SU1163097A1 - Device for checking and adjusting gas set - Google Patents

Abstract

A device for controlling and regulating the gas unit, comprising a housing, inlet and outlet ducts, an actuator valve with a n "evamplifier of the parameter being monitored, a trigger button, an additional valve with a saddle connected via a rod to the diaphragm, a chamber connected via chokes to the outlet channel and control sensors and adjustment, sealing gaskets and valve, which is due to the fact that, in order to simplify preventive maintenance, the seat of the additional valve is made in the form of a sleeve, the internal cavity of The second transverse windows communicate with the chamber, the sleeve is isolated from the gas flow and the atmosphere by sealing gaskets and pressed to the body with a clip, and the chamber is connected to the inlet channel through a trigger button. (Ls

Description

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The invention relates to control and regulation systems for gas ai-regatta and can be used for automation, gasified heat generating units and boilers,

The aim of the invention is to simplify preventive maintenance.

The drawing shows a constructive diagram of the device control and regul. and gas valve unit.

The device contains an input channel 1, an output channel 2 and a chamber 3. The main flow is formed by a saddle 4 with an actuating valve 5 fixed on the membrane 6, with a submembrane cavity 7 and a supramembrane cavity 8. A small flow is formed by a saddle 9, which is made in the form of a sleeve, the cavity of which is transversely communicated with the chamber 3 and the spring-loaded additional valve 10 placed in the cavity 11 connected to the inlet channel 1 through the opening 12. The seat body 9 is installed. into the central socket on the gaskets 13 and 14 and pressed by the lid 15 through the gasket 16 to the device body.

The rod 17 with one end rests against the additional valve 10, and the second through the plate 18 onto the membrane 19. The membrane 19 forms a submembrane cavity 20 and a supermembrane cavity 21 inside the housing, and lastly communicates with the atmosphere through window 22. Chamber 3 is connected to the inlet channel 1 through a window 23 and a trigger button with a spring, a rod 25, a flap 26 of a nozzle 27 “The trigger button is isolated from the housing using shims 28 29 and also has a gasket 30.

The inlet channel 1 communicates with the na7, the membrane cavity 8 through the channel 31 and the nozzle 32, over which the spring-loaded valve 33 is installed, the rod 34 of the valve passes through the nozzle 35 and abuts the plate 36 against the membrane 37. Membrane 3

forms inside the body a nadmembrane cavity 38 and a submembrane cavity 39, the latter communicating with the atmosphere through window 40. The overmembrane cavity 38 is connected in series through the choke 41 with the submembrane cavity 20 and then through the choke 42 to the chamber 3 and

then through the choke 43 - with the output channel 2.

The device is mounted on a gas heat engineering unit with a main burner 44 and a pilot burner 43 connected to the device by gas pipelines 46 and 47, respectively. A crane 48 is installed in front of the main burner.

Sensors of the nozzle-flap type with nozzles 49-51, bimetallic flaps 52 and 53, and dilatometric flap 54 are connected to the device for monitoring and regulating the gas unit. The sensors are connected to the device by impulse tubes 55 and 56.

The device control and regulation of the gas unit operates as follows.

In the initial state, the inlet pressure in the cavity 8, the valve 5 with the diaphragm is pressed against the seat 4, the seat 9 is also closed with a spring-loaded valve 10, therefore the input channel of the device is reliably isolated from the output communications.

To start operation, press the start button 24, and the valve 48 must be closed, since the performance of the start button is designed only for the operation of the burner 45: a power to eliminate the possibility of a significant amount of gas entering the burner at start-up and ensure safety. When you press the start button 24 gas from the input channel 1 through the window 23, the chamber 3 and the gas line 47 enters the burner 45, which is fired. Under the action of the flame, the bimetal gate 52 closes the nozzle 49, and the nozzle 50 turns out to be normally closed by the valve 53, therefore the pressure in the submembrane cavity 20 rises due to the flow of gas from chamber 3 through the throttle 42, so that the membrane 19 through the plate 18 and the stem 17 removes the additional valve 10 from the saddle 9.

Thus, a self-blocking occurs, therefore the start button 24 can be released and the gas supply to the igniter will be maintained through the open seat 9. When the valve 48 is opened, the burner 44 ignites from the igniter and operates in the small mode defined by the throttle 43.

In the small mode, the choke 43 is not provided for in the construction.

At the start of operation of the gas unit, the temperature sensor nozzle 51, as a rule, is closed. Therefore, due to gas leakage through the choke 41 in the supramembrane cavity 38, the pressure 37 and the membrane 37 through the plate 36 and the rod 34 shifts the spring-loaded damper, 33 from the nozzle 35 to the nozzle 32. The overmembrane cavity 8 communicates through the nozzle 35, the submembrane cavity 39 and the window 40 s the atmosphere. Under gas pressure from below, the diaphragm 6 with the actuating valve 5 departs from the seat 4 and is fixed in the extreme upper position. The main gas flow goes to the burner 44 and the unit goes to the nominal mode of operation. As the coolant temperature reaches the value specified by the sensor, the dilatometric pump 54 opens the nozzle 51, the pressure in the supra-membrane cavity 38 drops and the burner switches back to the low operating mode in the reverse order of the described one. Thus, the temperature of the coolant is maintained near a predetermined value. If one of the parameters deviates from this mode (flame extinction, violation of draft, pressure drop and

opens, which leads to a drop in pressure in cavities 20 and 38; this causes a complete cessation of the gas supply to the igniter and the burner in the sequence opposite to that described.

Negligible small portions of gas, limited by the throttles 41 and 42 and the nozzle 35, discharged during operation into a special evacuation channel (not shown), can be taken to burned 44 for combustion, eliminating the loss of even the smallest portions of gas.

When carrying out preventive work and the need to disassemble the device, the lower part of the housing and the membrane 19 with the plate 18 and the skid 17 are removed. Then the valve 15 is removed and the seat 9 of the additional valve 10 is removed, made in the form of a sleeve, thereby opening camera 3, holes 12 and other hard-to-reach parts of the device.

After cleaning or replacement of parts, the device is assembled in reverse order.

The implementation of the additional valve seat in the form of a sleeve, the internal cavity of which is transversely communicated with the chamber and the chamber communicates with the inlet through the start button, which simplifies preventive maintenance of the device.

Claims (1)

DEVICE FOR MONITORING AND REGULATING A GAS UNIT, comprising a housing, input and output channels, an executive valve with a pneumatic amplifier of a controlled parameter, a start button, an additional valve with a seat connected through a rod to the membrane, a chamber connected via chokes to the output channel and control and regulation sensors , gaskets and a cover, which consists in that, in order to simplify preventive maintenance, the seat of the additional valve is made in the form of a sleeve, the inner cavity of which operechnymi windows communicated with the chamber, wherein the sleeve is isolated from the gas stream and of the atmosphere gaskets and pressed against the housing cover, and the camera is connected to the inlet _Λ through a start button. £ ω 1 1163097 ²