SU1271455A1 - Pulsed sprinkler - Google Patents

Abstract

The invention relates to agriculture, namely to the field of irrigation of agricultural crops by sprinkling. The purpose of the invention is to increase the reliability of work, ensure the stabilization of the operating mode and simplify the design. Pulse sprinkler includes a mechanism for ejection in the form of a hydraulic cylinder 5 of double action. The ball 22 of the piston 6 of the hydraulic cylinder 5 is installed with the possibility of shutting off the drain bore 20. The sub valve 25 and the supra plunger 24 cavities are connected to the pressure line 29 and the rod end 30. When pressure is applied, the end of the stop 26 installed in the subvalvular cavity 25 pushes the ball 22 away from the saddle. The working fluid will go to the drain. The pressure in line 29 will drop. When the stem 8 is moved to the right, the water in the accumulation tank is compressed to the setting value of the pulse valve 17. At the design pressure, the valve 17 will move to the left. Under the action of pressure drop in the cavity 14, the valve 2 opens the interchangeable nozzle 3. Adjusting the pressure (O valve 17 and three-stage actuation (With that valve, you can change the ejection volume, rain intensity and pulse frequency. 1 Il.

Description

The invention relates to irrigation of crops and can be applied in sprinkler systems with pulsed sprinklers.

The purpose of the invention is improving the reliability, ensuring stabilization of the operating mode and simplifying the design.

The drawing shows a structural diagram of a pulsed sprinkler.

The pulse sprinkler apparatus 1 includes a barrel 1, inside which an automatically acting locking element 2 is placed, spring-loaded with respect to the conical chamfer at the outlet, in which the replaceable nozzle 3 is mounted, by a spring 4. The pulse ejection mechanism is made in the form of a double-acting hydraulic cylinder 5 with a piston 6, spring-loaded relative to the housing by a power spring 7, interacting through the rod 8 with a capacity of 9 for the accumulation of water. The tank 9 is connected through a non-return valve 10 to a low-pressure conductive irrigation network, by means of a throttle 11 to a nadklapannym cavity 12 and through passage channels 13 to a cavity 14 in front of the replaceable nozzle 3. Naklapanny cavity 12 through the channel 15 is constantly connected to the cavity 16 of the pulse valve 17 The spring-loaded three-stage valve comprises a housing 18 with a seat 19, a drain bore 20, a plunger 21 and a ball 22 to form a drain 23 over the plunger 24 and a subvalve 25 cavities. The piston 6 is provided with a stop 26 mounted in the subvalvular cavity 25 with the possibility of interacting with the ball 22 installed with the possibility of overlapping the drain bore 20, the seat 19 is made in the supravalve cavity 25. The subvalvular 25 and the supraplunger 24 cavity are interconnected by a line 27 and a line 28 - with pressure line 29 and rod cavity 30.

Pulse sprinkler apparatus operates as follows.

The working fluid pumped by the hydraulic pump 21, of the basic self-propelled chassis on which the device is mounted, enters the rod cavity 30 via line 29 and into the subvalve cavity 25 through line 28, from where it passes through the line 27 to the supraplunger cavity 24. Since the area of the first stage with the side of the subvalvular cavity 25 is smaller than the area of the third stage from the side of the supraplunger cavity 24, then the ball 22 under the action of the difference of pressure forces by the spring-loaded plunger 21 is received to the seat 19.

The working fluid in the rod cavity 30 acts on the piston 6 and moves it with the rod to the left position, compressing the power spring 7. This movement is transmitted to the stop 26, fastened to the piston 6. The rod 8 occupies the leftmost position and releases the volume in the cavity 9, which through the check valve 10 is filled with the next portion. water from a low pressure conductive irrigation network. The end of the stop 26, overcoming the stiffness of the spring-loaded plunger 21 and the pressure from the cavity 30, depresses the ball 22 from the seat 19. The area of the ball, which is affected by the pressure θ of the working fluid, increases and due to the fact that the area of the third stage is smaller than the second ball 22, squeezed spring-loaded plunger 21, moves to the left. The cavity 24 is connected and the _5th cavity 23 is drained, and the working fluid is drained. The pressure in line 29 drops. The piston 6 of the hydraulic cylinder 5 together with the rod 8 under the influence of the power spring 7 are displaced to the extreme right position, the working fluid from the rod cavity 30 is discharged. When the pressure in the subvalvular cavity 25 decreases to the drain, the spring-loaded plunger 21 moves the ball 22 to the right position and presses it against the seat 19 in the valve body 18. The discharge of the working fluid through the cavity 23 stops and the cycle repeats. The rod 8, moving to the right position, compresses the water in the accumulation tank 9 to the pressure at which the pulse valve 17 is configured. 30 Upon reaching the design pressure in the cavity 16, which is connected by a channel 15 to the supravalve cavity 12, the pulse valve 17 moves to the left the position and the water is drained from the cavity 16. Under the action of a pressure differential in the under 35 valve cavity 14, the automatically acting shut-off element 2 opens and water is discharged onto the irrigated surface through the replaceable nozzle 3. Next, the duty cycle is repeated in automatic mode. By appropriate adjustment of the operating pressures of the pulse valve 17 and the three-stage valve, as well as by adjusting the capacity of the hydraulic pump 21 and the diameter of the replaceable nozzle 3, it is possible to vary the range 45 and the ejection volume, rain intensity and pulse frequency over a wide range.

Claims (1)

Feeding 8odes The invention relates to the irrigation of agricultural crops and can be applied in sprinkler systems with pulsed sprinklers. The purpose of the invention is to increase the reliability of work, ensure the stabilization of the operating mode and simplify the design. The drawing shows a constructive scheme of a pulse sprinkler. Pulse sprinkler includes a barrel 1, inside of which is placed automatically acting locking body 2, spring-loaded relative to the conical chamfer at the outlet. in which a replaceable nozzle 3 is installed, a spring 4. The pulsed jet ejection mechanism is made in the form of a double-acting hydraulic cylinder 5 with a piston 6, spring-loaded relative to the body by a power spring 7, cooperating through a shaft 8 with a capacity 9 for storing water. The tank 9 is connected via a non-return valve 10 to a low-pressure conductive irrigation network, through drossel 11 to the over-valve cavity 12 and through passage channels 13 to the cavity 14 in front of the replaceable nozzle 3. The valve 15 is constantly connected to the cavity 16 of the pulse valve 17. The spring-loaded three-stage valve includes a housing 18 with a saddle 19, a drain bore 20, a plunger 21 and a ball 22 to form a drain 23 above the plunger 24 and under valve 25 cavities. Porschen 6 is equipped with a stop 26 installed in the sub-valve cavity 25 with the ability to interact with the ball 22 installed with the possibility of overlapping the drain bore 20, the saddle 19 is made in the over-valve cavity 25. The sub valve 25 and the above-plunger 24 cavity are interconnected by a line 27 and line 28 - with pressure line 29 and the rod end 30. Pulsed sprinkler works as follows. The working fluid pumped by the hydraulic pump 21 of the basic self-propelled chassis on which the device is mounted, via line 29 enters the rod cavity 30 and, through line 28, into the subvalvate cavity 25, from where, via line 27, into the super plunger cavity 24. Since the area of the first stage is the side of the subvalvular cavity 25 is smaller than the area of the third stage on the side of the pre-plunger cavity 24, then the ball 22 under the action of the difference in pressure forces with the spring-loaded plunger 21 is attached to the saddle 19. The working fluid in the rod cavity 30 acts on the piston 6 and moves it with the brush to the left position while compressing the power spring 7. This movement is transferred to the stop 26 fastened to the piston 6. The rod 8 takes the leftmost position and frees the volume in cavity 9, which through the check valve 10 is filled with another portion of water from low pressure conducting irrigation network. The end of the stop 26, overcoming the stiffness of the spring-loaded plunger 21 and the pressure from the cavity 30, pushes the ball 22 from the saddle 19. The area of the ball that is affected by the pressure of the working fluid increases and due to the fact that the area of the third stage is less than the second ball 22 the plunger 21 moves to the left, the cavity 24 and the drain cavity 23 are connected, and the working fluid goes to the drain. The pressure in line 29 drops, the piston 6 of the hydraulic cylinder 5 together with the rod 8 under the influence of the force spring 7 is shifted to the extreme right position, the working fluid from the squamous cavity 30 is drained. When the pressure in the sub-valve cavity 25 decreases to the drain, the spring-loaded plunger 21 moves the ball 22 to the right position and presses it against the seat 19 in the valve body 18. The draining of the working fluid through the cavity 23 stops and the cycle repeats. The rod 8, moving to the right position, compresses the water in the accumulation tank 9 to the pressure to which the pulse valve 17 is set. Upon reaching the design pressure in the cavity 16, which is connected to the valve cavity 12 by channel 15, the pulse valve 17 moves to the left position and water is drained from the cavity 16. Under the action of the pressure drop in the subvalvular cavity 14, the automatically acting locking member 2 opens and water is ejected onto the irrigated surface through the replaceable nozzle 3. Further, the duty cycle is repeated in automatic mode. By appropriately setting the trigger pressure of the pulse valve 17 and the three-stage valve, as well as by adjusting the performance of the hydraulic pump 21 and the diameter of the replaceable nozzle 3, the range of the discharge volume, the rain intensity and the frequency of the pulses can be varied over a wide range, including the impulse sprinkler, a body, a barrel with a nozzle, a locking member, a pulsed ejection mechanism, made in the form of a hydraulic cylinder with a piston and a rod cavity, and a spring-loaded three-stage a valve with a housing, a saddle and a drain bore and a plunger and a ball mounted therein with the formation of a drain, subvalvular and supra plunger cavities, characterized in that, in order to increase the ball, the saddle is made in the subvalvular reliability of the operation, ensuring the stabilization of the cavity, and the ball is installed with the possibility of operating mode and simplified, by means of a constant overlap of the drain boring, while Structures, the piston of the hydraulic cylinder is equipped with a sub valve and supra plunger cavity the stop mounted in the sub-valve is connected to the pressure line and dies with the possibility of interaction between the hydraulic cavity of the hydraulic cylinder. 1271455d