SU1147293A1 - Command pulse generator for forced irrigation system - Google Patents

Abstract

PULSE GENERATOR FOR COMMAND PRESSURE IRRIGATION SYSTEMS comprising gidrorele time, consisting of two hydraulic motors antiphase membrane forward and reverse with a common rod ,, internal cavity which communicated through drosgel and partially filled with oil and connected via external distributor valve kinematically coupled through a lever-trigger switch with a common stem of the diaphragm actuators, to a pressure pipeline or to the atmosphere, and a time interval controller, characterized in that increase reliability and simplify the design, the internal cavity of the back-up hydraulic motor is filled with air and provided with a tube with a drain plug located above the oil level in the cavity, the time interval controller being designed as a hydraulic cylinder, the internal cavity of which is connected to the internal cavity of the back-up hydraulic motor below the oil level in it, and its piston is driven by an adjusting screw.

Description

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The invention relates to agriculture, in particular to devices for the automation of irrigation systems.

The purpose of the invention is to increase reliability and simplify the design.

The drawing shows a schematic diagram of a generator of kolvfndnyh pulses for pressure irrigation systems.

The generator contains a time relay 1 equipped with a tube 2 with a drainage plug and a regulator of 3 time intervals, a throttle 4, a valve distributor. 5, a lever / trigger switch 6, a control check valve 7 and a drain valve 8.

Time relay 1 consists of two membrane hydraulic motors - forward 9 and 10 reverse stroke, in a case II divided by a partition, which are installed piston 12 with a common rod 13 with stops 14 and 15 on it and membranes 16 and 17 forming a cavity with a case and a partition A, B, C and G. Cavity A by means of pipelines 18 and 19 is hydraulically connected with valve distributor 5, and sweat D by means of pipelines 20 and 21 - with pressure pipe 22. Cavity B is filled with working fluid, for example oil, cavity C - air and oil and both of these cavities communicate with each other through the throttle 4. The cavity communicates with the oil layer situated above the tube 2, with a drainage tube, and below the oil level - with the regulator 3 timeslots.

The regulator 3 time intervals is designed as an amount of oil flowing through the throttle 4, which changes the duration of displacement of the hydraulic motors diaphragms and, consequently, the duration of the hydraulic cylinder 23 pulses with the piston 25 driven by the adjusting screw 24 and the internal cavity D communicating with the cavity B of the reverse motor 0.

The throttle 4 is made in the form of a package of throttle plates, pre-selected, tuned in the manufacturing process to the maximum necessary hydraulic resistance.

Valve. valve 5 contains a valve 26 with a stem 27, which interacts with a lever-trigger switch. Process 6, kinematically connected with a common stock of 3 diaphragm actuators, and a drain hole 28.

A controlled check valve 7: installed on the pressure pipe 22, has a membrane 29 with a spring-loaded shut-off member 30 and a pipe 31. connected to. drain valve 8 with -membrane 32 mounted on control pipeline 33. Submembrane control cavities

the return valve and the drain valve are hydraulically connected via pipeline 18 to the valve distributor 5.

The generator works as follows.

In the closed position of the locking member 30, water from the pressure pipe 22 flows under pressure through the pipeline 20 to the valve distributor 5, from which through the pipeline 18 to the submembrane cavities of the drain 8 and the controlled check valve 7. As a result, the first is closed, and the second is opened and the water from the pressure pipe 22 passes into the control pipe 33 and further into the irrigation system. At the same time, water enters the cavity A of the hydraulic motor .9 through pipeline 19 and into the cavity 7 of hydraulic engine 10 through pipeline 21. Since the effective area of the membrane 16 is larger than the area of the piston 12, the force created by the pressure of water from the membrane, more force from the piston and therefore the oil it is distilled from cavity B through choke 4 to cavity B, and the rigidly connected membranes 16 and 17 move the common rod 13 to the upper position. The time of movement of the membranes from one extreme position to the other, and consequently, of the common stem 13, is set with the help of throttles 4 and the time interval adjuster 3, which is carried out (hydraulic resistance of throttles constantly) all the adjustment of the change in the volume of distilled oil through the throttle through the selection or delivery of certain portions of oil using the adjusting screw 24. At a certain point in time, the stop 14 of the common rod 13 with the help of a lever-trigger switch 6 opens the valve valve 5 to drain into tmosferu water from cavity A and submembrane valve holders 7 and. At the same time, the drain valve 8 is turned off, and the controlled check valve 7 is closed.

Water from control pipeline 33 is discharged into the atmosphere, creating a low pressure pulse therein. At the same time, the water entering the cavity G through the pipeline 21, with its pressure on the piston 12, moves the common rod 13 downwards and, consequently, the membranes 17 and 16. The membrane 17, moving outwardly, first displaces into the cavity B through the choke 4 enclosed in the upper parts of the cavity B air (this part of the stroke occurs quickly, since the viscosity of the air is less than the oil), and then the oil is distilled through throttle 4 from cavity B into the cavity B until the valve 26 of the valve distributor 5 is switched by means of a lever-trigger switch 6. At the same time yx It appears at the top of the cavity B and on the next course of membranes up through the first throttle is displaced air, and is then distilled

oil until the next actuation of the lever-trigger switch c. If the valve distributor is opened and the control pipeline is re-energized, a boost is generated. Further, the operation of the generator is repeated in a similar way.

Thus, bypass air and oil and change with the help of the time interval regulator of the ratio of their volumes to 1 and 1 prop. 1 MONITOR the total time of the pulse.

Yspi.: 1b: i) nan11e as a regulator of temporal HHTCjjn.-i.ioB hydro-ilillin with an internal cavity, combined with an internal cavity of a reverse hydrostatic piston and a piston driven by an adjusting screw, allows to increase the reliability of the operation of the generator of command pulses and unstroke his design.

Claims (1)

COMMAND PULSE GENERATOR FOR HEADED IRRIGATION SYSTEMS, including a time hydraulic relay, consisting of two antiphase diaphragm direct and reverse hydraulic motors with a common rod, the internal cavities of which are communicated through the throttle and partially filled with oil, and the external ones are connected through a valve distributor kinematically connected through lever-trigger switch with a common rod of membrane actuators, to the pressure pipe or to the atmosphere, and a time interval regulator, characterized in that, in order to increase To improve reliability and simplify the design, the internal cavity of the backhaul hydraulic motor is filled with air and equipped with a tube with a drainage plug located above the oil level in the cavity, and the time interval controller is made in the form of a hydraulic cylinder, the internal cavity of which is connected to the internal cavity of the backward hydraulic motor below the oil level in it, and its piston is driven by _a setting screw. 18 “Che with so