returns to the set voltage V0 or more, The power output OUT2 is restored and when the battery voltage decreases from the set voltage V0 to the set voltage V2, the large power output OUT2 is stopped after the set delay time t2, When the battery voltage is reduced from the set voltage V0 to the set voltage V3, the large power output OUT2 is restored after the set delay time t3, The output of the large power output OUT2 is restored when the battery voltage is restored to the set voltage V0 or more. When the battery voltage decreases from the set voltage V0 to the set voltage Voff, When the power output (OUT2) is stopped The low power output OUT1 is restored after the set delay time t4 and the low power output OUT1 is restored when the battery voltage returns to the set voltage V3 or more, And the large power output (OUT2) is also recovered when the battery power is restored to the high level. delete delete delete delete delete

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