JP4049064B2 - Signal transmission device - Google Patents

Description

  The present invention relates to a signal transmission device that transmits a weak detection signal from a monitor or the like, and particularly transmits a weak current signal that is a detection signal of a neutron flux monitor (hereinafter abbreviated as SRNM) in a nuclear reactor in a nuclear power plant. The present invention relates to a signal transmission device suitable for the above.

In the signal transmission device, when transmitting the detection signal from the SRNM, the signal is converted into a voltage signal by a preamplifier in the middle of the transmission path, and is amplified and transmitted to the monitoring unit. In order to drive the preamplifier, a power source is required, and noise from an external device may be mixed into the cable that supplies the power. Since the noise frequency band from the external device is several hundred Hz to several MHz and the frequency of the detection signal is several hundred kHz to several tens of MHz, there is a problem that a part of the mixed noise is superimposed on the detection signal.

  For this reason, the conventional signal transmission apparatus uses a coaxial shield wire for the power supply cable, and further suppresses the generation of noise by separating the signal transmission cable and the power supply cable. Incidentally, a method for covering a conduit with an electromagnetic shield to enhance the shielding function is disclosed in Japanese Patent Laid-Open No. 2000-56027.

JP 2000-56027 A

  The conventional technology has a shielding effect against noise from an external device or an external transmission line, but is less effective against noise mixed from a connected device. Also, depending on the plant, the signal transmission cable and the power supply cable may be laid on the same conduit between the preamplifier and the monitoring unit, and it is clear that various noises may occur due to interference between the lines. Became.

A specific noise mixing route will be described with reference to FIG. In a system that transmits a weak current signal, the signal is amplified by the preamplifier 401 and transmitted to the monitoring device 402. Here, a case where a signal transmission cable (core wire 404, shield 405) and a power supply cable (core wire 406, shield 407) are laid in the same conduit 403 will be described. In the preamplifier 401, the core wire 404 of the signal transmission cable receives a signal from the preamplifier circuit 410, and the core wire 406 of the power supply cable is connected to the minute power input side of the preamplifier circuit 410. The shields 405 and 407 of both cables are connected to the housing of the preamplifier 401. In the monitoring device 402, the signal transmission cable core 404 is connected to the signal output terminal 408, and the power supply cable core 406 and the shield 407 are connected to the power supply 409. In this configuration, electromagnetic noise from an external device is simultaneously mixed into the core wire and the shield, and is superimposed as common mode noise (A in FIG. 4). Further, since the signal cable and the power supply cable are laid close to each other, it has been found that normal mode noise is mixed from the signal cable to the power supply cable by electrostatic induction (B in FIG. 4). Further, since both shields 405 and 407 are short-circuited through the frame in the preamplifier 401, there is a noise C that circulates there from, and this also becomes normal mode noise. Furthermore, noise D induced from the shield 407 of the power supply cable to the core wire also becomes normal mode noise. Among the A, B, C, and D noises, the external noise frequency of A is several hundred Hz to several MHz, but B, C, and D are mixed from the signal transmission cable, and the frequency Also, the frequency of the detection signal is almost the same as several hundreds of kHz to several tens of MHz. Here, the preamplifier circuit 410 is provided with a capacitor 411, which cuts DC voltage and low-frequency noise from the power supply cable, and against the noises of A, B, C, and D. There is almost no reduction effect. Therefore, these noises are amplified by the amplifier 412 and mixed into the core wire 404 of the signal transmission cable. Furthermore, a part thereof is mixed again with the core wire 406 of the power supply cable to form a loop and further amplified.

  In order to solve the new problems as described above, an object of the present invention is to mix a signal transmission cable in a signal transmission device that transmits a weak detection signal from a monitor or the like, particularly an SRNM detection device in a nuclear power plant. An object of the present invention is to provide a signal transmission device that reduces noise and ensures good signal transmission.

  In order to solve the above problems, a signal transmission device according to a first invention of the present application includes a detector that outputs a neutron flux of a nuclear reactor as a detection signal, a cable that transmits the detection signal, and an amplification of the detection signal A preamplifier for the output signal, a signal transmission cable for transmitting the output signal from the preamplifier, a power supply cable for supplying power to the preamplifier, and a monitoring unit for outputting the state of the neutron flux based on the output signal; In the signal transmission device having the above, the power supply cable is provided with a filter for attenuating a high frequency signal.

  In order to solve the above problem, the signal transmission device according to the second invention of the present application is configured to use a coaxial shielded cable as the power supply cable, and uses the ferrite as the filter according to the first invention to supply the power. The cable is installed close to the outside of the preamplifier so that the cable penetrates.

  In order to solve the above problem, the signal transmission device of the third invention of the present application uses ferrite as the filter of the first invention and installs it so as to surround the power supply cable inside the preamplifier. It is characterized by this.

  In order to solve the above problem, the signal transmission device of the fourth invention of the present application uses an LC filter as the filter of the first invention, and is installed by being inserted into a power supply line inside the preamplifier. It is characterized by.

  In order to solve the above problems, a signal transmission device according to a fifth aspect of the present invention uses a coaxial shielded cable as the signal transmission cable and the power supply cable according to the first aspect of the invention, and shields the signal transmission cable. And the shield of the power supply cable is insulated.

  As a result, according to the signal transmission device of the first invention of the present application, it becomes possible to reduce noise mixing into the signal line, and as a result, it is good even if the signal cable and the power supply cable are laid on the same conduit. Signal transmission can be realized.

  Further, according to the signal transmission device of the second invention of the present application, it is possible to realize a case where noise is applied to both the core and shield of the power supply cable, that is, to reduce common mode noise.

  Further, according to the signal transmission device of the third invention of the present application, when noise is applied to either the core wire or the shield of the power supply cable or when one of the noise levels is high, that is, normal mode noise is reduced. Can be realized.

  Further, according to the signal transmission device of the fourth invention of the present application, it is possible to selectively specify the frequency of noise to be removed with respect to the noise in the normal mode, and it is possible to realize more efficient noise reduction.

  In addition, according to the signal transmission device of the fifth invention of the present application, it is possible to prevent the mixing of noise that wraps around through the shield.

  As described above, according to the invention of the present application, in a signal transmission device of a nuclear power plant, normal mode noise such as normal mode noise from outside, induction noise between signal transmission cable and power supply cable, sneak noise, leakage noise, etc. Noise can be reduced, and appropriate measurements can be performed with minimal effects on the measurement system that measures very weak signals. Safety and operation of nuclear power plants Tolerance can be secured.

[First embodiment]
The 1st Example of this invention is shown. An SRNM measuring device for a nuclear power plant will be described with reference to FIGS. 1 and 2. In FIG. 1, a start-up region fission ionization chamber 103 housed in a dry tube 102 inserted into a reactor pressure vessel 101 generates a weak current of several μA due to ionization by thermal neutrons in the reactor. This weak current signal is transmitted to the preamplifier 106 installed outside the reactor containment vessel 105 by the weak current transmission cable 104. Further, the signal is transmitted to the SRNM processing apparatus 110 outside the reactor building 109 by the SRNM signal transmission cable 107. The preamplifier 106 is supplied with DC power using a preamplifier power supply cable 108. The weak current transmission cable 104, the SRNM signal transmission cable 107, and the preamplifier power supply cable 108 are protected by a thick steel conduit 111.

The space between the preamplifier and the SRNM processing apparatus in FIG. 1 will be described in detail with reference to FIG. SRNM signal transmission cable 107 and preamplifier power supply cable 108 are both coaxial shielded cables (core wire 201 of SRNM signal transmission cable, shield 202 of SRNM signal transmission cable, core wire 203 of preamplifier power supply cable, shield 204 of preamplifier power supply cable). Is used. Within the preamplifier 106, the weak current from the activation region fission ionization chamber 103 input from the weak current transmission cable 104 is charged and amplified by the preamplifier circuit 207 and transmitted by the SRNM signal transmission cable 107. On the other hand, in the SRNM processing device 110, the core wire 201 of the SRNM signal transmission cable is connected to the signal output end 205, and the core wire 203 and the shield 204 of the preamplifier power supply cable 108 are connected to the DC power source 206. Here, in order to cut the external noise A described in FIG. 4, the common mode noise removing ferrite 208 is attached to the preamplifier power supply cable 108. Ferrite is an impedance element having an impedance peak from several tens of MHz to several hundreds of MHz, and the attenuation can be further increased by installing one or more, ideally a plurality. Since the external noise A, which is common mode noise, is mainly mixed on the cable and transmitted to the preamplifier, the common mode noise removing ferrite 208 is attached to the end of the cable, that is, the portion connected to the preamplifier 106 as much as possible. Thereby, it is possible to reduce common mode noise.

  Further, since the signal transmission cable and the power supply cable are installed close to each other, electrostatic induction occurs, and the induction noise B is mixed into the power supply cable from the signal transmission cable. Further, leakage noise C from the shield to the core wire is generated at the portion where the power supply cable is connected to the preamplifier. Inductive noise B and leakage noise C are normal mode noise, and in order to cut them, normal mode noise removing ferrite 209 is attached to the core line portion in preamplifier 106. Also, it is desirable to attach as close to the power supply point 210 as possible in order to prevent mixing into the signal line. As described above, the frequency of the normal mode noise to be superimposed here is mainly a component of several hundreds kHz to several tens of MHz, which is the same as the signal frequency, but the ferrite has characteristics sufficient to cut noise in these bands. Use things. Thereby, it is possible to reduce normal mode noise.

Further, in order to suppress the wraparound from the signal cable to the power cable in FIG. 4, the shield of the preamplifier power supply cable is not grounded to the SRNM processing device 110 but to an external grounding point that is not connected to the casing of the SRNM processing device 110. It is possible to prevent noise from entering through the shield by grounding with the device outside earth 211 and providing the non-ground shield 212 in the preamplifier 106 without grounding.
[Second Example]
A second embodiment of the present invention will be described with reference to FIG. This embodiment, like the first embodiment, relates to an SRNM signal transmission device for a nuclear power plant, and differs from the first embodiment in terms of normal mode noise removal means. The same one as in the first embodiment is used. Only differences from the first embodiment will be described below. In the present embodiment, in order to cut the induction noise from the signal cable to the power cable and the leakage noise from the shield to the core wire, a normal mode noise removing LC filter 301 is attached to the core wire portion in the preamplifier 106. . In order to prevent these noises, which are normal mode noises, from entering the signal line, the normal mode noise removing LC filter is preferably attached near the power supply point 210.

  According to this embodiment of the present invention, regarding the noise in the normal mode, by setting the characteristics of the LC filter, it is possible to selectively designate the frequency of the noise to be removed, thereby realizing more efficient noise reduction. .

It is a block diagram of the SRNM measuring apparatus of the nuclear power plant which is the 1st Example of this invention. FIG. 2 is a detailed configuration diagram between a preamplifier and an SRNM processing device in FIG. 1. It is a detailed block diagram between a preamplifier and a SRNM processing apparatus regarding the SRNM measuring apparatus of the nuclear power plant which is a 2nd Example of this invention. It is a figure explaining the noise mixing route when the signal line and the power line are laid close to each other.

Explanation of symbols

DESCRIPTION OF SYMBOLS 101 ... Reactor pressure vessel, 102 ... Dry tube, 103 ... Fission ionization chamber for starting area, 104 ... Weak current transmission cable, 105 ... Reactor containment vessel, 106, 401 ... Preamplifier, 107 ... SRNM signal transmission cable, 108 ... Preamplifier power supply cable, 109 ... Reactor building, 110 ... SRNM processing device, 111 ... Thick steel conduit, 201 ... SRNM signal transmission cable core, 202 ... SRNM signal transmission cable shield, 203 ... Preamplifier power supply cable Core wire, 204 ... Preamplifier power supply cable shield, 205 ... Signal output end, 206 ... DC power supply, 207, 410 ... Preamplifier circuit, 208, 408 ... Common mode noise removal ferrite, 209 ... Normal mode noise removal ferrite, 210 ... Power supply point, 211 ... Outside earth, 212 ... Non-ground shield, 301 ... LC filter for normal mode noise removal, 402 ... Monitoring device, 403 ... Conduit, 404 ... Signal transmission cable core, 405 ... Signal transmission cable shield, 406 ... Power supply cable 407 ... Shield of power supply cable, 409 ... Power supply, 411 ... Capacitor,
412 ... Amplifier, A ... External noise, B ... Inductive noise from the signal cable to the power cable, C ... Leakage noise from the shield to the core wire, D ... Need noise from the signal cable to the power cable.

Claims (2)

A detector that outputs a neutron flux of a nuclear reactor as a detection signal; a cable that transmits the detection signal; a preamplifier that amplifies the detection signal to generate an output signal; and a signal transmission cable that transmits the output signal from the preamplifier; In a signal transmission device comprising a power supply cable that supplies power to the preamplifier and a monitoring unit that displays a state of a neutron flux based on the output signal, the power supply cable has a hollow structure that attenuates a high-frequency signal A signal transmission device comprising: a filter made of ferrite , wherein a hollow portion of the ferrite is installed so that a power supply cable inside the preamplifier penetrates .   A detector that outputs a neutron flux of a nuclear reactor as a detection signal; a cable that transmits the detection signal; a preamplifier that amplifies the detection signal to generate an output signal; and a signal transmission cable that transmits the output signal from the preamplifier; An LC filter for attenuating a high-frequency signal in the power supply cable in a signal transmission device comprising a power supply cable for supplying power to the preamplifier and a monitoring unit for displaying a state of a neutron flux based on the output signal A signal transmission device installed in the middle of a power supply line inside the preamplifier.

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