CS255133B1 - Apparatus for measuring the mass flow of the suspension - Google Patents

Abstract

The device allows to increase the accuracy of measurement without using a source of radioisotope ionizing radiation. The device consists of an induction flowmeter and a throttle with a pressure difference sensor. A first amplifier is connected to the induction flowmeter, which is connected to a dividing circuit via a first voltage/frequency converter, to the second input of which a pressure difference sensor is connected via a second amplifier and a second voltage/frequency converter. The output of the dividing circuit is connected to a digital-to-analog converter and/or a display. The dividing circuit consists of a first gate connected to the output of the first voltage/frequency converter, and a second gate connected to the output of the second voltage/frequency converter. The output of the first gate is connected to the first counter, one output of which is connected to the second gate, the second output via a flip-flop to the first gate and directly to the first monostable flip-flop, the output of which is connected to the buffer and via the second monostable flip-flop to the third monostable flip-flop, the output of which is connected to the flip-flop and to the reset input of the second counter, to whose input the output of the second gate is connected and whose output is via a buffer connected to the display and/or digital-to-analog converter.

Description

BACKGROUND OF THE INVENTION The present invention relates to a device for measuring the mass flow rate of substances which form a suspension with water.

So far, methods for determining the volume flow rate of a suspension and its specific gravity have been used to measure the slurry mass flow rate. The mass flow is then given by the product of both quantities. The main problem is the determination of the specific density of the suspension, which has so far been realized by methods that most often use radiation attenuation when passing through the suspensions. Previously known mass flow connections use two parts. To determine the volume amount of the suspension, either a pressure drop measurement on a throttle, such as a Venturi nozzle, or an electro-induction flow meter is used. An ionizing radioisotope density meter is then used to measure the density of the suspension. The mass flow is then given by the product of the volumetric flow rate with the slurry density value realized by an analog multiplier.

The disadvantage of this method is a large error of determination of specific density caused by varying intensity of ionization isotope source and error of ionization sensors, complexity of equipment, demanding operation and moreover problems connected with use of ionizing radiation source with possible health threat to operator.

The above-mentioned disadvantages are overcome by the device for measuring the mass flow of the suspension according to the invention, consisting of an induction flow meter and a throttle element, for example a Venturi nozzle, with a pressure difference sensor. It is based on the fact that the first amplifier is connected to the induction flowmeter and its output is connected to one input of the divider circuit via the first voltage / frequency converter, the second input is connected via the second amplifier and the second voltage / frequency converter outputs the throttle differential pressure sensor. .

The output of the splitter circuit is connected to the input of the D / A converter and / or to the display. A computer can be connected to the output of the splitter circuit. Its synchronization output is connected to the synchronization input of the first and second amplifiers, the first and second voltage / frequency converters, and the splitter circuit. The splitter circuit has a first gate connected at one input connected to the first converter output and a second gate connected at the second input connected to the second voltage / frequency converter output.

The output of the first gate is connected to the input of the first counter, one output of which is connected to the second input of the second gate and the second output is connected to one input of the flip-flop, the output of which is connected to the second input of the first gate and the input of the first monostable flip-flop. The output of the first monostable flip-flop is connected both to one buffer input and through the second monostable flip-flop to the input of the third monostable flip-flop whose output is coupled to the second flip-flop input and to the second counter reset input. The output of the second gate is connected to the input of the second counter and the output of the second counter is connected to the second input of a buffer, the output of which is connected to the display and / or to the input of the D / A converter.

The advantage of the proposed device is to increase the accuracy of mass flow measurement without the need to use a health-hazardous source of radioisotope ionizing radiation, the possibility of measuring instantaneous mass flow in autonomous mode with substantially reduced demands on operation and maintenance. In the coupled mode of operation by connection to a computer, the total mass flow rate of the suspension per selected time unit can be calculated and thus accurately quantified the mass flow rate of the solid component of the suspension.

An exemplary embodiment of the suspension flow measurement device according to the invention is shown in the accompanying drawings. Fig. 1 is a block diagram of the device; and Fig. 2 is a block diagram of a circuit that forms a fraction of the input frequency signals and is the core of the device.

The tube through which the suspension flows is provided with an inductive flow meter J and a throttle element, for example a Venturi nozzle, with a pressure difference sensor 2. The first amplifier 3 is connected to the induction flowmeter 1, the output of which is connected to the input of the first voltage / frequency converter 5. A second amplifier is connected to the pressure difference sensor 2, the output of which is connected to the input of the second voltage / frequency converter 15.

The outputs of the first and second voltage / frequency converters 5 and 15 are connected to the inputs of the splitter circuit 6. The output of this splitter circuit 6 can be connected to the digital-to-analog converter j3 and / or to the display 2. connected to the output of the divider circuit 2 and the synchronization output ^e 2 j connected to the synchronizing input 9.1 divider circuit 6, a synchronization input 93 of amplifier _3 'synchronizing input 94 of the second amplifier 4, a synchronization input 95 of the first housing 5 voltage / frequency synchronizing input and 92 of the second voltage / frequency converter 15.

The device employs an indirect method for measuring the density, which is to determine it from the pressure drop on a throttle sensed by a pressure differential sensor 2 at a known volumetric flow rate determined by an induction flow meter 11. The actual mass flow is then proportional to the ratio of the pressure drop signals to the throttle, such as the Venturi nozzle, and the suspension flow rate determined by the induction flow meter.

The output analog signal from the induction flowmeter 1 is amplified to a normalized magnitude in the first amplifier 2 ^and further adjusted to the first frequency signal 51 in the first voltage / frequency converter 5.

Similarly, the signal processing of the sensor output ^to the throttle 2 by means of the amplifier 4 and the second converter 15 the voltage / frequency to the second frequency input 52. The first and second transducers 2 ^and 15 of the voltage / frequency are set so that there is always the frequency of the first frequency signal 51 less than the frequency of the second frequency signal 52.

The core of the mass flow measuring device is a dividing circuit 11 which forms a fraction of the first and second input frequency signals 51 and 52, which is then further converted in the digital-to-analog converter 2 ^{to an} output analogue proportional to the mass flow or displayed numerically in the display. 3 ^{and 10 is} a decimal representation of the mass flow rate. A cooperating mass flow balancing computer can be connected to the output of the splitter circuit 6 by providing the computer in synchronized mode to synchronize the triggering of the first and second amplifiers 2 ^and A by the synchronization signals 93 and 94, the voltage / frequency converters 5 and 15 respectively. 95 and the dividing circuit 6 by the signal 91. In autonomous mode, the flowmeter can operate without the need to provide a synchronization signal j).

The dividing circuit 2 operates such that, for one period of the first frequency signal 51 proportional to the volume flow rate from the flow meter 2 ^{, the} number of incoming pulses of the second frequency signal 52 with a higher frequency proportional to the pressure drop size on the pressure difference sensor 2 ^is measured. This number of pulses indicates the ratio of the two frequencies of the first and second frequency signals 51 and 52 and thus the mass flow rate of the suspension, shown in digital decimal form in the display 7.

The wiring of the two-frequency splitting circuit 6 has a first gate 61 connected at one input connected to the output of the first voltage / frequency converter 2 and a second gate 61 connected at one input and connected to the output of the second voltage / frequency converter 15 the second gate 62 is connected by one input. The first gate 61 output is connected to the input of the first counter 63. One output of the first counter 63 is connected to the second input of the second gate 62 and the other output is connected to one input of the flip-flop 64. with the second inlet of the first gate 61 and the inlet of the first mono-stable flip-flop 65. and with the zero input of the second read although £ 8. The output of the second gate 62 is connected to the input of the second counter 68. The output of the counter 68 is coupled to the display buffer 69, the output of which is connected to the display 1 or to the digital-to-analog converter 6.

The partition circuit 6 operates as follows. Initially, it can be assumed that the second counter 68 is reset, the buffer 69 is locked, the monostable flip-flops 65, 66, 67 are in the idle state, and the first counter 63 is in the display state.

A second frequency signal 52 at a higher frequency is converted to the input of the second gate 62 and a first frequency signal 51 at a lower frequency to the input of the first gate 61. The flip-flop 64 surrounds the first gate 61 and allows the first frequency signal 51 to pass through the first gate 61. The first counter 63, with the leading edge of the output signal from the first gate 61, moves into the measurement state and opens the second gate 62. the second counter 68 reads the number of incoming pulses from the output of the second gate 62. This interval lasts for 1 or 10 frequency periods of the first frequency signal 51 read by the first counter 63, depending on the mass flow rate range selected.

Upon completion of the measurement, the first counter 63 returns to the display state, locks the second gate 62, and the output pulse puts the flip-flop 64 into the locked state and locks the first gate 61. The first counter 63 also triggers the first monostable flip-flop 65. writing the measured data to the buffer 69 and displaying the display

7. The first monostable flip-flop 65 activates the second monostable flip-flop 66, which determines the display time of the measurement results on the display 7. After the swinging time, the second monostable flip-flop 66 starts the third monostable flip-flop 66. This circuit resets the second counter 68 and flips the flip-flop 64 which unlocks the first gate 61 and the measurement cycle starts again.

Claims (3)

I HAVE INVENTED An apparatus for measuring the mass flow of a suspension, consisting of an induction flow meter and a throttle element, for example a Venturi nozzle, with a differential sensor, characterized in that a first amplifier (3) is connected to the induction flow meter (1) a voltage / frequency converter (5) to one input of the divider circuit (6) to which the other input is connected via a second amplifier (4) and a second voltage / frequency converter (15) output of a throttle differential pressure sensor (2), the splitter circuit (6) is connected to the input of the digital-to-analog converter (8) and / or to the display (7). Device according to claim 1, characterized in that the output of the partition circuit (6) is connected to an input of a computer whose synchronization output (9) is connected to the synchronization input (91) of the partition circuit (6) by a synchronization input (93) of the first. the synchronization input (94) of the second amplifier (4), the synchronization input (95) of the first voltage / frequency converter (5), and the synchronization input (92) of the second voltage / frequency converter (15). Device according to Claims 1 and 2, characterized in that the separation circuit (6) has a first gate (61) connected at one input connected to the output of the first voltage / frequency converter (5) and a second input connected at the second input (5). the output of the second voltage / frequency converter (15) has a second gate (62) connected through the first input, wherein the output of the first gate (61) is connected to the input of the first counter (63), one output of which is connected to the second input of the second gate (62); the second output is connected to one input of the flip-flop (64), the output of which is connected to the second input of the first gate (61), and to the input of the first monostable flip-flop (65), ) and secondly through a second monostable flip-flop (66) with the input of a third monostable flip-flop (67), the output of which is connected to the second input of the flip-flop (64) and the reset input d a counter (68) whose input is connected to the output of the second gate (62) and whose output is connected to the second input of a buffer (69) of the display (7), the output of which is connected to the display (7) and / or numerically - analog converter (8). 2 drawings t Giant. 1 Severography, n. P., MOST Price 2,40 Kčs