SU817480A1 - Apparatus for controlling frequency-pulse batch meter - Google Patents

Description

(54) DEVICE FOR CONTROL OF A FREQUENCY-PULSE

DISPENSER

one

The invention relates to the control of metering devices, in particular, the regulation of the flow of liquids using frequency-pulse metering systems and molset to find application in various industries.

A pneumatic pulse generator is known, which contains one pnevmorele, the output of which is connected through an inertial link consisting of series-connected throttles and a tank with a minus chamber of this relay, and the plus chamber of which is connected to the backwater channel 11.

The closest technical solution to the present invention is a device for controlling a frequency-pulse dispenser, containing a square pulse generator consisting of a pneumorella, the plus chamber of which is connected to the remote control channel, and the minus one to the output of the inertial link, made in the form of serially connected alternating thrusters and capacitance, and to the output of the generator is connected a logical unit 12.

The disadvantages of the known devices implemented on the basis of a generator with a single pneumorel of the USEPPA system are the nonlinearity and instability of the characteristics and the limited frequency range, which does not allow using them directly to control the frequency-pulse metering unit in the automatic control loop of the technological parameter.

0

The purpose of the invention is to expand the field of application of the device.

This goal is achieved by the fact that a device for controlling a frequency-impulse dosage unit, containing a remote-controlled rectangular impulse generator, consisting of a first pneumorele, the plus chamber of which is connected to a remote channel

0 control, and minus - to the output of the first inertial link, made in the form of successively connected throttle and capacitance, a logical block is introduced, the outputs of which

5 are connected to the first, second and third control channels of the pulse dispenser, and the second pneumorele is introduced into the square pulse generator, the second inertial link

Claims (2)

0 made in the form of series-connected throttles and tanks, two normally-open pneumatic valves and a throttle, the flow chambers of normally-open valves through the throttle and directly connected to the atmosphere, the control chambers with outlets corresponding to the pneumorel, and the nozzles of the corresponding pneumatic valves with the negative. the camera of the first pneumorele and the positive chamber of the second pneumorele, the second inertial link is connected to the positive chamber of the second pneumorele, the negative camera of which is connected to the remote channel onnogo control, the output .vtorogo pneumatic relay and the first inertial link connected with the input logical block. In addition, the logic block consists of three pneumatic eyes, two normally open valves and three drawers, the first pneumatic switch being switched on according to bheme YES, its output is connected to the control input of the first normal open valve and the first output of the unit, the second and third stump Morel are connected according to the HE scheme, the output of the first of which is connected to the control input of the first normal-open valve and the first output of the block; the output of the second pneumorele is connected to the control input of the second normal-open valve and to the second output of the unit The third pneumatic valve is connected to the third output of the unit, and the input of the unit is connected to the nozzles of normally-open valves and through the first choke to the control chamber of the first pneumorel and the flow chamber of the first normal-open valve, through the second choke to the control chamber of the second pneumorel and the flow chamber of the second normally open valve, and through the third choke, with the control chamber of the third relay. The use of reference pneumorelles of the inertial link and two normally open pneumatic valves serves to expand the frequency range of the generator according to a linear law depending on the value of the control signal coming from the datum frequency changing unit, and allows the use of frequency-pulse metering systems in automatic whom to regulate the technological parameter. The logic unit with the proposed connection circuit provides for the formation of control pulses of a given duration, duty cycle and phase shift relative to each other over three channels, which makes it possible to use the device for controlling a frequency-pulse dispenser with a membrane drive and diaphragm valves. FIG. 1 shows a diagram of a device for controlling a frequency-pulse dispenser assembled on the basis of the USEPPL elements; in: FIG. 2 cyclogram of work at the facility. The proposed device consists of a pneumatic generator 1 of rectangular pulses, a lo-logical block 2, a frequency-impulse 1 | p11 of the dispenser 3, and a node 4 for a continuous frequency change. ,: V Pneumatic generator 1 sos, goit of izdvuh pneumorele 5 and 6 of type P1P.1, two normally open valves 7 and 8 of type PZK.1, two inertial links: Drossel 9 and capacity 10, Drossel 11 and capacity 12 and one constant throttle 13. Logic block 2 consists of three pneumorele 14-16 of type P1R.Z, two normally open pneumatic valves 17 and 18 of type ZPK.G and three power amplifiers 19-21 of type P1100 and three chokes 22-24 of type P2D2 The dispenser 3 is an actuator for varying the flow rate. The proposed device works in the following way. The minus chamber of the relay 6 and the positive chamber of the relay 5 is supplied with a control pressure Rupr The power nozzle in the chamber of the relay b is closed and the pressure P is set at its outlet, and the chamber of the power supply of the relay 5 has RPT (RPIT supply pressure). The pressure of the RPIT is applied to valve 8 locking the connection of the positive chamber and relay 5 to the atmosphere, and through an inertial link is fed to the positive chamber of relay 6, where the pressure increases according to the law Rb + Rp (where Tj is the time constant of the inertial link of the drossel and capacity 11 and 12, respectively. Once pressure in the positive chamber rel 6 exceeds PCP RUPR + 0 | 03 kgf / cm, the membrane block of the relay b is shifted to the Lower position and opens the nozzle in the power chamber of the relay 6, where Pcr is the actuation pressure. The pressure of the generator is energized on the valve 7, locked The connection of the negative chamber of the relay 5 with the atmosphere, and through the inertial link 9 and 10 in the same chamber begins to increase according to the law (-e VTi), where T; is a constant of the time of the inertial link 9 and 10. As soon as the pressure in the negative chamber relay 5 exceeds the value equal to vnp +0.38 kgf / cm, the membrane block of relay 5 switches to the upper Assumption, closing the nozzle into the power chamber (Rurtst 0) and opening the nozzle communicate with the atmosphere in the atmospheric chamber of relay 5 thus R5pit OOtkryvaets valve 8 and the pressure is discharged into the atmosphere. Relay 6 membrane blockage is moved to the upper position (). When valve 7 is opened, the positive chamber of relay 5 is connected through throttle 13 to the atmosphere. Relay 5 switches over after locking time and Rupit - RPIT. Then the cycle repeats. The frequency, the duty cycle and their phase shift are determined by the control pressure and the time constant of the inertial links T and T Therefore, the flow rate depends on Ruppr (signal, on the primary converter). The cyclogram of the operation of the device (Fig. 2) on the axis of the ordinates is applied to the values of the pressures on the individual elements of the circuit, where P is the pressure released by the pneumorel 6; P5 - pressure in the positive chamber of the pneumorel 5; Pcp-f pressure trigger of the pneumorel 5; Рр - output pressure of the generator, given by the logic block; P is the pressure in the in-chamber chamber of the pneumorele 6 cPi; P is the output pressure of the pneumatic relay 6; Rsch pressure control inlet diaphragm valve dispenser; P (9 - control pressure of the outlet diaphragm valve of the dispenser; P2 pressure control of the diaphragm actuator of the dispenser; - time delay of the impulse to the diaphragm valves of the dispenser; TI - time delay of the impulse on the diaphragm of the drive. Using the proposed device as compared to the known ones liquids in frequency-pulse dispensers due to a change in the frequency in the range of 1: 8 and allows the dispenser to be included in the automatic control loop of the technological parameter. Claim 1. Device for controlling a frequency-pulse dispenser, comprising a remote-controlled square pulse generator, derived from the first pneumorele, the positive chamber of which is connected to the remote control channel and the negative one to the output of the first inertial link, made in the form of connected throttle and capacitance, which is so that, in order to expand the scope of application, it contains a logical unit, the outputs of which are connected to the first, second and third channels lam control pulsed dispenser, and S generator of rectangular pulses introduced the second pneumorele, the second inertial link, made in the form of a group of connected throttle and capacitance, two normal-open, pneumatic valve and throttle, and.-Flow chambers of normal-open valves through the throttle and directly c-Odineny with the atmosphere, uprail chamber with outlets corresponding to the Nemoremore, and the nozzles of the corresponding Hemevalves - with a minus-chamber of the first pneumorel and a positive chamber of the second pneumore e, a second link connected to the inertial plysoaoy Ka, as the second pneumatic relay, the negative chamber is connected to: a. a remote control channel, with the output of the second pneumorel and the first inertial link connected to the input of the logic unit. 2. The device according to claim 1, from the fact that the logical lock consists of three pneumorele, two normally-open valves and three chokes, the first pneumorelle on the circuit. YES, the output of its connection with the control of the first normal-on-open valve and the first output of the unit is controlled, the second and third pneumorel switches on the main circuit, the output of the first of which is connected to the control input of the first normal-open Valve and: with the first output of the block, the output of the second pneumorele is connected to the upstream input of the second normally open valve and the second inlet of the unit, the output of the third pneumatic actuator is connected to the third output of the unit, and the input of the block is connected to the nozzles of the normally open valves and through first choke - .c the control chamber of the first pneumorele and the flow chamber of the first normally open valve, through the second throttle - with the control chamber of the second pneumorel and the flow chamber of the second normally open valve, and through the third throttle - with the control chamber: the swarm of the third relay. Sources of information taken into account during the examination 1. USSR author's certificate №566032, cl. F 15 C 3/16, 1976. 2. Gurevich A.L. and Sokolov M.V. Pulse systems for automatic dosing of aggressive liquids. M., Energie, 1973, p. 68 (prototype).