JP3110462U - DC power automatic detection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect an operating state of DC power supply control under various load conditions and protect the DC power supply and its related work system from overcurrent when the DC power supply is abnormal.
An adjustable timer, a current detection and overcurrent protection device, a voltage detection and overvoltage protection device, and an overload protection device are included. Adjustable timer sets cycle of time period and automatically detects the operating status of DC power supply. The current detection and overcurrent protection device is used for level comparison / reference and current measurement. In the event of an abnormality, the operating electrical circuit is closed to protect the DC power supply and its associated work system from overcurrent.
[Selection] Figure 1

Description

  The present invention relates to a DC power supply automatic detection device that detects and displays a DC power supply, and particularly detects and displays a DC battery power supply status for a plurality of specified load conditions, and further protects the DC power supply. The present invention relates to a detection device.

Many DC power supply devices are used in industry and daily life. It is also very widely known that a DC power supply device is involved in energy conversion with an AC electricity supply system.
In order to prevent the system from being down due to overload of the DC power supply, the detection and protection electric circuit for the DC power supply has been used for a long time.

  However, in the conventional detection and protection techniques for DC power supplies, adjustments for optimization must be made according to the operating state of each DC power supply system.

The present invention has been made in view of the above points. The object of the present invention is to detect the operating state of the DC power supply under various load conditions and display the DC power supply system state, thereby providing a DC power supply system. It is an object of the present invention to provide an automatic DC power supply detection device that can prevent a malfunction of the DC power supply.
Another object of the present invention is to solve the problems of overvoltage, overcurrent, and overload caused by an abnormality in a generator, a traffic accident or a short circuit of an electric circuit by disconnecting the load of the DC power supply for the vehicle. An object of the present invention is to provide an automatic DC power supply detection device capable of providing a better selection for protection.

The first device of the present application is a direct-current power supply automatic detection device that protects against overvoltage, overcurrent, and overload by means of a protection device built in an electric circuit, and has both an electronic time counting device and an electronic multiplier device, It is composed of a timer circuit that can adjust the test cycle and an electronic switching circuit that has a function of switching the load and the display state in accordance with the power supply detection. The electronic switching circuit automatically supplies DC power supplies in various system forms. A plurality of load devices for detecting and displaying the state of the DC power source on the power source detection display device in comparison with an equal load according to a preset load condition, and a voltage signal detection device used for processing the voltage state And a current signal detection device used for processing the current state, and a direct current power supply protection device that protects the direct current power supply and its related work system. An overvoltage protection device for protecting the power source and related work system from overvoltage, an overcurrent protection device for protecting the DC power supply and related work system from overcurrent, and an overload protection device for protecting the DC power supply and related work system from overload When the DC power supply is abnormal, the operating electric circuit is closed to protect the DC power supply and its related work system from overcurrent.
A second device of the present application is the automatic DC power supply detection device according to the first device, wherein the DC power source is a battery system.
A third device of the present application is the DC power supply automatic detection device according to the first device, wherein the DC power supply is a vehicle battery system (vehicle power supply system using a battery and a dynamo).
A fourth device of the present application is the direct-current power supply automatic detection device according to the first device, wherein the load is a passive load system (a system in which a load can be arbitrarily set and applied).
A fifth device of the present application is the direct-current power supply automatic detection device according to the second device, wherein the load is a passive load system (a system in which a load can be arbitrarily set and applied).
A sixth device of the present application is the DC power supply automatic detection device according to the third device, wherein the load is a passive load system (a system in which a load can be arbitrarily set and applied).

The DC power supply automatic detection device according to the present invention can prevent a DC power supply system failure by detecting the operating state of the DC power supply under various load conditions and displaying the DC power supply system state.
Also, by disconnecting the load of the DC power supply for the vehicle, it is possible to solve the problems of overvoltage, overcurrent, and overload due to generator abnormalities, traffic accidents or electrical circuit short circuit, and provide better choice for vehicle power supply protection It is possible to provide a DC power supply automatic detection device that can be used.

FIG. 1 shows a preferred embodiment of the device.
The illustrated time counting circuit (timer circuit) 10 includes a time generation electric circuit 101, a counter electric circuit 102, and an AND logic gate 103.
The electrical connection relationship will be described below.
The time generation electric circuit 101 generates a fixed reference time, the output terminal of the time generation electric circuit 101 is coupled to the counter input terminal of the counter electric circuit 102, and the output terminal of the counter electric circuit 102 is connected to the AND logic gate 103. Coupling to the input end.
In this design example, in order to design the device more simply, an adjustable test period T = n T ′ adjusted to the counter electric circuit 102 with the fixed reference time T ′ generated by the time generating electric circuit 101 as a reference. To match various operating conditions required by the device.

In this design, when T = n T ′, the AND logic gate 201 is used to switch the device open and close.
The input terminal of the AND logic gate 201 is the output terminal of the AND logic gate 103, voltage detection, voltage abnormality protection electric circuit 302 of the overvoltage protection electric circuit 30, current detection and overcurrent protection electric circuit 404 of the overcurrent protection electric circuit 40. An operation circuit 20 is formed by electrical coupling with the output end.
The electrical operation circuit 20 obtains the input signal of the time counting circuit 100 from the electrical coupling location of the AND logic gate 103, and then conducts the device and starts the test.

The voltage detection and voltage abnormality protection electric circuit 30 includes a voltage detection electric circuit 301, a voltage abnormality protection electric circuit 302, an overvoltage closing electric circuit 303, and a low voltage closing electric circuit 304.
The voltage detection electric circuit 301 detects the load voltage and performs comparison.
The input terminal of the voltage detection electric circuit 301 is coupled to the load connected to the DC power supply and the output terminal of the voltage stabilization circuit 601 of the reference voltage electric circuit 60.
The voltage abnormality protection electric circuit 302 detects and protects the DC power supply.
The input terminal of the voltage abnormality protection electric circuit 302 is coupled to the output terminal of the voltage stabilizing circuit 601 of the DC voltage and reference voltage electric circuit 60.

The voltage detection electric circuit 301 compares the levels of the load voltage and the reference voltage Vref, and if the comparison result shows that the value exceeds the standard, the voltage detection electric circuit 301 transmits the warning signal to the overvoltage closing electric circuit 303.
Accordingly, the overvoltage signal lamp LED1 is turned on, the system operation is stopped by the overvoltage closing electric circuit 303, the load is protected, and a cut-off signal is sent to the AND logic gate 201 of the electric operation circuit 20. At the same time of transmission, the test process is stopped and then switched to the discharge mode to prevent battery burnout.

  The voltage abnormality protection electric circuit 302 compares the levels of the load voltage and the reference voltage Vref, and when the comparison result falls below the reference value, transmits a stop signal to the AND logic gate 201 of the electric operation circuit 20 to stop the test process. Or switch to discharge mode to prevent battery burnout.

The voltage detection electric circuit 301 may be an OP amplifier.
The overvoltage protection electric circuit 302 may be an OP amplifier.
However, the voltage detection electric circuit 301 and the overvoltage protection electric circuit 302 may be any components used in a differential electric circuit for voltage comparison / amplification in addition to the OP amplifier.
4013 IC may be used for the electric circuit 303 for the suspension.
However, the closing electrical circuit 303 may be any part used in the system closing electrical circuit in addition to the 4013 IC.

The current detection and overcurrent protection electric circuit 40 includes a current detection circuit 401, a current amplification circuit 402, and a current comparison circuit 403.
Further, the current comparison circuit includes a primary current comparison circuit 4031, a secondary current comparison circuit 4032, a current abnormality protection electric circuit 404, and an electric selection circuit 405.
The input terminal of the current detection circuit 401 is coupled to a direct current, and the output terminal is coupled to the input terminal of the current amplifier circuit 402.
The input terminal of the current amplification circuit 402 is coupled to the output terminal of the current detection circuit 401, and the output terminal is coupled to the current comparison circuit 403.
The input terminal of the primary current comparison circuit 4031 of the current comparison circuit 403 is coupled to the output terminal of the current amplification circuit 402, and the output terminal is coupled to the input terminal of the electrical selection circuit 405.
The input terminal of the secondary current comparison circuit 4032 of the current comparison circuit 403 is coupled to the output terminal of the current amplification circuit 402, and the output terminal of the secondary current comparison circuit 4032 of the current comparison circuit 403 is coupled to the electrical selection circuit 405. Coupling with the input control side.
The input terminal of the overcurrent protection electric circuit 404 is coupled to the input terminal of the current amplifier circuit 402, and the output terminal of the overcurrent protection electric circuit 404 is coupled to one terminal of the logic gate 201.
Coupling is performed on the input control side of the electric selection circuit 405 and the output terminal of the current comparison circuit 4031, and coupling is performed on the input control side of the electric selection circuit 405 and the output terminal of the current comparison circuit 4032.
The input terminal of the electric selector 405 and the DC power supply load side voltage are connected.
The output of the electrical selector 405 is coupled to the comparison circuits 501, 502, and 503 for the three outputs and the load, respectively, according to the signal at the input end.

The current detection circuit 401 acquires a power supply signal of a DC power supply, and converts the current signal into a voltage signal by induction of a coil.
The conversion ratio is determined by the primary side and secondary side coils.
Furthermore, the current / voltage conversion function serves to isolate the electric circuit, avoiding the influence of power overload of the electric control circuit, and at the same time serving the purpose of signal transmission and protection of the electric circuit.
The linear amplifier of the current amplifier circuit 402 catches the detection signal of the current detection circuit 401 and provides it for signal comparison and classification by the current comparison circuit 403, and also lowers the output resistance to increase the energy transmission efficiency.
The current comparison circuit 403 includes a primary current comparison circuit 4031 and a secondary current comparison circuit 4032 for classifying and analyzing radio waves.
Furthermore, a load value is determined in accordance with the load electricity selection circuit 405, and corresponds to a relative comparison line.
The load electrical selection circuit 405 is a level classification electrical circuit, which classifies and selects the voltage level of the current comparison electrical circuit 403 and sends the signal to the relative electrical circuit 50 of the load.
The current detection circuit 401 uses a Hall sensor.
However, the radio wave detection circuit 401 may be any component used for a current-voltage conversion circuit in addition to the Hall sensor.
The current amplification circuit 402 and the current comparison circuit 403 include a primary current comparison circuit 4031, a secondary current comparison circuit 4032, and an overcurrent protection electric circuit 404, and use an OP amplifier.
However, in addition to the OP amplifier, a differential electric circuit used for voltage comparison amplification may be used.
The load electricity selection circuit 405 uses a 4051 IC.
However, the load electrical selection circuit 405 may be any component used in the current classification electrical circuit in addition to the 4051 IC.
The currents in the truth table of 4051 IC are classified as follows.
When the current is less than 10 amps, it is considered unloaded.
(1) When the current is 10 amperes or more and less than 20 amperes, it is regarded as a primary load.
(2) When the current is 20 amps or more and less than 30 amps, it is regarded as a secondary load.
(3) When the radio wave is 30 amperes or more and less than 50 amperes, it is regarded as a tertiary load.
(4) When the current exceeds 50 amperes, the battery failure signal LED2 is turned on.

The load corresponding electrical circuit 50 includes a primary load corresponding comparison circuit 501, a secondary load corresponding comparison circuit 502, and a tertiary load corresponding comparison circuit 503.
Among them, each subsequent load includes one or more sets of display electric circuits and load electric current interruptions.
When the load states are different, a comparison is made by the electric selection circuit 405, and a corresponding electric circuit is determined in comparison with the current state.
When a signal corresponding to the voltage of the relative load is sent to any of the comparator circuits 501, 502, 503 corresponding to the load, when the load voltage is lower than the reference voltage level, the corresponding comparator reduces the alarm. Transmitting to the voltage closing circuit 304, the battery failure signal lamp LED2 is lit.

  The reference voltage electrical circuit 60 includes a voltage stabilization circuit 601 and provides a stable reference voltage Vref to the system.

Electrical circuit diagram of a better embodiment of the present invention Flow chart of the present invention Logic flow diagram of the present invention

Explanation of symbols

10 .... Time counting circuit (timer circuit)
DESCRIPTION OF SYMBOLS 101 ... Time generation electric circuit 102 ... Counter electric circuit 103 ... AND logic gate 20 ... Electric operation circuit 201 ... AND logic gate 30 ... · · · Overvoltage protection electrical circuit 301 · · · Voltage detection electrical circuit 302 · · · Voltage abnormality protection electrical circuit 303 · · · Overvoltage closure electrical circuit 304 · · · Undervoltage closure Electric circuit 40 ··· Overcurrent protection electric circuit 401 ··· Current detection circuit 402 ··· Current amplification circuit 403 ··· Current comparison circuit 4031 · · · Primary current comparison circuit 4032... Secondary current comparison circuit 404... Current abnormality protection electrical circuit 405... Electric selection circuit 50... Corresponding electrical circuit (load device)
501... Primary load corresponding comparator 502... Secondary load corresponding comparator 503. Tertiary load corresponding comparator 60... Reference voltage electric circuit 601.・ Voltage stabilization circuit

Claims (6)

A DC power supply automatic detection device that protects against overvoltage, overcurrent and overload by a protection device with built-in electric circuit,
A timer circuit that has both an electronic time counting device and an electronic multiplier device and is capable of adjusting the test cycle;
Consists of an electronic switching circuit having a load and display state switching function in accordance with power supply detection,
The electronic switching circuit automatically detects DC power supplies of various system forms, and displays a plurality of DC power supply states on a power supply detection display device in comparison with an equal load according to a preset load condition. A load device;
A voltage signal detection device used for processing the voltage state;
A current signal detector used to process the current state;
Consists of a DC power supply protection device that protects the DC power supply and related work systems,
The DC power supply protection device is
An overvoltage protection device for protecting the DC power supply and related work system from overvoltage;
An overcurrent protection device for protecting the DC power supply and related work system from overcurrent;
Consists of an overload protection device that protects the DC power supply and related work systems from overload,
When the DC power supply is abnormal, the operating electrical circuit is closed, and the DC power supply and related work system are protected from overcurrent.
DC power supply automatic detection device.   The DC power supply automatic detection device according to claim 1, wherein the DC power supply is a battery system.   The DC power supply automatic detection device according to claim 1, wherein the DC power supply is a vehicle battery system.   The DC power automatic detection device according to claim 1, wherein the load is a passive load system.   The DC power supply automatic detection device according to claim 2, wherein the load is a passive load system. The DC power supply automatic detection device according to claim 3, wherein the load is a passive load system.

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