KR20110083129A - Circuit for detecting a current - Google Patents

Abstract

PURPOSE: A current detecting circuit is provided to minimize the measuring error by offering a circuit for detecting load current. CONSTITUTION: An operational amplifier(U902-A) amplifies voltage difference created in both ends of a power supply circuit. The operational amplifier amplifies the minute voltage between a ground terminal(4) and the load side. The ground terminal of the power is connected to an inverting input(2) of the operational amplifier through an input resistor. The load side ground terminal is connected to a non-inverting input(3) of the operational amplifier.

Description

Circuit for detecting a current

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a current detection circuit, and more particularly, to a current detection circuit configured to be detected by a simple configuration of patented load current detection.

In many cases, it is necessary to detect the direction and magnitude of the current and use it for the control of the electric and electronic circuits, or send it to the outside and display and notify it. In particular, accurate current detection is essential in overcurrent protection circuits and constant current control circuits.

A method known in the related art as a method for measuring current is to measure the voltage across both resistances and impedances and calculate the current flowing in the formula V = IR and V = IZ. In the case of a large current, the loss in the resistance is large, so a shunt is made so that a large current flows into a very small resistance, and a small current flowing in the shunt is measured to convert the entire current.

However, a further improvement over this classical approach is that of a current detection circuit using a main FET and a detection FET in US Pat. No. 4,553,084.

1 is a circuit diagram of a current detection circuit disclosed in US Pat. No. 4,553,084. The main FET 11 is connected in series with a load 16 between the first power supply terminal 15 and the second power supply terminal 12. The detection FET 13 is connected in parallel with the main FET 11. This connection constitutes a second current path for the portion of the load current flowing through the load 16, and the comparator 15 also has a voltage at the resistor 14 according to the reference voltage applied to the terminal 12. The drop is compared and the output signal is generated from the output terminal 23 according to the comparison result. In such a circuit, the detection resistor 14 requires a small resistance value so as to maintain a good linearity of the current flowing through the resistor 14 compared to the load current, and the accuracy of the detection is determined by the accuracy of the resistor 14. However, it is not easy to have an accurate resistance value with a small resistance value.

Korean Patent No. 1993-0007482 discloses another current detection circuit. The invention disclosed herein includes a first MOS transistor 21 having a source-drain path connected in series with a gate electrode and a load 24 to generate a source-drain voltage in response to a load current, and an input to which an input signal is applied. A reference voltage generating means 20 and a first MOS transistor for generating a reference voltage Vr having a terminal 28, a second MOS transistor 22, and a constant current source 25 connected to the second MOS transistor 22; First circuit means (40) for generating an output voltage proportional to the source-drain voltage of (21), and comparing means (27) for comparing the output voltage of the first circuit means (40) with a reference voltage (Vr). It is configured to include a) and is a circuit designed to detect the load current flowing through the load (24).

Conventionally, current transformers (CT) are mostly used to detect or measure current. However, in this measurement, errors are about 20%, which is not accurate, and the current transformers are bulky and expensive.

In order to detect the magnitude of the load current using a conventional current detection circuit, the circuit is complicated by shunting the current path through which the load current flows, causing the classified current to flow through the voltage drop resistance, and comparing the voltage drop with a reference value. There was a problem.

It is an object of the present invention to provide a circuit capable of detecting a load current without specially installing a shunt unlike the prior art in which a shunt for classifying load currents has to be provided for current detection.

The present invention is to provide a voltage amplification circuit capable of accurate voltage detection by minimizing the measurement error even with temperature changes.

The present invention seeks to provide a circuit for accurately detecting a minute potential difference between the ground terminal on the power supply side and the ground terminal on the load side.

In the present invention, since all currents returned from the load return to the power supply and the current path connecting the current exit of the load and the current return point of the power supply has a resistance, the resistance, i.e., the resistance of both ends of the line resistance is weak. There is a potential difference, however, based on the idea that the magnitude of the load current can be known by detecting the potential difference.

The present invention provides a load current detection circuit, in which two inputs are respectively connected to both ends of the line resistance of the current path from the power supply to the load, for example, both ends of the line resistance between the power ground terminal and the load ground terminal. Comprising an operational amplifier for amplifying the minute voltage to be, and converts the output voltage of the operational amplifier into a load current to calculate the magnitude of the load current supplied from the power supply to the load.

As an embodiment of the present invention, the operational amplifier uses an inverting amplifier, the ground terminal of the power supply side is connected to the operational amplifier inverting input through the input resistor R922, the ground terminal of the load side is connected to the non-inverting input of the operational amplifier, The feedback resistor R923 is connected to the output terminal and the inverting input, and the voltage obtained by amplifying the minute voltage between the power supply ground terminal and the load side ground terminal, that is, the amount of voltage output to the output terminal is converted into a load current and supplied from the power supply to the load. Determine the magnitude of the load current.

Preferably, the present invention connects one or more temperature compensation diodes between the inverting input and the non-inverting input of the operational amplifier, and connects the same number of diodes as the same standard as the temperature compensation diode between the power supply ground terminal and the non-inverting input of the operational amplifier. By connecting in the opposite direction, these diodes are subjected to temperature changes, such as operational amplifiers, to reduce errors due to temperature changes.

In addition, additional capacitors are connected in parallel with the feedback resistors to maintain the stability of the circuit.

In another aspect, the present invention is a circuit for amplifying a weak voltage generated by the flow of current between the first terminal and the second terminal to detect the current between the terminals, which includes an operational amplifier having an inverting input and a non-inverting input, Connect the operational amplifier inverting input to the first terminal through the input resistor, connect the second terminal to the non-inverting input of the operational amplifier, connect the feedback resistor to the output terminal and the inverting input of the operational amplifier, and the inverting input of the operational amplifier. One or more temperature compensation diodes are connected between the non-inverting inputs, and between the first terminal and the second terminal, the same number of diodes as the same standard as the temperature compensation diodes are connected in opposite directions, and between the first terminal and the second terminal. Amplifying the weak voltage of the voltage, that is, the magnitude of the voltage output to the output terminal is converted into a load current to determine the magnitude of the current flowing from the first terminal to the second terminal And a current detection circuit.

The present invention can solve the problem of having to install the shunt in the prior art by providing a circuit capable of detecting the load current without providing a shunt for classifying the load current for current detection.

The present invention can provide a voltage amplification circuit capable of amplifying weak voltages with high amplification, minimizing measurement errors due to temperature changes, and making accurate voltage detection.

In the present invention, since the load current is determined by accurately detecting a minute potential difference between the ground terminal on the power supply side and the ground terminal on the load side, the circuit is simple and inexpensive, and can be installed separately from the power supply or the load. The load current can be detected at an objective position from the overload.

The present invention is a load current detection circuit, which is computed at both ends of the line resistance on either side of the current path from the power supply to the load, for example, at both ends of the power ground terminal and load ground terminal or between the output terminal of the power supply and the input terminal of the load. The two inputs of the amplifier are connected to each other to amplify the minute voltage dropped from the line, as well as the potential difference between any part of the line through which the load current passes, that is, the voltage drop is amplified by the operational amplifier and converted into the load current. It is very convenient to measure the load current because the input of the operational amplifier is connected by selecting the most suitable place even in the wire which is wired properly.

1 is a circuit diagram of a conventional current detection circuit.
2 is a circuit diagram of a current detection circuit according to an embodiment of the present invention.

An embodiment of the present invention will be described with reference to the drawings.

2 is a view showing an embodiment of the present invention.

In this embodiment, the power supply rectifies AC power to supply DC to the load. One electrode of the DC power source, that is, the + terminal or the-terminal is grounded.

The load receives the voltage from the power supply and uses the power to operate electronic devices such as electronic circuits or motors. In the load side, the same polarity as that of the ground electrode of the power source is grounded as in the power source side.

In this circuit, the load current flows through the line by the amount of power used in the load through the power supply line on the power supply side. The power supply and the load may be located in spatially separated locations, or may be in adjacent spaces or in the same PCB. In either case, the current supplied by the power supply will return to the supply after the load has been applied. Therefore, there is a difference in potential between the ground potential at the power supply and the ground potential at the load. In other words, since there is a resistance Rs in the line, the potential of the current outlet and the current inlet of the power supply is higher or lower than the potential of the current inlet and the current outlet of the load side. Thus, the potential difference Vr occurs. This potential difference becomes very small when the current is small or the line resistance of the current path is small. It is very difficult to detect this weak potential.

The present invention starts on the basis that even a very small potential difference that is difficult to detect can be amplified to make it a meaningful signal.

In the present invention, a weak voltage is amplified using a high amplification amplifier such as an operational amplifier having an infinite amplification degree in theory.

As shown in Fig. 2, there is a slight potential difference Vr between the ground terminal INPUT on the power supply side and the ground terminal 4 on the load side, and it is based on the technical idea that the magnitude of the load current can be known by detecting the potential difference. .

The load current detecting circuit of the present invention includes an operational amplifier (U902-A) for amplifying a minute voltage between the ground terminal (INPUT) on the power supply side and the ground terminal (4) on the load side, and the output terminal (1) of the operational amplifier (1). Convert the output voltage of to load current magnitude.

The operational amplifier can be connected to an inverting amplifier, connected to the operational amplifier inverting input (2: "-") through the input resistor (R922) at the ground terminal of the power supply side, and the ground terminal of the load side of the operational amplifier non-inverting input (3). : Connect "+"), connect the feedback resistor (R923) to the output terminal (1) and the inverting input of the operational amplifier, and further connect the capacitor (C921) in parallel with the feedback resistor. This embodiment is an inverting operational amplifier whose amplification degree is A = R923 / R922, and the output voltage is as follows.

Voutput = -Vinput (R923 / R922)

Determines the magnitude of the load current supplied from the power supply to the load by converting the voltage obtained by amplifying the minute voltage between the power supply ground terminal and the load side ground terminal, that is, the voltage output to the output terminal, into the digital processor and converting it into the load current. do.

Here, the amplification degree of the load current detection circuit should always be constant. However, since the electronic circuit is composed of elements whose characteristics change with temperature change, the amplification also decreases or increases. Thus, a circuit is added to compensate for this characteristic change with temperature.

A circuit added for temperature compensation is a preferred example of connecting one or more temperature compensating diodes D917 and D918 between the inverting input 2 and the non-inverting input 3 of the operational amplifier. Between the non-inverting input 3, i.e., the load-side ground terminal 4, the same size and the same number of diodes D915 and D916 as the temperature compensation diode are connected in opposite directions, so that these diodes are connected to other electronic components. By receiving a temperature change, such as to reduce the error of the current detection circuit due to the temperature change.

In addition, the capacitor C920 is connected in parallel with the diodes to reduce the miscellaneous signal, and the capacitor C921 is connected to both ends of the feedback resistor so that the circuit operates stably. In this embodiment, two diodes are used, but they can be increased or decreased depending on the potential difference.

This configuration is a circuit for detecting the current between the terminals by amplifying a weak voltage generated due to the current flow between the first terminal (INPUT) and the second terminal (4), which is not compared with the inverting input (2) The operational amplifier U902-A having the inverting input 3 and the first terminal are connected to the operational amplifier inverting input 2 through the input resistor R922, and the second terminal 4 is connected to the operational amplifier non-inverting input. (3), the feedback resistor (R923) is connected to the output terminal (1) and the inverting input (2) of the operational amplifier, and one or more temperature compensation diodes (D917, D918)) and connect the same number of diodes (D915, D916) as the same specifications as the temperature compensation diode between the first terminal and the second terminal so that the diode polarity is in the opposite direction, Compensation for temperature characteristic change and weak voltage between the first and second terminals The amount of the current flowing from the first terminal to the second terminal is determined by converting the amplified voltage, i.e., the voltage output to the output terminal 1, into a load current. In this case, the relationship between the load current and the voltage may be prepared in advance by a graph, and the current value may be determined, but it is cumbersome to use the digital process to convert the output voltage into a digital value and convert it into a current. Conversion and temperature compensation or control program may be processed by the microprocessor.

The operation of the circuit of the present invention will be briefly described as follows.

In the case where the + electrode is directed to the load at the power supply side and the-electrode is grounded at the power supply, the secondary ground potential becomes + more than the power supply ground potential, and the difference is called a ground potential difference.

If the input resistance of the operational amplifier is considered to be infinite, and there is no input current, the ground potential difference is applied to the reverse resistance of the diode and the input resistance R922 and divided in proportion to the resistance value. will be. In reality, however, some input current flows and a reverse current flows in the diode connected in the reverse direction. The ground potential difference is not large enough for the forward diodes to conduct (or increase the number of diodes if the voltage is high), but the potential difference is applied to the resistance of the forward diodes so that a weak current flows in the forward direction.

The operational amplifier amplifies the potential difference input to the inverting input 2 by the ratio of the input resistance R922 and the feedback resistor R923 and outputs it to the output terminal 1. Capacitor C921 serves to smooth the ingress across feedback resistor R923, and capacitor C920 passes and removes high frequency noise mixed in the ground potential difference.

In addition, the diodes are designed to maintain a constant degree of amplification in the current detection circuit stably with temperature changes, and diodes connected in the forward and reverse directions cancel out characteristic changes due to temperature rise and fall.

When the ground potential difference is amplified and the output voltage is displayed, it can be displayed on the gauge, or can be displayed on a digital device, or can be used as a signal to control another device by using this current. When the current value increases above a certain value, that is, when the current value exceeds a predetermined value, the overcurrent protection circuit may be operated to cut off the power supply or to operate the alarm device.

Since the circuit of the present invention can be used in various circuits, many application circuits can be made in addition to the embodiments shown herein.

1: op amp output terminal, 2: op amp inverting input,
3: op amp non-inverting input, 4: ground terminal,
Rs: line resistance, Vr: potential difference: voltage drop, C920, C921: capacitor,
U902-A: operational amplifier, R922: input resistance, R923: feedback resistor,
D917, D918: Diode

Claims (5)

It includes an operational amplifier for amplifying the potential difference generated across the line resistance of the power supply circuit installed in order to supply power to the load from the power supply, and converts the output voltage of the operational amplifier into a load current to supply to the load from the power supply A load current detection circuit characterized by calculating the magnitude of the load current. The method according to claim 1,
The operational amplifier uses an inverting amplifier,
Connect the ground terminal of the power supply to the operational amplifier inverting input through the input resistor R922,
Connect the ground terminal of the load side to the operational amplifier non-inverting input,
Connect the feedback resistor R923 to the output terminal and the inverting input of the operational amplifier.
Load current detection characterized by determining the magnitude of the load current supplied from the power supply to the load by converting the magnitude of the amplified minute voltage between the power supply ground terminal and the load side ground terminal, that is, the voltage output to the output terminal, into the load current. Circuit. The method according to claim 2,
Connect one or more temperature compensation diodes between the inverting and non-inverting inputs of the operational amplifier,
A load current detection circuit characterized by reducing errors in temperature change by connecting the same number of diodes as the same as the temperature compensation diode in the opposite direction between the power supply ground terminal and the non-inverting input of the operational amplifier.
The method according to claim 3,
And a capacitor is further connected in parallel with the feedback resistor R923.
In a circuit for detecting a current between the terminals by amplifying a weak voltage generated by the flow of current between the first terminal and the second terminal,
An operational amplifier with inverting and non-inverting inputs,
Connect to the operational amplifier inverting input through the input resistor to the first terminal,
Connect the second terminal to the op amp non-inverting input,
Connect the feedback resistor to the output terminal and the inverting input of the operational amplifier,
Connect one or more temperature compensation diodes between the inverting and non-inverting inputs of the operational amplifier,
Between the first terminal and the second terminal by connecting the same number of diodes of the same specification as the temperature compensation diode in the opposite direction,
The magnitude of the current flowing from the first terminal to the second terminal is determined by converting the voltage obtained by amplifying the weak voltage between the first terminal and the second terminal, that is, the voltage output to the output terminal into the load current. Load current detection circuit.

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