SU853109A1 - Hydraulic pulser - Google Patents

Description

5 in the working barrel 3. The piston 5 is in equilibrium, and the valve 6 is pressed to the seat 13 by the action of the velocity head. All water flows to the nozzle of the working barrel 3.

The start of the hydraulic pulse is made by turning the three-way valve 10 so that cavity A is connected to the discharge into the atmosphere, while the pressure drops sharply to zero there, the check valve 11 collapses and in the cavity B the pressure remains equal to the pressure in the impact pipeline. As a result, the piston 5 is displaced to the left (according to the drawing) against the flow, the valve 6 is pressed against the seat 14, the flow of water to the working barrel 3 is stopped, and at the same time the access of water from the impact pipe 1 to the channel of the waste barrel 4 opens.

The flow rate of water in the impact pipe 1 increases, and the pressure drops, since the outflow of fluid occurs through the waste barrel 4 with a nozzle with a larger flow area. When the three-way crane Yu returns to its original position (see drawing), the pressure in cavity A increases and equalizes with the pressure in cavity B, and the piston 5 under the action of the force of the velocity head sharply mixes in the direction of flow of the fluid.

When the valve 6 is pressed against the saddle 13, the channel of the waste barrel 4 is blocked and the flow rushes along the flow part of the piston 5 into the working barrel 3.

Since the working barrel 3 has nozzles of a smaller flow area, a sudden braking of the flow occurs. This causes a hydraulic shock, i.e., an abrupt increase in pressure in front of the nozzle of the working barrel 3. The increased pressure wave propagates from the nozzle of the working barrel 3 towards the surge generator 2 through the impact pipeline 1 and through the pipeline 7 in cavity A and B, and also in cavity G, pneumohydroaccumulator 8. Gas in cavity B is compressed through separation diaphragm 9 to a pressure equal to the pressure of water in cavity B. In case of discharge 2, surge wave attenuates and wave N extends towards working shaft 3 rmalnogo (supplied) pressure.

During the travel time of the overpressure wave to surge 2 and the reflected normal pressure wave from surge 2 to the nozzle of the working bore

3 there is an outflow of fluid under pressure. In this case, the valve 6 remains tightly pressed to the seat 13 by the force of the velocity head and the hydraulic friction of the flow in the channel of the piston 5. The water pressure during the action of the water hammer stably maintains its maximum calculated value. When a normal pressure wave reflected by the discharge 2 enters the control chamber A through the pipeline 7, the pressure drops there and the cavity B remains high, as the non-return valve I closes and water leaks are filled from the cavity G of the pneumohydroaccumulator 8. Under the action of the difference in pressure in the control cavities A and B, the piston 5 moves to the left towards the flow, and the valve 6, reaching the seat 14, blocks the access of water to the working shaft 3. In this position, the valve 6 will remain until B the water pressure will be higher than in cavity A. The duration of the piston retention

5 and the valve 6 in this position depends on the discharge time of the pneumohydroaccumulator 8 through the throttle 12 into the atmosphere and is regulated by the corresponding setting of the throttle 12. When the pressure in cavity B drops to such a value that the piston 5 with valve 6 moves again in the direction of flow, this will close the water access to the waste barrel 4 and open to the working barrel 3. Again

a water hammer will occur and the cycle will repeat.

Claims (2)

1. USSR Author's Certificate No. 237776, cl. E 21S 25/60, 1967. 2. USSR author's certificate jYo 244991, cl. E 21S 25/60, 1967. / .XX X Y4X4X V Y V t №