SU1718193A1 - Flow regulator - Google Patents

Abstract

The invention relates to automatic regulation and can be used for the dosed supply of gas in technological processes. The purpose of the invention is to expand the range of adjustment and increase accuracy. The flow regulator includes a housing, between the inlet and outlet cavities of which a regulating member is installed, a sensing element forming a control cavity with the housing that is connected to the input cavity through a variable throttle formed by a float located in the measuring tube, leading and driven gears with annular the grooves between which the control tube is installed, located in the measuring tube, connected to the input and control cavities, and provided with openings in the upper end and a travel stop along melting mounted on a regulating tube with the formation of variable choke points with openings; the regulator is made in the form of a sleeve fixed in the housing with diametrical holes through which the inlet cavity is connected to the output cavity and a hollow shaft installed in the sleeve in which a slide valve is installed along the guides, the diametrical holes are made in the hollow shaft and in the slide valve the sensing element, and the hollow shaft is kinematically connected with the pinion gear, and the measuring tube is connected to the output cavity. 6 Il. “Yo

Description

The invention relates to the field of automatic regulation and can be used for the dosed supply of gas in technological processes.

Known regulators include a housing with inlet and outlet channels, between which a regulator is installed, made in the form of a disk mounted in the inlet channel. A tuning unit, made in the form of a piston, spring-loaded with a spring, tucked under the binder with a drainage hole, is connected to the disk with the help of a rack and pinion mechanism.

However, such a device does not provide for a change in costs over wide ranges, and the spring stiffness reduces the control accuracy.

A device comprising a first body with inlet and outlet nozzles, between which a regulating member is installed, a sensitive element made in the form of a bellows installed in the first body, a narrowing device mounted on the inlet nozzle, a regulating body made in the form of coaxially arranged tubular elements, one of which is connected to the bottom

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bellows, with the bellows cavity connected to the inlet pipe to the tapered device, and the inner bellow cavity is connected to the second tubular element.

However, such a device does not provide a change in the gas flow rate in a wide range.

Closest to the invention is a device comprising a housing, between the inlet and outlet cavities of which a regulating member is installed, a sensing element forming a control cavity with the housing, which is connected to the inlet cavity through an alternating choke formed by a float measuring tube.

However, such a device also does not provide a change in gas consumption over a wide range ...

The purpose of the invention is to expand the adjustment range and increase accuracy. This will increase the stability of technological processes.

The goal is achieved by those. that the controller contains driving and driven gears with annular grooves, between which a control tube is installed, located in a measuring conical tube, one end connected to the input and control cavity of the mi cutter. At the upper end of the tube there are openings and a float stator that moves freely along the regulating tube and in the upper position it closes the apertures of the regulating tube, forming a variable choke with the measuring tube.

The regulating choke is made in the form of coaxially arranged sleeves, a hollow shaft and a spool having diametrical holes connecting the input cavity with the output one. In the hollow shaft mounted in the sleeve, a spool is mounted along the guides connected to the sensing element, and the hollow shaft is connected kinematically with a worm gear to a drive gear by means of a worm gear, and the measuring tube is connected to the output cavity.

FIG. 1 shows the regulator, a general view; in fig. 2 shows section A-A in FIG. one; in fig. 3 shows a section BB in FIG. one; in fig. 4 and 5 are diagrams of blocking the channel connecting the input and output cavities; FIG. 6 is a view B of FIG. 3

The flow regulator contains a housing with an inlet nozzle, inside of which a regulating tube 7 is installed with openings in the upper end, limiter 8 of the float stroke and a float 11. On the housing flange 1, a measuring tapered tube 6 is installed through the sealing ring 5.

the upper end of which, through the sealing ring 9, is a flange 10 with an outlet branch pipe. A flexible tube 13 is put on the lower end of the regulating tube 7, which connects the output cavity with the cavity of the sensing element and the entrance cavity of the housing 1 through the jet 17.

The drive pinion shaft 4 is a worm shaft, which engages with a worm wheel 14 of a hollow shaft 3. Inside the hollow shaft, a spool 2 is installed along the guides, which is preloaded on one side by a spring 19 with a reduction screw 18, and the other side is a sensitive element 15. connected to the cover 16. Slave gear 12 is mounted on the axis 21. The tightness of the movable joints is provided by the sealing rings 20.

The sleeve, the hollow shaft and the slide valve have diametrical holes. The rectangular forms, respectively, A, B, C and the flow area of G.

The flow regulator operates as follows.

In the initial state, the regulating tube 7 is lowered down, the float 11 covers the upper holes, closing the outflow of gas from the cavity of the sensing element 15. Connected to the inlet pipe channel D. The bushing casing of the housing 1 is blocked by a hollow shaft 3. The applied pressure propagates into the cavity of the sensing element 15 and moves the spool 2 to the extreme position, blocking the diametrical holes of the hollow shaft and ensuring complete shut-off of the gas supply ..

When the flow adjustment knob is rotated, the rotation is transmitted to the driven shaft with a worm, as well as driving and driven gears 12. Tube 7 rises to a predetermined level determined by the scale of the measuring tube 6. The holes in the upper end of the regulating tube 7 open and the pressure in the cavity drops sensor 15, the spool 2 opens the passage hole in the spool. At the same time, through the worm gear, turn the worm gear 14 with the shaft 3, a passage channel H is formed. Gas rushes through the inlet cavity to the exit one, and the float 11 rises to the level specified by the regulating tube 7.

The automatic maintenance of the flow rate is carried out in the following sequence. As the inlet pressure rises, it spreads into the cavity of the sensing element 15, which, expanding, closes the bore hole G by moving the spool 2, reducing the gas flow. When the inlet gas pressure decreases, the reaction is reversed. When the flow rate decreases, the float 11 is lowered, opening the holes on the regulating tube 7. The gas outflow from the cavity of the sensing element 15 is ensured, reducing the pressure in it. The sensing element is compressed, moves the spool 2 to increase the orifice G, increasing the gas flow.

Claims (1)

The invention The flow regulator, comprising a housing, between the inlet and outlet cavities of which a regulating member is installed, a sensitive element forming a control cavity with the housing, which is connected to the input cavity through a variable throttle formed by a float located in the measuring tube, from T - in order to expanding the range of regulation and increasing the accuracy of the regulator, it contains driving and driven gears, with annular grooves between which a regulating tube is installed, located in the measuring tube, connected to the inlet and control cavities and provided with a hole in the upper, end, and stroke limiter mounted on a control tube with forming a variable throttle with a hole, the regulator is designed as a sleeve fixed in the housing with a diametrical hole through which the inlet cavity is connected to the output cavity, and a hollow shaft installed in the sleeve in which a spool is mounted along the guides and diametrically in the hollow shaft and slide the bore, the spool is connected to the sensing element, the hollow shaft is kinematically connected to the drive gear, and the measuring tube is connected to the output cavity of the housing. Vfffffifl exit To aneroid 1 Shig.2 bb sixteen 15 Fig R Rig.6 Compiled by A. Volkhov. Editor I. Vanyushkina Tehred M. Morgental 6 Proofreader O. Tsiple