SU1765321A1 - Hydrant - Google Patents

Abstract

Usage: in irrigation systems. The essence of the invention: the locking member has the possibility of vertical movement in the sealing cuff and is made with an axial channel, the hydraulic actuator with a switch and a piston. The piston is connected to the shut-off organ by a vertical tube, to-between communicates the cavities of the inlet pipe of the housing and the hydraulic drive through the axial channel of the organ. The switch is equipped with an ejecting tube, the output end of the cut is installed in the discharge pipe of the housing along the flow and hydraulically with a pressure pipe, the output end of the cut is placed in the discharge pipe and directed towards the flow, and made in the form of a crane with an adjustable return spring connected to the hydraulic rod. The locking member is provided with a valve that closes the axial channel and is connected to the switch. The locking member is made with a float chamber and vertical perforated guides mounted above it, 1 Cp. F-ly, 2 sludge. with

Description

The invention relates to water stop fittings, in particular to columns installed on irrigation systems.

A hydrant column is known, comprising a rotatable body with a cuff, water outlet pipe, tubular elements with windows, a valve connected to the hydraulic diaphragm actuator by means of a rod. At the same time, the valve is installed inside the branch pipe with windows, and the hydraulic actuator is connected to the subvalvular cavity through a spool device and a tube

one.

The disadvantages of this hydrant column:

the relative complexity of the design, associated with the implementation of the membrane actuator, spool device, tubular elements, valve:

The absence of water discharge from the supramembrane and supravalvale cavities during frost damage:

unreliability of the diaphragm actuator and valve;

large head losses due to the complex flow path in the hydrant column;

when closing, the water from the spool device and the diaphragm actuator is dumped out onto the ground;

the diaphragm actuator provides only abrupt closing and opening, leading to hydraulic shocks and damage to the mains and columns;

the column does not release air plugs in time from the network, which leads to hydraulic shocks and vibrations;

the column does not automatically close the flow if damaged

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a sprinkler attached to it, leading to water loss and soil erosion.

Closest to the proposed technical solution is a water intake column comprising a housing with inlet and outlet pipes, a locking member having the possibility of vertical movement in the sealing cuff and completed with an axial channel, a hydraulic actuator with a switch and a piston connected to the locking organ a vertical tube, by means of which the cavities of the inlet pipe and the hydraulic actuator communicate with each other through the axial channel of the closure member 2.

The disadvantages of this water intake column is that in emergency situations the water supply is not turned off, which leads to further destruction of the system. In addition, water is discharged from the hydraulic drive to the ground, the work of the indicated organ is unreliable, especially in case of breakdowns, it is impossible to ensure constant flow.

The purpose of the invention is to increase the reliability in emergency situations.

The goal is achieved by the fact that in a column containing a housing with inlet and outlet nozzles, a locking member having the possibility of vertical movement in a sealing cuff and made with an axial valve, a hydraulic actuator with switches and a piston connected with a locking organ of a vertical tube, by means of which the cavities of the inlet pipe and the hydraulic drive through the axial channel of the closure member communicate with each other, the switch is equipped with an ejecting tube, the output end of which is installed in the outlet pipe at the flow, and hydraulically with a pressure tube, the output end of which is placed in the outlet pipe and directed towards the flow, and is designed as a valve with an adjustable return spring connected to its hydraulic drive rod, and the valve body is equipped with a valve that can close its axial channel connected to the switch.

In addition, the locking member is provided with a float chamber and vertical perforated guides mounted above it.

Distinctive features of the proposed technical solution in combination with the known ones ensure the achievement of a positive effect, which consists in simplifying and increasing the reliability of the design of the standpipe, increasing its versatility, improving the hydraulic parameters and preventing water losses. Thanks to doing all

the set of features, the column provides smooth closing and opening, damping of water hammer, is a plunger safety lock, automatically closes in case of breakdowns of machines connected to it.

0 FIG. 1 shows a longitudinal section of a water column in the open position; in fig. 2 - a kinematic connection of a tap to a valve of a tube when closing a water selection column.

5 The water dispenser consists of a housing 1 with a discharge pipe 2, a mounting flange 3, a closure member with an axial channel (not indicated) and its hydraulic drive with a switch (not indicated). Cor0 PUS 1 is equipped with a cuff 4, stops 5 and 6, while the latter are made removable. The housing 1 is placed rotatably in the cuff 7, fixed in the flange 3, and the upper arms 5 and 6 of the housing are located above and below it.

To simplify the design and increase reliability, the locking member is made in the form of a float chamber 8 filled with foam plastic 9 and equipped from above with

About the edge of the perforated guides 10, between which the culvert windows 11 are formed. With this design, the float chamber 8 can be made of a conventional pipe in which the

5 culvert windows 11. In the float chamber 8 is made of an axial channel (not labeled),

To simplify construction, increase reliability, improve hydraulic

Q parameters, reducing water hammer body 1 from above is plugged with a plug 12 and is divided by a partition 13 into cavities 14 and 15. At the same time, a piston 16 is placed in the upper cavity 14, which presents a hydraulic drive. The cavity 14 is provided with an opening 17 for air outlet and air inlet.

For ease of installation and repair, the partition 13 is made removable and a gland 18 is fixed on it, in which is placed

The Q piston rod 16, made in the form of a tube 19, by means of which the over-piston cavity 14 communicates through the axial channel in the shut-off organ with the space of the inlet pipe 20.

To increase the reliability and simplify the design of the piston control system 16, as well as to prevent water from being ejected from the piston cavity 14, its switch is made in the form of a tap 21 with a passage 22, housing 23 sec.

an opening 24. A valve 21 is fixed on the plug 12 and communicated on one side with the over-piston cavity 14, and on the other side with the ejection tube 25 with the outlet nozzle 2. The ejection tube 25 is directed with its end toward the outlet port of the nozzle 2, i.e. downstream.

To prevent water leakage at the time of closing the column and disconnecting the leaching machine, as well as to ensure smooth closing and opening of the flow at the lower end of the axial channel of the closure member, i.e. the float chamber 8, a valve 26 is provided, which is kinematically connected to the valve 21.

To prevent water losses and ensure timely closure of the column when the pipeline is broken or the sprinkler is connected to the outlet nozzle 2, the valve 21 is kinematically connected with a hydraulic actuator made in the form of a piston rod 27 of the hydraulic cylinder 29, the piston chamber communicated by means of a pressure pipe 30 with a discharge pipe 2. In this case, the end of the pressure tube 20 is directed toward the water outlet port 31 of the housing 1, i.e. towards the stream.

To regulate the timely closing and opening of the crane 21 and, consequently, the column hydrant, the rod 27 of the piston 28 is provided with a regulator made in the form of a return spring 32 and a graduated screw 33.

The crane 21 is mounted rotatably around a vertical axis, fixed to the plug 12 of the housing 1 by means of a tube 34 and is kinematically connected to the valve 26 through a rotary plate 35 and a telescopic connection, made in the form of a tube 36 and stop plates 37, which are fixed in tube 36 is rigid and between which, with the freedom of vertical movement, the upper end of plate 35 is placed.

In order to increase reliability, the valve 26 of the tube 19 and the axial channel of the float chamber 8 is made in the form of a perforated rubberized disk 38, i.e. equipped with an elastic casing 39. The hard disk 38 is fixed on the axis 40, which is fixed on the plate 35 and installed with free rotation in the center of the bottom 41 of the axial channel of the chamber 8 and the tube 19, which is provided with openings 42 for the passage of water. Holes 43 are also formed in the disk 38 and its shell 39, which are located at the same distance from the center as the holes 42 in the bottom 40.

The column works as follows. In the initial position, the valve 21 is disconnected from the rod 27 and is open, the holes 42 in the bottom 41 are closed, i.e. tube 19 is blocked. TO

The water outlet pipe 2 is connected to a pipe or a sprinkler (not shown). Float chamber 8 is in the lower position. When water is introduced into the network, the air freely exits the system through windows 11. When the system is filled with water, chamber 8 rises upward (Fig. 2). As a result, the cuff 4 of the body 1 is pressed against the float chamber 8, and the cuff 7 of the flange 3 is pressed against the body 1, such

water leakage is prevented.

To open the valve 21, it is connected to the rod 27 of the piston 28 of the hydraulic cylinder 29 and is closed. Together with the crane 21, the plate 35 and the disk 38 with the shell 39 are rotated, as a result of which the holes 43 coincide with the holes 42 in the bottom 41, the entrance to the tube 19 opens. Water through the holes 42 and 43 enters the tube 19, and from it into the over-piston cavity 14. Since

the area of the piston 16 is larger than the cross sectional area of the float chamber 8, then they smoothly descend downwards under the pressure force created in the over piston cavity 14. As a result, water flows through the windows 11 and

the holes in the guides 10 into the cavity 15 of the housing 1, and from the latter through the outlet port 31 into the outlet pipe 2 and further to the sprinkler. In the initial period, the valve 21 is held in the closed position manually or by compressing the spring 32 with a screw 33. With the full start of the sprinkler and the creation of a working head in it (in the system as a whole), the screw 33 is released by a predetermined amount.

The water column closes in reverse order. The tap 21 opens, as a result of which the openings 42 in the bottom 41 are closed, the flow of water to the tube 19 is stopped. Since ejecting

Because the tube 25 is directed by the end hole in the direction of the outlet of the stream, then at the initial moment of closure an ejecting effect is created and water is sucked out of the piston cavity 14. At the same time

when the water supply to the latter is interrupted, since the valve 16 blocks the entrance to the tube 19, under the action of the pressure from below and the buoyancy force, the float chamber 8 together with the piston 16 rises up. The plate 35 also freely enters the tube 36.

When the water intake column is open, the openings of the channel 22 of the tap 21 do not coincide with the openings 24 of its body, and when they are closed, they coincide.

Water from the piston cavity 14 flows out to the outside, and into the cavity of the outlet pipe 2.

In the working position, the standpipe is open, and the head required for the operation of the sprinkler is installed. If the pipeline of the latter is damaged or an additional water leak occurs, the velocity head in the outlet pipe 2 increases. Since the pressure tube 30 is directed towards the flow, an overpressure occurs in the hydraulic cylinder 29 in the sub-piston space. The piston 28 together with the rod 27 compresses the spring 32 and rotates the crane 21, as a result of which the latter opens, leading to the release of water from the piston casing 14 of the housing 1 and the closing of the valve 26, to the cessation of the water supply to the cavity 14 and the lifting of the piston 16 and the float chamber 8, i.e. to reduce and stop the supply of water to the irrigation machine. Due to this, water loss and soil erosion are reduced, and further damage to the machine is prevented,

When water is discharged from the network, air flows freely into the system through the gaps between the cuffs 4 and 7 and the sealing surfaces, as well as through the tube 19. At the same time, the float chamber 8 goes down and all the cavities of the column are automatically freed from water, which prevents damage to the units by frost. .

Thus, in comparison with the prototype, the proposed water dispenser is more reliable, provides smoother closing and opening, prevents water losses, is more versatile, is a plunger and safety valve, turns off the water if the machines or pipelines connected to it break.

Claims (1)

1. A separation column comprising a housing with inlet and outlet nozzles, a locking member having the possibility of vertical movement in a sealing cuff and made with an axial channel, a hydraulic actuator and a piston connected to the locking member by a vertical tube, through which the cavities of the inlet fitting and the hydraulic drive through the axial channel of the closure member communicates with each other, characterized in that, in order to increase reliability in emergency situations, the switch is provided with an ejection tube, the output end of which is installed in the discharge branch pipe downstream, and hydraulically with a pressure tube, the output end of which is placed in the discharge branch pipe and directed towards the flow, and is designed as a crane with an adjustable return spring connected to the stem of its hydraulic actuator; the body is equipped with the possibility of blocking its axial channel valve connected to the switch. 2, a column according to claim 1, characterized in that the intake organ is provided with a float chamber and vertical perforated guides mounted above it. Oh N i 33 23 g8 four/ 55 3