SU1589257A1 - Vacuum flow regulator - Google Patents

Abstract

The invention relates to hydraulic engineering, in particular to vacuum flow controllers, and can be used to stabilize the flow of water to irrigation systems. The aim of the invention is to improve the accuracy of the controller and the expansion of the range of regulation. The goal is achieved by the fact that in the flow controller containing a siphon water outlet 1 with a charging nozzle 3, a float sensor 6 level, an air intake device in the mouth of the siphon water outlet 1, additionally contains a tank 9 with a float 10 connected through a lever 18 with a cone 14 of a two valve valve body, also including a cone 15, placed in the housing 12, which forms an air intake device with a double valve valve body. 3 hp ff, 2 ill.

Description

The invention relates to hydraulic engineering and can be used to control and stabilize the flow of water on irrigation systems (including automated), as well as for other needs where water is required with a given constant flow rate.

The purpose of the invention is to increase the accuracy of the flow regulator and the expansion of the control range. (Figo depicts a vacuum regulator of flow, a general view; in Fig. 2, an air intake device.

The vacuum flow regulator containing this lever 18 performs the function of: a siphon outlet I, which is assembled by a pipeline 2 with a charge set 3, is in operation. A siphon mouth; water outlet 1 is equipped with a starting air nozzle 4, with an open valve JQ forcing valve 5.

: The vacuum flow regulator contains a level 6 float sensor; with a valve 7 placed in the drain hole 8, which is made in the tank 25 9 communicated with the upper reach. A float 10 is installed in the tank 9. With a stem 11. The vacuum flow regulator contains an air inlet device, made in the form of a housing on 12, communicated with the throat of the siphon water outlet 1 by the tube 13 and provided with a double valve shut-off element. Two valve valve body

the diverter moves the float 10 into the displacement of the cone 14, leading to the opening of the lower air intake opening in the housing 12 by a certain amount. A certain air flow starts to flow into the throat of the siphon outlet 1, reducing the regulator's capacity to a predetermined flow rate.

The water level in the downstream regulator is set at the design elevation, since the magnitude of this elevation, the position of the cones 14 and 15, the area of air intake through the openings of the housing 12 and the capacity of the siphon outlet 1. are interdependent. As the water level rises in the upstream, the difference between the upstream and downstream levels increases. With

made in the form of cones 14 and 15, once-, this should increase

placed respectively in the lower and upper parts of the casing 12. The cone 15 is placed on the rod 16 with a magnet 17 fixed on it. The kinematic connection between the float 10 and the cone 14 is made in the form of a lever 18 pivotally connected to the siphon water outlet 1. The cone 15 is placed on the rod 16 with the possibility of relative movement. The reservoir 9 is in communication with the upstream by the tube 19. Behind the siphon water supply 1, the flow goes around the water-measuring threshold 20. The task element 21 is installed on the rod 11.

The 1 / 1l regulator ramp for the required flow is set by the rod 21 (calibrated in advance) via the rod 11 (calibrated in advance), respectively, the position of the float 10 and the rod 16 on the cone 15. on the spot or remotely (for remotely controlled starting valve 5) valve 5 is closed.

40

45

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performance of the siphon water supply 1. But, as the level in the tank 9 also increases, the float 10 pops up, raises the cone 14 and opens the lower air inlet of the housing 12 even more, the air access to the throat of the siphon drain 1 increases and therefore, the capacity of the siphon outlet 1 remains the same. A further increase in the level of the upper reach cone 14 and at a certain moment (from the installation of the rod 16 in the position) hanging with its upper end of the rod to the magnet 17 is placed at the lower end of the rod 16 cone. From this moment both cones 14 and 1 begin to work together to ensure the intake of the required amount of air simultaneously through the upper and lower openings of the housing 12.

The supply of the lower end of the rod with the magnet 17 allows precise fixing

In this way, the access of air to the throat of the siphon outlet 1 is stopped, the working charge of the nozzle 3 through the pipeline 2 sucks air out of the throat of the siphon outlet 1, the siphon outlet 1 is activated. The water level in the downstream regulator rises, the float sensor 6 pops up and closes hole 8 in the bottom of tank 9. The water level in tank 9 rises and becomes equal to the water level in the upstream regulator. Float 10 pops up when

In this way, the lever 18 performs the function of converting the movement of the float 10 into the movement of the cone 14, leading to the opening of the lower air inlet in the housing 12 by a certain amount. A certain air flow starts to flow into the throat of the siphon outlet 1, reducing the regulator's capacity to a predetermined flow rate.

The water level in the downstream regulator is set at the design elevation, since the magnitude of this elevation, the position of the cones 14 and 15, the area of air intake through the openings of the housing 12 and the capacity of the siphon outlet 1. are interdependent. As the water level rises in the upstream, the difference between the upstream and downstream levels increases. With

0

five

0

five

siphon water supply capacity 1. But, as the water level in the tank 9 also rises, the float 10 pops up the cone 14 and opens the lower air inlet of the housing 12 even more, the air inlet to the throat of the siphon water outlet 1 increases and therefore The performance of the siphon outlet 1 remains the same. A further increase in the level of the upper reach, the cone 14 rises and at a certain moment (depending on the installation of the rod 16 in the desired position) with its upper end is attracted to the magnet 17 placed at the lower end of the rod 16 of the cone 15. From this moment both the cones 14 and 15 begin to work together, ensuring the intake of the required amount of air simultaneously through the upper and lower holes of the housing 12.

Providing the lower end of the stem 16 with the magnet 17 makes it possible to precisely fix the interposition of the cones 14 and 15 when they are. teamwork and dispense with the device of any guides to move the cone 15.

When the water level in the upstream of the regulator decreases, the total area of both air ports of the housing 12 decreases first, and with a further decrease only the area of the lower air inlet decreases, thereby the siphon and water outlet 1 remains unchanged, despite the reduction in the hydraulic flow differential, regulator.

Performing the cone 14 in the form of a sharp cone at the top, and the cone 15, on the contrary, in the form of a blunt cone at the top, helps to ensure smooth

expense, it contains reported with. the upper pool and the tank equipped with a drain hole, in which the float is placed, the air intake device is made in the form of a housing connected to the throat of the siphon water outlet and equipped with a two-valve shut-off element, kinematically connected to the float, and a valve in the drain hole connected with float level sensor.

2. Flow regulator according to claim 1,

15 characterized in that the two-valve shut-off opj-aH is made in the form of cones contacting each other, installed parallel to each other, with the tops down, injecting the required volume of air into the throat than one of the cones is placed in the top of the siphon outlet 1, which is necessary to maintain the design flow rate constant under the conditions of fluctuations of the headwater level in the entire range from minimum to maximum.

Invention Formula

1. A vacuum flow regulator containing a siphon water outlet connected by a pipe with a charge nozzle, a float level sensor associated with an air inlet device at the mouth of the siphon water outlet, characterized in that in order to improve the accuracy of the regulator

This part of the body is equipped with a rod with a magnet attached to it, and the other part is located at the bottom of the body.

3. The flow control valve in accordance with Clause D, t-25, which is characterized in that the kinematic connection between the float and the porous body is made in the form of a lever on which the float is fixed

and a cone located in the lower part 30 of the housing, and the axis of which is fixed on the siphon outlet.

4. The flow regulator according to claim 2, which is characterized by the fact that, in order to expand the range of the adjustable NIN, the cone in the upper part of the body is installed with the ability to move along the rod.

expense, it contains reported with. the upper buoy and the tank equipped with the drain hole, in which the float is placed, the air inlet device is made in the form of a body connected to the throat of the siphon water outlet and equipped with a two-valve shut-off organ, kinematically connected with the float, and a valve connected with the float level sensor

2. Flow regulator according to claim 1,

characterized by the fact that the dual valve shut-off opj-aH is made in the form of cones contacting each other, which are installed vertically down each other, with one of the cones placed in the upper part of the body and provided with a rod with a magnet attached to it, and the other at the bottom of the case.

3. The flow regulator according to claim G, which is characterized by the fact that the kinematic connection between the float and the locking organ is performed in the form of a lever on which the float is fixed

and a cone, located in the lower part of the body, and whose axis is fixed on the siphon outlet.

4. The flow regulator according to claim 2, which is characterized by the fact that, in order to expand the range of the regulator, the cone in the upper part of the body is mounted for movement along the rod.

FIG 2

Compiled by T. Zadvorna L.Pcholinska editor Techred L.Serdyukova Corrector V.Girn K

Order 2541

Circulation 653

VNIIPI State Committee for Inventions and Discoveries at the State Committee on Science and Technology of the USSR 113035, Mockea, Zh-35, 4/5 Raushsk Nab.

Production and Publishing Combine Patent, Uzhgorod, st. Gagarin, 101

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Claims (4)

Claim 1. A vacuum flow regulator containing a siphon outlet connected to a charging nozzle by a pipe, a float level sensor connected to an intake device is inserted into the neck of the siphon outlet, characterized in that, in order to increase the accuracy of the flow regulator, it contains a message connected to. the upper pool and the tank equipped with a drain hole, in which the float is placed, the intake device 5 of the air is made in the form of a housing in communication with the neck of the siphon outlet and equipped with a two-valve shut-off element kinematically connected to the float, moreover, a valve connected to the float level sensor is placed in the drain hole, 2. Flow controller according to π. 1, 15 characterized in that the two-valve shut-off element is made in the form of cones contacted to each other, mounted vertically downward coaxially with one another, one of the cones being placed in the upper part of the body and provided with a rod with a magnet fixed to it, and the other in bottom of the case. 3. Flow controller according to π. I, t25 characterized in that the kinematic connection between the float and the locking element is made in the form of a lever on which the float and cone are mounted, located in the lower part 30 of the housing, and the axis of which is fixed to the siphon outlet. 4. The flow regulator according to claim 2, characterized in that, in order to expand the regulation range, the cone in the upper part of the housing is installed with the possibility of movement along the rod.