RU2193245C2 - Digital reactimeter - Google Patents

Abstract

FIELD: reactivity metering for monitoring and control systems of nuclear reactors. SUBSTANCE: digital reactimeter has n metering channels each incorporating pulse-current ionizing chamber. Electrometric amplifier, amplifier-signal-to- spectrometric-amplifier-code converter, discriminator, count-to-code converter, processing device, switch, and additional processing, control, and display device. Outputs of amplifier converters and processing and control device are integrated by means of channel bus. Processing device is connected through switch to additional processing, control, and display device. EFFECT: enlarged dynamic measurement range, enhanced noise immunity of reactimeter. 1 dwg

Description

 The invention relates to the field of reactor measurements and can be used in monitoring and control systems of nuclear reactors.

 A device for measuring reactivity [1], consisting of a series-connected neutron detector, a signal meter, a simulator of groups of instantaneous and delayed neutrons and a divider, the output of a simulator of groups of instantaneous and delayed neutrons is connected to the first input of the divider, and the output of the signal meter is connected to the second input of the divider whose output is the output of the device.

 The disadvantage of this device is the limited dynamic range of measurement, equal to 6-8 decades, and a relatively large error due to non-linearity and drift of the characteristics of the decisive elements of the simulator.

 Known digital reactimeter [2], containing measuring channels, each of which consists of an ionization chamber, a transducer (transmitter), a meter, a matching device, a mini-computer and peripheral display and control devices.

 The dynamic range for measuring the reactivity of a digital reactimeter is ~ 10 decades. The noise immunity of this reactimeter is small.

These disadvantages are explained as follows. The dynamic range of signal measurement is limited by the capabilities of the measurement channels, each of which consists of an ionization chamber and a converter into the mainframe code. The noise immunity of the reactimeter consists of the security of each channel, which at currents of 10 ^-8 A is very small due to the presence of interference in the communication line.

 The objective of the invention is to expand the dynamic range of measurement and increase the noise immunity of the reactimeter.

 The problem is solved in that a well-known digital reactimeter containing the nth number of channels, each of which includes a series-connected ionization chamber, an electrometric amplifier with a signal converter of the amplifier into a trunk code, to which a processing device (minicomputer) is also connected spectrometric amplifier, discriminator, count-code converter, the output of which is connected to the trunk of its channel, a switch and an additional processing, control and indication device.

 The input of the spectrometric amplifier is connected through a capacitor to the positive electrode of the camera, and the output to the input of the discriminator. The output of the discriminator is connected to the input of the converter account code, the output of which is connected to the trunk of the processing device of its channel. The output of the processing device is connected via a switch to an additional processing, control and indication device.

The signs that distinguish the proposed reactimeter from the prototype — the presence of an additional pulse channel, consisting of a spectrometric amplifier, discriminator and count-code converter, a processing device in each channel, and a switch with an additional processing, control, and indication device — determine the expansion of the measurement range and increase the noise immunity for the transition from measuring low currents, less than 10 ^-8 A, to measuring pulses from the camera, the number of which is proportional to the neutron flux.

 The drawing shows a diagram of a digital reactimeter.

A digital reactimeter contains the nth number of measuring channels l ₁ ... l _n , each of which consists of an ionization pulse-current chamber 2, an electrometric amplifier 3, an amplifier signal to code 4 converter, a spectrometric amplifier 5, discriminator 6, and a count converter code 7, control and processing device 8, switch 9 and additional processing, control and display devices 10.

 Digital reactimeter works as follows.

 When the reactor has energy, the neutron flux on the ionization chamber 2 of each channel generates a current proportional to the magnitude of the flux. The current is supplied to an electrometric amplifier 3, at the output of which a signal is supplied to the input of the converter 4. The converter generates signals in the channel of the channel that enter the processing device 8 and then through the switch 9 to an additional device 10, which calculates the magnitude of the nuclear power and reactivity the reactor.

With a decrease in power, the current value from the chamber 2 decreases and represents superimposed pulses with a load of less than 10 ⁷ pulses / s. The pulses from camera 2, noise and interference of the communication line are fed through an isolation capacitor to the input of the spectrometer amplifier 5. The amplified signals are fed to the input of discriminator 6, where noise and interference are separated from the useful signal by discriminating them by the input signal level. In addition, discriminator 6 generates an output signal by duration and level. The generated pulses from the discriminator are fed to the input of the converter account code 7, the output of which is connected to the channel trunk. The signal from the converters 7 and 4 is sent to the processing device 8 along the channel highway. The device 8 receives incoming information from the converters 4 and 7, selects one of the channels and generates a signal through the switch 9 to the control, processing and indication device 10. The switch 9 is used for signals from the device 10 it is connected to one of the channels 1, calculates the reactivity value by solving the kinetics equation of the reactor according to the neutron flux density, forms on the monitor a numerical value of the power and reactivity p each channel.

 Thus, the proposed digital reactimeter allows the calculation of reactivity in a wide measurement range (10-12 decades) of reactor power, taking into account its spatial effects in the presence of interference in the communication line 30-50 m long between the camera and the device.

Sources of information
1. Karasev I. B. et al. "Development of reactimeter schemes for nuclear weapons". Questions of atomic science and technology. Nuclear instrumentation. - Issue 36, M., Atomizdat, 1978, p. 59.

 2. Saryrov V.N., Voskresensky F.F., Gorbunov A.P. "Digital reactimeters." Nuclear technology abroad. 1979 11, p. 19, fig. 1 (Prototype).

Claims (1)

 A digital reactimeter containing the nth number of measuring channels, each of which includes an ionization pulse-current chamber connected in series, an electrometric amplifier with an amplifier signal to code converter, the output of the converter connected to a highway, the highway of each measuring channel connected to a processing device, characterized in that a spectrometric amplifier, discriminator, counting converter are introduced - the code, the output of which is connected to the trunk of its channel, a switch and an additional a processing, control and indication device, the input of the spectrometric amplifier through the capacitor connected to the positive electrode of the camera, and the output to the input of the discriminator, the output of which is connected to the input of the transducer count-code, the output of the converter is connected to the main of the measuring channel of the signal, the output of the processing device is connected with the input of the switch, the output of the switch is connected to an additional device for processing, control and indication.