SU1643935A1 - Sampling automatic suspension batcher - Google Patents

Description

The invention relates to techniques for volumetric dosing of liquids.

The purpose of the invention is the expansion of the scope, improving reliability and performance.

The drawing shows a diagram of a pulsed automatic suspension dispenser.

The dispenser contains an actuator 1, a control unit 2, a control unit 3, and a flow integrator 4.

The actuator 1 consists of three cylindrical disks 5-7, between which the membranes 8 and 9 are clamped. On the two extreme disks there are four shut-off valves 10 - 13 controlled by the pair-cross connection scheme. Valves 10 and 13 are connected to the pressure channel 14, and valves 11 and 12 to the drain

15. On the inside of the discs 5. and 7, metering chambers 16 and 17 are made. In the middle disk 6, liners 20 are made on both sides. A membrane 8 connects the piston 23 to the throttle 24 in the cylinder 22. The cylinder 22 is made of non-magnetic material.

In the disk 6 flush with the surface of the cylinder 22 is a magnet 25 with a magnetically controlled contact 26. Measured, chambers 18 and 19 and the cylinder 22 are filled with a separation fluid.

The control unit 2 consists of a controlled pulse generator 27 connected to a trigger 28 with a counting input. The direct output of the trigger 28 is connected to the shutoff valves 11 and 13, and the inverse to the valves 10 and 1 2.

The control unit 3 consists of triggers 29 and 30, elements And 31 and NOT 32. The first inputs of the triggers 29 and 30 are connected respectively to the direct and to 28. the keys are 26, the keys to this contact are through the element NOT 32. The outputs of the triggers 29 and 30 are connected to the And element 31. The output of the And element is connected to the signaling unit 33 (lamp, siren).

The integrator 3 consists of a counter 34 pulses connected to the magnetic chambers 18 and 19. 21 exclude the pressure of 9 into the cylinder 22, the chamber chambers 18 and 19. A floating inverse trigger output is installed. The second input of the trigger 29 is connected to the magnetically-controlled contact. The second input of the trigger 30 is under the 50-controlled contact 26 through a differentiating circuit consisting of a capacitor 35 and a resistor 36 and a rectifier bridge 37.

The dispenser works as follows.

The pulses of a given frequency coming from the pulse generator 27 to the counting input of the trigger 28 transfer it from one stable state to another, i.e. at both outputs of trigger 28, pulses appear in the gas mask. These pulses are alternately supplied to the corresponding groups of shut-off valves and to the triggers 29 and 30. For example, when a pulse appears at the direct exit of the trigger 28, the valves 11 and 13 are closed and the dosed suspension under pressure in the pressure channel 14 through the open valve 10 fills the metering chamber 16 , pressing the membrane 8 against the spherical surface of the metering chamber 18. This leads to extrusion of the release fluid into the metering chamber 19. In this case, the suspension from the metering chamber 17 through the open valve 12 is extruded into the drain channel 15. a pressure differential inducer liquid separation on the piston 23, it moves to the right.

Since the friction force of the floating piston 23 against the cylinder wall 22 is negligible, the dose rate is maximum and is determined by the hydraulic resistance of the actuator, pressure head 14 and drain 15 channels. But since the volume of the cylinder 22 is less than the total volume of the measuring chambers 18 and 19, the piston 23 reaches its extreme right position before all the separation liquid flows from the measuring chamber 18 into the measuring chamber 19. The remaining separation liquid flows through the throttle 24, which sharply increases the hydraulic resistance of the dispenser and, as a result, reduces the rate of dispensing of the dose. In this case, the piston 23 stops shunting the magnet 25 and its magnetic flux begins to act on the contact 26, which closes. In this case, the supply voltage is supplied to the second input of trigger 29 and turns it off, and the differential circuit, consisting of a capacitor 35 and a resistor 36, is converted into a short-term pulse of positive polarity, which, passing through the bridge 37, turns on the counter 34.

With the switching of the trigger 28, a signal appears on its inverse output, which turns on the trigger 30 and closes the valves 10 and 12, while the valves 11 and 13 open. The liquid from the pressure channel 14 through the open valve 13 enters the metering chamber 17 and presses the membrane 9 from the spherical surface of the measuring chamber 19. In this case, the separation liquid is pressed into the measuring tank 18, which leads to the displacement of the membrane 8 to the left and squeezing the dose of suspension into the pressure channel 15 Thus, the piston 23 moves to the left and shunts the magnet 25, and the rest of the separation fluid flows through the throttle 24. This magnetic flux ceases to function. This is a cop NOT 32

In this case, the Sator 35 and the polarity i-polarity, by the rectifier bridge 37 into a pulse of positive polarity, including a pulse counter 34.

In an emergency, for example, the absence of suspension in the pressure channel 14, clogging of the output channel 15, leakage of shut-off valves, etc., the appearance of a pulse at the direct output of the trigger 28 sets the trigger 29 to 1. However, the piston 23 does not move to the right and shunts the magnet 25 and the contact 26 remains open, and therefore, the trigger 29 remains on. When the trigger 28 is subsequently switched, an impulse appears on its inverse output, which turns on the trigger 30, and a signal appears on the output of the And 31 element, which turns on the signaling unit 33.

When the object 10 is connected to pin 26, it leads to the shutdown of the trigger 30 due to the circuit. The circuit, consisting of a condenser resistor 36, produces a negative negative pulse

Claims (2)

Claim 1. A pulse automatic slurry dispenser containing an actuator with a membrane metering chamber and shut-off elements connected to the outputs of the control unit ·, and a control unit with an alarm unit, characterized in that, in order to increase reliability and performance, the actuator is introduced additional dosing tank and two 'measuring chambers interconnected by a cylinder with a floating piston in which a throttle hole is made, the total volume of the measuring chambers exceeds the volume of the cylinder and, moreover, the measuring chambers and the cylinder are filled with a separation liquid, and the control unit is made in the form of two triggers, elements AND and NOT, and a magnetically controlled contact, the control magnet of which is mounted flush with the surface of the cylinder, with the first inputs of the triggers connected respectively to the first and. to the second outputs of the control unit, the second input of the first trigger is connected to the output of the magnetically controlled contact, and the output of the first trigger is connected to the first input of the element And, the second input of which is connected to the output of the second trigger, the second input of which is connected through the element NOT to the output of the magnetically controlled contact, and the output of the element And connected to the alarm node .. I 2. The dispenser according to claim 1, with the fact that it is equipped with a flow integrator made in the form of a pulse counter, a capacitor, a resistor and a rectifier bridge, and the pulse counter through a series-connected capacitor, a resistor and a rectifier bridge are connected to the magnetically controlled contact of the control unit.