CS251268B1 - Apparatus for measuring the rate of drop of a substance in a container - Google Patents

Abstract

It relates to the field of digital measurements, and solves the problem of measuring the rate of decrease of the substance level in the reservoir with continuous or quasi-continuous, withdrawal of this substance, with periodic replenishment of the reservoir contents. The essence of the device lies in the fact that a movable probe, controlled by a jack, performs a vertical oscillatory movement in the area of the substance level in the reservoir and copies this level, the axis of the jack is connected to an incremental rotary sensor, the outputs of which are connected to the inputs of the return counter via coupling elements and a system of gates, controlled by the signal of the reservoir filling signaling block, further the signal of the filling signaling block blocks the flow of pulses of the measurement time generator for the return counter, which achieves measurement only during the time of decrease of the substance level in the reservoir. The rate of decrease of the substance level in the reservoir is proportional to the frequency of pulses counted in the return counter, with a constant pre-selected measurement time. The connection can be used in measuring automated control systems in the field of digital measurement of the rate of decrease in the level of a substance in reservoirs with continuous or quasi-continuous withdrawal of this substance and occasional replenishment of the reservoirs of substances.

Description

BACKGROUND OF THE INVENTION The present invention relates to a device for measuring the rate of drop of a substance level in a container.

Devices are known for measuring the rate of drop of a substance in a container using movable probes to indicate the position of the level of a substance in a container, followed by the necessary calculation of the rate of drop of a level; Measurement is strenuous, time consuming, requires constant attention of the operator, does not consider the problem of replenishment of the substance in the container.

The disadvantage of the present invention is to eliminate the device for measuring the rate of drop of the substance level in the container according to the invention, characterized in that the movable probe is mechanically connected to a jack which is mechanically coupled to an incremental rotating agent. whose output is coupled to the signal input of the first gate whose output is coupled to the first signal input of the return counter, the second output of the incremental rotary encoder is coupled to the input of the second coupler whose output is coupled to the signal input of the second gate whose output is coupled to the second signal the counter counter input, wherein the counter counter timing input is connected via the third gate output and the third gate signal input: the clock pulse generator output, and an analog output is connected to the return counter, which is the first output and a digital output of the return counter which is the second output of the device, wherein the first gate control input, the second gate control input, the third gate control input are connected to the output of the fill signaling block.

The charge signaling block consists of the input of the charge initiation signal which is connected to the input of the third coupler whose output is connected to the 9e input of the combing circuit.

The fill signaling block consists of a fill start signal input that is coupled to a fourth coupler input whose output is coupled to a memory setting input, the memory erase input being coupled to the fifth coupler output and the fifth coupler input to the fill stop signal input.

The device according to the invention is a compact system for automatically measuring the rate of decrease of the level of a substance in a container with a citizen replenishment of this substance.

The device for measuring the rate of drop of the level to the container according to the invention is shown in the accompanying drawings, in which Fig. 1 shows a jack of a movable probe which is mechanically coupled to an incremental rotating agent 6, the first output of which is connected to the input of the Crush Coupler VI. . whose output is coupled to the signal input of the first gate H1, whose output is coupled to the first signal input, etc. of the return counter C, the second output s2 of the incremental rotary encoder S is coupled to the input of the second coupler 52, whose output is coupled to the signal input second gate H2. the output of which is connected to the second signal input ¢ 2 of the return counter C, wherein the timing input cj of the return counter C is coupled via the output of the third gate H3 and the signal input of the third gate HJ to the output of the clock pulse generator G; c, which is the first output of the device, the digital output of the return counter network C, which is the second output of the device, the control input h1 of the first gate H1 the control input J1 of the second gate H2, the control input h3 of the third gate H3 are connected to the block output .

In Fig. 1a, a fill signaling block i is shown, which consists of an input K of the fill initiation signal that is connected to the input of the third coupler V3. the output of which is connected to the input of the third coupler 63, the output of which is connected to the input of the timing circuit T.

Fig. 2 shows block Ί. a fill signaling, which consists of an input to the fill ignition signal which is coupled to the input of the fourth coupler V4. whose 'output' is connected to the adjusting input ml of the memory U, the erasing input m2 of the memory being connected via the output of the fifth coupler V5 and the input of the fifth coupler V5 to the input K1 of the fill termination signal.

The function of the device according to the invention is that the movable probe uses either capacitive, radiation or other principle to indicate the level of substance in the container. The movable probe performs a vertical oscillating movement by means of a jack Z with a control device operating such that when the movable probe drops below the substance level, this is indicated by a jack control device which changes the direction of jack Z movement, in the tray. This is indicated by a jack control device that changes the direction of downward movement of the movable probe, etc. The amount of creeping movement of the movable probe to copy the level of substance in the reservoir is determined by the characteristics of the regulator providing the vertical bend of the movable probe. In the interests of measurement accuracy, the magnitude of the copying oscillating motion of the movable probe should be the smallest. The magnitude of the vertical movement interval of the movable probe depends on the technological arrangement of the device at which the rate of drop of the substance level is measured. This may be the height of the container, the blast furnace room area, etc.

The axis of the jack Z is connected to the axis of the incremental rotary encoder S with a known translation of the position of the movable probe and the output frequency of the pulses.

The return counter C consists of a return counter with binary outputs associated with the memory-inverter inputs to store data at the end of sampling, with the memory-inverter outputs associated with the digital-analog converter inputs, with internal data transfer control at the end of sampling and resetting whose signal inputs are connected to the internal sampling circuit by the control inputs. Sampling of the return counter C is performed with the clock cycle pulses supplied from the external clock pulse generator G via the outer third gate H3 at the timing input c3 of the return counter C sampling circuit.

The pulse at outputs s1 and s2 of the incremental rotary encoder S is counted into the return counter C while the movable probe is lifted, when the movable probe is lifted, the pulses at outputs s and s2 of the incremental rotary encoder S are read from Using the sequence of pulses of the incremental rotary encoder S generated at the first output s1 and the second output s2 and offset in time, the motion direction of the movable probe is reversed by the counter C, as the substance level in the reservoir decreases. the time of measurement to fill the container is indicated by a block J of the fill signaling with a fill duration signal, a fill start signal, or a fill end signal. Depending on the modification of the device, these signals include both signal inputs c1 and c2, including timing input c3 of the counter C, to stop the counting of the counting time by stopping the generation of the sample counter C at the fill times, which continues after filling.

This achieves a stable pulse counting time from the incremental rotary encoder S at the time the level of substance in the reservoir drops. After the counting time determined by the internal sampling circuit of the return counter C, the reading is reset and the measurement can be repeated. The counting of the pulse rate is proportional to the rate of decrease of the substance level in the reservoir at a constant measurement time.

The apparatus shown in FIG. 1 uses a fill duration signal to override the tank fill interval, which blocks the gate control inputs H1 for the tank fill time. H2. H3.

The device shown in Fig. 1a uses a fill initiation signal to overlap the tank fill interval, which initiates the shuffle Tc and for a preset time longer than the tank fill time, the driver inputs of the gate H1 are blocked. H2. H3.

AND

The apparatus shown in FIG. 2 uses a fill initiation signal to denote the fill interval of the container, which indicates the memory M a of the container fill status with subsequent blocking of the gate inputs H1. H2. M3. The filling termination is given by the filling termination signal, which puts the memory £ M into the filling termination state, with the subsequent control inputs of the gate gates H1.

H2, SiFirst to fifth coupler V1 to V5 provide the voltage matching of the signals or the desired galvanic isolation, using opto-couplers. The clock pulse generator G is the source of the control pulses to produce the desired interval - a sample of measurements.

A particular embodiment of the device according to the invention can be used, for example. to measure the rate of drop in the blast furnace baffle level. Let the conversion of the height movement of the movable probe and the output pulse rate of the incremental rotary encoder S be 1000 imp / lm.

If, for example, at 300 seconds the landfill level is 1.20 m, then the rate of fall of the landfill level is at ~ 1'2 ^m = 4. 10m / sec;

300 eec

The general relation for the rate of drop of landfill level is v = k. 1 = *. No; t t where: i - rate of decline

Jí - proportionality constant £ - pulse rate counted at time t i - measurement time (constant)

After substituting the previous values:

* -] ' ^2m 3Ó0 sec k = 0.001;

t = 300 sec;

'-6

3.33. 10 .č; m / sec

The invention finds application in measuring the rate of drop of the substance level in a container in all technological processes where the container forms an inter-production storage capacity with continuous or quasi-continuous withdrawal of substance from the container with occasional relatively short-term loading of the substance into the container.

The device model of the invention is also feasible using digital computers as part of process control systems.

The device for measuring the rate of drop of the substance level in the reservoir can be applied in the construction of automated control systems in a number of industries.

Claims (3)

SUBJECT OF THE INVENTION 1. Apparatus for measuring the rate of drop of a substance level in a container containing a movable probe, characterized in that the movable probe jack (Z) is mechanically coupled to an incremental rotary encoder (S), the first output (sl) of which is connected to the inlet of the orifice coupler (VI). whose output is coupled to the signal input of the first gate (H1), whose output is coupled to the first signal input (cl) of the return counter (C), the second output (s2) of the incremental counter (S) is connected to the input of the second coupler (V2) ), the output of which is connected to the signal input of the second gate (Ή2), the output of which is connected to the second signal input (c2) of the return counter (C), the Timing input (c3). the counter (C) is connected via the third gate output (H3) and the third gate signal input (H3) to the clock pulse generator output (G), and an analog output (c4) is connected to the return counter (C). the first output of the device and the digital output (o5) of the return counter (C), which is the second output of the device, wherein the control input (hl) of the first gate (H1), the control input (h2) of the second gate (H2) the gates (H3) are connected to the output of the fill signaling block (1). Apparatus according to claim 1, characterized in that the fill signaling block (1) consists of an input (K) of the start signal which is connected to the input of the third coupler (3) whose output is connected to the input of the timing circuit (T). . Device according to claim 1, characterized in that the signaling block (1) consists of an input (K) of the start signal which is connected to the input of the fourth coupler (V4), the output of which is connected to the adjusting input (ml) of the memory. M), wherein the erase input (m2) of the memory (K) is connected via the output of the fifth coupler (V5) and the input of the fifth coupler (V5) to the input (K1) of the fill termination signal.