CS239578B1 - Connection for extent evaluation of exposive transformation - Google Patents

Abstract

The solution relates to involvement in evaluation the extent of explosive conversion by the indication temperature, variation and / or differences by means of located temperature sensors connected via an amplifier to a recording member. The essence of the solution is that between the amplifier and the recording member is energized memory. The connection is suitable for testing flammability to determine the technical safety parameter

Description

The invention relates to a circuitry for evaluating the extent of an explosive conversion by indicating temperature changes in the spreading reaction zone by means of temperature sensors, the arrangement being selected so as to allow accurate and reproducible results to be obtained.

Obtaining accurate complex data with good accuracy and reproducibility on the extent of explosive conversion requires an appropriate measurement technique. This technique is needed to determine the technical-safety parameters for addressing potential fire and / or explosion hazards, as well as the effectiveness of their suppression, which is very important because of the ever-increasing scientific and technological advances associated with the intensification of production processes in different industries , especially mining, chemical, petrochemical, gas, petroleum and others, many of which are showing a dangerous explosion. This requires reliable measuring equipment to be developed, implemented and implemented, thus contributing to ensuring greater safety in working conditions in industrial enterprises.

Most of the known literature procedures use temperature sensors to indicate explosive conversion in test devices, especially thermocouples usually in combination with another sensor, such as pressure [Sello H .: Ind. Eng. Chem. 50, No. 10, 1561 (1958); Gaube J., Grasse H., Simroch K .: Chem. Ing. Tech. 40, No. 13, 660 (1968); Bezop. Tr. Prom. 11, 46-47 (1975); MS. author's certificate no. 223 652; no. 219,586 and others].

A disadvantage of the explosion assessment in the above-mentioned works is the fact that the signal from the temperature sensor does not pay the required attention in terms of its processability. The obtained monitoring data are of a qualitative informative character only.

The above drawback and the other solves according to the present invention a circuitry for evaluating the extent of the explosive conversion by indicating temperature changes and / or their differences by the effect of the spreading temperature wine by means of situating temperature agents connected via an amplifier to a recording member. a voltage memory is included.

Advantages of the invention include the technical and economic availability of the wiring component associated with obtaining accurate and comprehensive results with good reproducibility. It is also possible to use the wiring part to record peak values and other characteristics associated with the magnitude of the explosive conversion.

In the drawings of the exemplary embodiment, the block diagram and the interconnection diagram for evaluating the extent of the explosive conversion are indicative of temperature changes and their differences in the device for determining the concentration between the explosives. However, this example does not exhaust all possibilities of the invention nor limit the scope of its protection.

The circuit (FIG. 1) according to the invention consists of two temperature sensors 1, which are connected via amplifiers 2 and voltage memories 3 to the recording member 4.

The principle of the invention is to include it between the amplifier 2 and the recording member 4 of the voltage memory 3. Since the connection is intended to measure the temperature difference with a time shift, it is necessary to remember the relevant signals.

The interconnection (Fig. 2) capable of remembering the peak value consists of the comparator OZ1, the D2 high-resistivity diode in the reverse direction, the OZ2 integrator with the high input resistance and the inverter OZ3 with unit gain.

Positive input voltage charges capacitor C through diode D2, OZ2. Charging lasts until the OZ3 output reaches a negative voltage level in absolute terms. value equal to the height of the voltage peak at the memory input. Then the OZ1 comparator flips and a positive voltage appears at its output; level limited by diode D1.

Diode D2 is locked and capacitor C “memorizes” the peak value of the monitored signal that appears at the output of the opposite sign memory. Capacitor C must have a dielectric with high insulation resistance (eg terylene) to ensure a long discharge time constant. The high input resistance of the integrator is ensured by a pair of FET transistors in a single T-case. After reading the measured value, the capacitor C is discharged by means of the switch S1.

The description of the engagement operation for an explosive sphere-shaped sphere with two temperature sensors 1 at the top and bottom differently disposed relative to the centrally located ignition sources is as follows: the flame formed in the explosive mixture after initiation usually moves upwards where its propagation is recorded by the top temperature sensor . Upon reflection of the front of the reaction zone, propagation by the lower temperature sensor is recorded.

The signals from the temperature sensors 1 are amplified in the actual amplifier 2 and recorded in the voltage memory 3 and displayed after processing by the recording member 4.

The wiring according to the invention is particularly suitable for evaluating the extent of the explosive conversion by indicating temperature changes in a mixture of flammable gases, vapors or dusts with air or other oxidant.

Claims (2)

SUBJECT Involvement for evaluating the extent of an explosive transformation by indicating temperature changes and / or their differences, by the effect of a spreading thermal wave, by means of situating temperatures INVENTED sensors connected via an amplifier to a recording member, characterized in that between the amplifier (2) and the recording member (4) a voltage memory (3) is included.