KR100835645B1 - Reed switch position transmitter module used in control system of nuclear plant - Google Patents

Abstract

The present invention is provided by separating the input and output signal and the power supply, and by converting the position signal of each control rod to a voltage through a plurality of channels in one electronic control module to configure a circuit resistant to noise to reduce the malfunction of the nuclear power plant Reed switch position transmission module used in the control system.

The present invention provides a connector, which receives an operating power source from the outside and inputs and outputs the input signal and the output signal separately; A first channel unit converting the first position signal of the control rod included in the input signal transmitted from the connector into a first voltage signal and outputting the first voltage signal; A second channel unit converting the second position signal of the control rod included in the input signal transmitted from the connector into a second voltage signal and outputting the second voltage signal; And a direct current / direct current converter configured to convert operating power provided from the connector into power of different intensities so as to drive the first channel unit and the second channel unit, respectively, and to supply the first channel unit and the second channel unit. Characterized in that made.

Reed Switch, Channel, Connector, Power, Nuclear Power, Control, Position Transfer Module

Description

Reed switch position transmitter module used in control system of nuclear plant}

1 is a block diagram schematically showing the configuration of the reed switch position transmission module used in the nuclear power plant control system according to an embodiment of the present invention.

2 is a circuit diagram illustrating in detail a reed switch position transmission module used in the nuclear power plant control system shown in FIG.

FIG. 3 is a circuit diagram illustrating a mode selector and a position signal converter of the first channel unit shown in FIG. 2.

FIG. 4 is a circuit diagram illustrating a filter unit of a first channel unit illustrated in FIG. 2.

FIG. 5 is a circuit diagram illustrating a mode selector and a position signal converter of the second channel unit shown in FIG. 2.

FIG. 6 is a circuit diagram illustrating a filter unit of the second channel unit illustrated in FIG. 2.

FIG. 7 is a circuit diagram illustrating a DC / DC converter and a connector illustrated in FIG. 2.

<Description of the symbols for the main parts of the drawings>

10: connector 20: first channel portion

30: second channel portion 40: DC / DC converter

The present invention relates to a reed switch position transmission module, and is provided with a separate input and output signal and power, and a circuit resistant to noise by providing a position signal of each control rod to a voltage through a plurality of channels in one electronic control module It relates to a reed switch position transmission module used in the control system of the nuclear power plant by reducing the malfunction.

Numerous nuclear power plants are being constructed to cope with the recent surge in energy demands, but the maintenance and maintenance of such nuclear power plants requires a lot of cost and technology, and there is always a risk that a large-scale safety accident may occur. have.

In other words, in the nuclear power plant, it is necessary to have a control system that is very stable and reliably operated compared to other general plants or power plants due to the use of nuclear fuel, and the electronic control module used in such a control system malfunctions even in the environment of a high vibration power plant. This requires high reliability.

Conventional reed switch position transmission module used in the nuclear power plant as described above typically performs the following four functions.

First, the position signal of the control rod is converted into a voltage.

Second, an inverting circuit and a non-inverting circuit are configured by using an operational amplifier for the converted output signal.

Third, the circuit is configured to output only a limited range of signals, and the final output signal is not separated into the input signal and the circuit.

Fourth, input signals and output signals are processed through one channel in one module.

However, in the conventional reed switch position transfer module that performs the above function, one module is provided in one module to perform this function, and thus, many modules are required. Compared to the function, the actual size of the printed circuit board is increased. Due to its size, there is a problem in that it takes up a lot of space in a subrack and a cabinet in a nuclear power plant.

In addition, in the conventional reed switch position transfer module, since an input signal and an output signal are not separated from each other, elements such as resistors and capacitors are used to reduce noise generated therefrom, thereby increasing the probability of malfunction. .

In addition, the conventional reed switch position transfer module has a problem that the test procedure is complicated because the state can be verified after the module is directly isolated from the system.

The present invention is to solve the above-mentioned problems of the prior art, it is provided by separating the input and output signals and power, and by providing a position signal of each control rod to a voltage through a plurality of channels in one electronic control module to provide noise It is an object of the present invention to provide a reed switch position transmission module used in a control system of a nuclear power plant to reduce malfunction by constructing a strong circuit.

In order to achieve the above technical problem, the reed switch position transmission module used in the nuclear power plant control system according to the present invention includes a connector for receiving an operating power from the outside, the input signal and the output signal are input and output separated; A first channel unit converting the first position signal of the control rod included in the input signal transmitted from the connector into a first voltage signal and outputting the first voltage signal to the connector; A second channel unit converting the second position signal of the control rod included in the input signal transmitted from the connector into a second voltage signal and outputting the second voltage signal to the connector; And a direct current / direct current converter configured to convert operating power provided from the connector into power of different intensities so as to drive the first channel unit and the second channel unit, respectively, and to supply the first channel unit and the second channel unit. Characterized in that made.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

Referring to Figures 1 to 7 describes the configuration of the reed switch position transmission module used in the nuclear power plant control system according to the present invention, Figure 1 is a reed switch used in the nuclear power plant control system according to an embodiment of the present invention. 2 is a block diagram schematically illustrating a configuration of a position transmission module, and FIG. 2 is a circuit diagram showing in detail a reed switch position transmission module used in a nuclear power plant control system shown in FIG. 1, and FIG. 3 is a first channel shown in FIG. 2. FIG. 4 is a circuit diagram illustrating a negative mode selector and a position signal converter. FIG. 4 is a circuit diagram illustrating a filter unit of the first channel unit shown in FIG. 2, and FIG. 5 is a mode selector and position signal converter of the second channel unit illustrated in FIG. 2. 6 is a circuit diagram illustrating a filter unit of the second channel unit illustrated in FIG. 2, and FIG. 7 is a DC / DC converter and a controller illustrated in FIG. 2. A circuit diagram of the emitter.

Reed switch position transmission module used in the nuclear power plant control system of the present invention shown in Figures 1 to 7 is a connector 10, the first channel portion 20, the second channel portion 30 and the DC / DC converter And 40.

The connector 10 receives operating power from the outside and provides the DC / DC converter 40 to the DC / DC converter 40 and separates the input signal and the output signal from the first channel part 20 and the second channel part 30, respectively. It is configured to be.

At this time, the connector 10 is a DIN41612 standard connector is used to facilitate expansion, it is preferable that the back of the module is provided.

The first channel unit 20 converts the first position signal of the control rod transmitted from the connector 10 into a first voltage signal and outputs the first voltage signal to the connector 10. The first mode selection unit 22 and the first position The signal converter 24 and the first filter unit 26 are included.

The first mode selector 22 selects from a test mode for testing the state of the reed switch position transfer module or an actual mode for executing an operation of the actual reed switch position transfer module.

As shown in FIG. 3, when the switch SW1 is operated as a switch for a mode, and the test mode is selected by the first mode selector 22, TP1, TP2, and TP3 provide virtual input signals. This can be confirmed in TP4 and TP5.

If the first mode selection unit 22 is switched to the actual mode, the 15V power is input to drive the position indicator assembly.

At this time, since the position indicator assembly is connected by a voltage divider circuit connected to the reed switch and the resistor, a voltage signal corresponding to the closing of each reed switch is output.

That is, the output power varies from 3.0V to 9.8V according to the position of the permanent magnet (position of the control rod), and a voltage change of 0.2V occurs every time the permanent magnet is moved 20mm.

Therefore, the value of the corresponding output signal is verified by the following equation (1).

.....(1)

.....(One)

The R _POSITION represents a resistance value of the position to be dispensed.

The first filter unit 26 filters the noise of the voltage signal converted by the first position signal converter 24, and separates the filtered signal from the input signal and the operating power to the connector 10.

 As shown in FIG. 4, in the first filter unit 26, U1 separates an input signal and an output signal and separates the driving power in the circuit, and removes feedthrough noise of the power supply. A pi filter is provided, and an output filter U4 capable of removing 500 mW carrier ripple is provided at the final output end.

That is, the input signal of the first filter unit 26 is input through U2, and is obtained by the RC filter as a circuit for separating signal components by removing high frequency noise components from the outside, and the cutoff frequency is 398 kHz. At this time, U2 functions as a low pass filter, and U3 acts as a buffer for the input signal through the filter.

The second channel unit 30 converts the second position signal of the control beam transmitted from the connector 10 into a second voltage signal and outputs the second voltage signal to the connector 10. The position signal converter 34 and the second filter 36 are included.

The second mode selector 32 selects from a test mode for testing a state of the switch position transfer module or an actual mode for executing an operation of the actual switch position transfer module.

As shown in FIG. 5, the switch SW2 is operated as a switching switch for the mode, and when the test mode is selected in the mode selector 32, TP6, TP7, and TP8 provide virtual input signals. This can be seen in TP9 and TP10.

If the second mode selection unit 22 is switched to the real mode, a 15V power source is input to drive the position indicator assembly.

At this time, since the position indicator assembly is connected by a voltage divider circuit connected to the reed switch and the resistor, a voltage signal corresponding to the closing of each reed switch is output.

That is, the output power varies from 3.0V to 9.8V according to the position of the permanent magnet (position of the control rod), and a voltage change of 0.2V occurs every time the permanent magnet is moved 20mm.

Therefore, the value of the corresponding output signal is verified by the following equation (2).

.....(2)

.....(2)

The R _POSITION represents a resistance value of the position to be dispensed.

The second filter unit 36 filters the noise of the voltage signal converted by the second position signal converter 34, and separates the filtered signal from the input signal and the operating power to the connector 10.

As illustrated in FIG. 6, in the second filter unit 36, U1 separates an input signal and an output signal and separates the driving power in the circuit, and removes the feedthrough noise of the power supply. π) filter is provided, and an output filter U4 for removing 500 mW carrier ripple is provided at the final output end.

That is, the input signal of the second filter unit 36 is input through U7, and is obtained by the RC filter as a circuit for separating signal components by removing high frequency noise components from the outside, and the cutoff frequency is 398 kHz. At this time, U7 functions as a low pass filter, and U8 acts as a buffer for the input signal through the filter.

The DC / DC converter 40 converts the operating power provided from the connector 10 into power of different intensities so as to drive the first channel unit 20 and the second channel unit 30, respectively. Supply to the unit 20 and the second channel unit 30.

As shown in FIG. 7, the DC / DC converter 40 receives a single + 15V power supply from the connector 10 to supply + 15V and -15V power to the first channel unit 20 and the second channel unit. Four power sources separated by circuits are provided to supply 20 to each.

Those skilled in the art to which the present invention pertains will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. Therefore, the above-described embodiments are to be understood as illustrative in all respects and not as restrictive.

As described above, the reed switch position transmission module used in the control system of the nuclear power plant according to the present invention is provided with a separate input and output signal and power, the position of each control rod through a plurality of channels in one electronic control module By converting the signal into voltage and providing it, a noise-resistant circuit is formed to reduce malfunctions.

In addition, by designing and configuring for the 3U size of the VME bus specification, subracks and cabinets can be reduced in nuclear plants.

In addition, testing and operation can be easily applied without isolating the reed switch position transfer module from the system.

Claims (6)

In the reed switch position transmission module used in the nuclear power plant control system, A connector which receives an operating power from an external source and inputs and outputs the input signal and the output signal separately; A first channel unit converting the first position signal of the control rod included in the input signal transmitted from the connector into a first voltage signal and outputting the first voltage signal to the connector; A second channel unit converting the second position signal of the control rod included in the input signal transmitted from the connector into a second voltage signal and outputting the second voltage signal to the connector; And Including a DC / DC converter for converting the operating power provided from the connector to the power of different strength to supply the first channel portion and the second channel portion to drive the first channel portion and the second channel portion, respectively Reed switch position transmission module used in the nuclear power plant control system, characterized in that made. The method of claim 1, The first and second channel units, respectively A mode selection unit for selecting from a test mode for testing a state of the reed switch position transfer module or an actual mode for executing an operation of an actual reed switch position transfer module; A position signal converter converting the position signal of the control rod input according to the mode selected by the mode selector into a voltage signal and outputting the voltage signal; And And a filter unit for filtering out noise of the voltage signal converted by the position signal converting unit and separating the filtered signal from the input signal and operating power and providing the connector to the connector. Reed switch position transfer module. The method of claim 2, When the test mode is selected in the mode selector, the position signal of the virtual control rod is input to the position signal converter. When the actual mode is selected in the mode selector, the position signal of the actual control rod is input to the position signal converter. Reed switch position transmission module used in the nuclear power plant control system, characterized in that the input. The method of claim 2, The position signal converting unit converts 15V input power into 3.0-9.8V according to the position of the control rod and outputs the output power, and the output voltage changes by 0.2V whenever the position of the control rod is moved 20mm. Reed switch position transfer module used in the control system. The method of claim 2, The filter unit is a reed switch position transmission module for use in a nuclear power plant control system, characterized in that it comprises a pie filter for removing feedthrough noise of the power source. The method of claim 1, The DC / DC converter receives + 15V power from the connector and supplies + 15V and -15V power through four lines to the first and second channel parts, respectively. Reed switch position transfer module used.

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