SU158615A1 - - Google Patents

Description

Devices for monitoring and controlling a continuous process using ionizing radiation are known, comprising a radiation source and a radiation intensity recording device having particle counters, a multivibrator, and an integrating price.

The proposed device allows for integrated process control. This is achieved by installing an additional radiation source, an additional recording device and a differential voltmeter in two places corresponding to the monitored phases of the process. In order to avoid disrupting the process flow with a certain deviation of the process input parameters from the given ones, a correction device is connected between the outputs of the primary and secondary registration devices.

FIG. 1 shows a block diagram of the proposed device; in fig. 2 - its basic scheme.

The devices I VI P of the radiation intensity recording contain counters Cr of particles, forming multi-vibrator cascades M, coincidence schemes I, a differential voltmeter HI, integrating circuits IV and a correction device V.

Control and regulation of the continuous / technological process is as follows.

The signals from the two forming stages in the form of rectangular pulses are fed to one common integrating circuit. Typically, the flow times of various manufacturing processes can range from a few seconds to tens of minutes. In order to control such processes according to the proposed method, it is necessary that the time constant T of the integrating circuit be set in accordance with the time of the process.

To obtain large tons without the use of bulky capacitor banks, each arm of the device contains a cascade with dynamic capacitance. To smoothly vary the time from a few seconds to tens of minutes, the instrument applied a smooth change in the gain of the dynamic stage. Signals from both shoulders are fed to a differential voltmeter, and a differential signal is fed to a recorder.

The conditions of control of the object being processed in the course of the technological process may be different. For example, the geometrical dimensions of the monitored object may vary, some of the monitored materials may be lost, density and others may vary. If these parameters are not controllable, then changes in the intensity of missed or scattered ionizing radiation from changes in parameters will introduce greater error or make it impossible to measure . Therefore, each arm of the device has its own divider sigpal, coming to the voltmeter. The matching of the dividers is set according to the specific process control conditions.

In many technological processes, a parameter often spontaneously changes even at the beginning of the process to the first control point, and, accordingly, the flow of the process changes and at the end - at the second control point. In order to control the course of the process taking into account the changes in the input parameters from a given value, a special correction circuit is provided in the NSDC, which operates as follows.

Sigal and, corresponding to the condition at the beginning of the process, with the integrating value of the left shoulder is fed to the input of the corrective amplifier, where it is compared with the established 6d jump. If the process corresponds to the problem, and the output of the corrective amplifier, the difference signal is zero. When the process is disconnected, the LJ value changes, and the difference signal will have some value with positive or negative polarity ± AL. Part of the selected differential signal

CHAL is fed to the right handwheel circuit.

ra. The values of the reference pressure and the parts of the illusion signal fed to the right shoulder can be adjusted and set according to the specific process conditions. For example, to control the completeness of sintering sinter and to automatically regulate the speed of the sintering machine, the remote head of the left shoulder is positioned above the sintering hill before the mountain, at the place where the cheese mixture is located on the machine. The head of the right arm of the device is installed above the sintering tape at the end of the machine, in the place where the sintered agglomerate is located on the machine. Sources of gamma rays are located under the agglomerate and shine through the agglobe and the whole layer of materials on the ground. Gamma rays, passage through the controlled material, partially inclined; In remote heads, corresponding signals are obtained. The main signal L / i of the left shoulder corresponds to the selected optimal loading density of the scraper on the sintering machine. The reference voltage Uofj is set equal to the main signal / 1. The magnitude of the division — the difference signal ± U is chosen almost so that when the loading density of the raw charge changes, but with the same degree of completeness of the sintering process, the calibration curve is not shifted.

The device has two remote heads (left and right shoulder). The head contains two or more groups of counters Cr of nuclear radiation (up to five straps of brushes in each group). Each counter is connected through a separate chain Ri, Ci, Yag, C- ,; RH, Sc; , Ci2. A groove of sub-taped counters to its cathode Hbiii newer with multivibrator.m (lamps L, L-2, //: j, // 4; Ld, // 1o; L, i.e. in the head the number of parallel channels equals the number of primer counters To adjust the normalized pulses, each multivibrator is supplied with variable resistance in the circuit of the second triode (R-, R, Ri-2, Rn).

Including all the caiales and one integrating circuit is produced through series-connected diodes and capacitances Yes, C3; D.): 41 Yes, Su; Du, Xu.

Cascades with dynamic capacity are made with L and Lz lamps. The effective capacitance of the integrating value is determined by the formula, where K is the gain of the cascade over the load, and C is the capacitance of the capacitor C (CelC-iCs) between the grid and the aiod of the lamp. A change in the gain of the NIBP is due to a change in the resistance value 7 (9) in the anode of the lamp. With the help of the / 7 p variable switch, the time constant τ of the integrating circuits can be varied within wide limits — to sand minutes.

The resistances Ra, Re and, Rn of the integrating circuits are at the same time divisors, from which, in a certain established ratio, signals are taken to a differential voltmeter made on a self-propagating device.

From the grid of the lamp L, a signal is fed through the resistance 1h to the input of the correction amplifier i / 7i3. The setting of the reference voltage and the compensation of the initial oscillation is produced with the help of variable resistances Rn. The correction signal is taken from the cathode of the lamp L and is supplied to the cathode of the lamp LT. The magnitude of the correction signal is set by the resistance.

The proposed device for monitoring and controlling continuous technological processes can be used in the chemical and metallurgical industries, for example, to control the ratio of two components (in the refractory clay-mortar industry), to control the end of processes, etc.

Subject invention

Claims (2)

1. Device for control of regulated continuous technological process. using ionizing radiation, comprising a radiation source and a device for detecting the intensity of radiation, including particle counters, a multivibrator, and an integrating circuit characterized in that. that, in order to provide integrated monitoring of the process by comparing the various stages of the process, a differential voltmeter, an additional radiation source and an additional device that is connected to one voltmeter, and the second input device is connected to the main recording device. 2. The device according to claim I, characterized in that, in order to exclude process disturbances with a certain deviation of the input process parameters from the specified, between the outputs of the main and additional radiation detection devices is included a correction device. I Nregi P: iuiyu: 11K: and G / npuf) 0pi /. , l (71 LJ «Ш  J