SU1383310A1 - Device for dosing liquid components - Google Patents

Abstract

The invention relates to the textile and knitwear industry of easy prod- uctiness and can be used on chemical plants in the dyeing and finishing industry, as well as on objects of other industries of advanced productivity, using the airlift method of liquid dispensing. The aim of the invention is to simplify the design of the device. For this, the device contains in storage tank 1

Description

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gauge 3, calculator 5, unit 4 of the airlift depth, nonlinear converter 7, frequency regulator 6, air flow controller 8, air consumption sensor 19, control valve 20 on the air supply line, control unit 9 and solenoid valve 17, When the device for dispensing liquid chi: mikat is operated, the com parity 1 is also taken into account.

The invention relates to the textile and knitwear industry of lightweight manufacturing industry and can be used on chemical plants in the dyeing and finishing industry, as well as on objects of other branches of industry, using the method of airlift-based liquid dispensing.

The purpose of the invention is to simplify the arrangement.

Figo is a block diagram of the proposed device; Figs 2 are graphs explaining the operation of the device; FIG. 3 shows block diagrams of the device i. The device for dispensing liquid components comprises a storage tank 1, a sensor 2 of the level gauge 3, a setting device 4 of the depth of immersion, a calculator 5, a frequency controller 6 and a nonlinear converter 7, the controller 8 air flow block

9 control consisting of element

10, trigger 11, pulse generator 12, which is a multivibrator, pulse counter 13, reference element 14, dose setter 15, amplifier 16, the device also contains a solenoid valve 17 on the air line 18. The latter also includes an air flow sensor 19 and a control valve 20 connected through an amplifier 21 to the output of the controller 8. The diagram shows an air-lift dispenser 22 and a dyeing unit 23,

The device for dispensing components works as follows.

The dose control unit 15 sets the required dose of chemical factors, depending on the accuracy of the dosage during installation of the airlift in the storage tank with an unstable level of filling, which allows to simplify the design and reduce the cost of the device. With this, an economic effect is achieved by reducing the initial capital investment and reducing the air flow for transporting the chemical 3 sludge.

kata (dosing time). At the same time, the corresponding signal in a binary-decimal code is fed from the output of the sensor 15 to one of the inputs of the comparison element 14. The signal from trigger 10 switches trigger 11 to a state in which its output signal turns on a generator 13 and 0 pulses, the frequency of which pulses depend on the control voltage applied to its input from the output of frequency regulator 6, which depends on the value of the calculator signal five,

S controlling the chemical level in the storage tank 1 using a level meter 3. With the start of the pulse generator 12, the pulses are counted by the counter 13, at the same time

0 through the amplifier 16, a solenoid valve 17 is turned on, supplying air to the airlift 22, which transports the chemical to the dyeing unit 23,

5 At that moment, when the number of pulses counted by the counter, J. becomes equal to the preset, the code combinations on both inputs of the comparison element 14 coincide, and a signal appears on its output, switching trigger 11 to its initial state, as a result of which the signal is removed enabling the pulse generator 12 and maintaining the open solenoid valve 17, as well as the counter 13 is reset to the initial state. The air supply to the airlift 22 stops

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The decrease in the level in the storage tank 1 during the operation of the airlift 22 reduces the depth of its immersion and productivity (efficiency) and also necessitates a change in the flow rate of air supplied to it.

Nevertheless, the airlift is operable in the range of 1.7–3.5 immersion coefficient K, which, with appropriate consideration of the efficiency of the airlift and air flow adjustment at different values of K, allows using er9 as a metering device and installing it in tanks with unstable liquid level, for example, in storage tanks.

Compensation for the change in the performance of the airlift 22 when the level in the storage tank 1 changes as follows.

In a device for dispensing a single time pulse, there is a strictly defined number of single volume volumes, which does not change with a change in the pulse duration.

The dose adjuster 15 sets the number of units of volume corresponding to a certain number of pulses, but the pulse duration during the dosing process varies depending on the efficiency of the airlift. (dosing rate), depending on the level

chemical in storage tank 1 (the coefficient of airlift K).

A signal corresponding to the value of the coefficient K is formed by calculating mt & 5, which implements the function

H division K g, where H is the setpoint signal of the greatest depth of the airlift 22 at the maximum level of the chemical in the storage tank .1, and h is the signal of the actual level of the chemical received from the level gauge 3. This uses the level gauge 3 with a linearly decreasing characteristic with an increase in the level, which makes it possible to receive from block 5 a decreasing signal on the degree of airlift submersion 22 as the level of the chemical in the storage tank 1 decreases.

Frequency controller 6, receiving a signal from calculator 5, generates a control action at the input of the pulse generator 12, which determines the frequency at its output

As the level of the chemical in the supply tank decreases, the frequency of the pulses decreases, and when the level rises, the frequency of the pulses of the generator 12 increases.

The technical means for implementing the pulse frequency regulator 6 is a block of nonlinear transformations, which allows to convert to its input a signal from the calculator 5 to a nonlinearly varying analog signal in accordance with the graph in Fig. 26, a piecewise linear approximation method of a nonlinear function characterizing the dependence of the efficiency of airlift from the coefficient K of his dives about

Regulator 8 air flow together with a non-linear converter

7 changes the flow rate in the air pipeline 18, measured by the air flow sensor 19 in the controllability of the air-lift factor, through the amplifier 21, the control valve 20 "

The nonlinear converter 7 forms on one of the inputs of the regulator 8 a task signal — a dynamic curve for the specific air flow rate Vg versus the immersion coefficient K, shown in FIG. 2ao. This graph image is obtained by analyzing a known chart. The second input of the regulator 8 receives a feedback signal from the air flow sensor 19 (Vp). The actual flow rate signal (VP) is summed up at the input of the regulator

8 with a reference signal (V), and the error signal (L) arising at its output controls the valve 20, which, depending on the phase of the error signal, increases or decreases the air flow, changing VP in accordance with curve S in FIG.

Forms in the invention

A device for metering - liquid components, containing a storage tank with an air-lift metering unit, connected to an air supply pipeline, as well as a control unit, including a dose setting unit, a trigger element and a first amplifier, characterized in that It contains series-connected airlift depth gauge, computer, non-linear converter, air flow controller and second amplifier, as well as a level gauge, frequency controller sequentially installed on the pipeline e in the direction of air supply, a control valve, a flow sensor and a solenoid valve, the control unit additionally containing a trigger, a pulse generator, a counter and a comparison element, the second input of which is connected to the output of the dose sensor, and the output to the second input, respectively; - the counter and the first input of the trigger connected by the second input with the snag element, and the output - with the input of the first / o {m

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amplifier, the output of the level gauge is connected to the second input of the calculator, the output of which is connected to the input of the frequency controller, the output of the flow sensor is connected to the second input of the air flow regulator, the output of the second amplifier is connected to the control valve, the output of the frequency regulator is connected to the second input pulse generator of the control unit, the first amplifier of which is connected to the solenoid valve by the output,

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Claims (1)

Claim A device for dispensing liquid components, comprising a storage tank with an airlift dispenser, connected to the air supply pipe, and a control unit including a dose adjuster, a trigger element and a first amplifier, characterized in that, in order to simplify the device, it contains connected airlift depth gauge, calculator, non-linear converter, air flow regulator and a second amplifier, as well as a level gauge, frequency regulator, sequentially mounted on the pipeline in the direction of the air supply, a control valve, a flow sensor and a solenoid valve, the control unit additionally containing a serially connected trigger, pulse generator, counter and a comparison element, the second input of which is connected to the output of the dose .. sensor, and the output to the second counter input and the first input of the trigger connected. the second input with the plug element, and the output with the input of the first amplifier, the output of the level meter is connected to the second input of the calculator, the output of which * is connected to the input of the frequency regulator, the output of the flow sensor is connected to the second input of the air flow regulator, the output of the second amplifier is connected to the control valve , the output of the frequency controller is connected to the second input of the pulse generator of the control unit, the first amplifier of which is connected by the output to the solenoid valve. B (4) Fig g