SU1661725A1 - Hydraulic drive speed jet reversal stabilizer - Google Patents

Abstract

The invention relates to hydraulics. The device contains two pairs of coaxially located supply nozzle 18 (31) and made of the movable part 24 (37) and the fixed part 28 (41) of the receiving nozzle. The working agent (liquid) is fed alternately to one or the other of the feeding nozzles 18 and 31. When the fluid is supplied, part of the feeding nozzle 18 (31) and part 24 (37) of the receiving nozzle move in a coordinated manner towards the stationary part 28 (41) of the receiving nozzle. This reduces unproductive fluid losses. With the reverse movement of the moving parts, the resistance to reverse flow from the load is reduced. As a result, the efficiency of the device is increased. 4 il.

Description

The invention relates to the field of automatic control and can be applied in pneumatic automation systems.

The invention is an increase in efficiency by reducing unproductive fluid leakage and reducing the resistance of the receiving nozzle with a negative flow rate.

FIG. 1 shows a speed stabilizer; in fig. 2 shows a section A-A in FIG. in fig. 3 shows a section BB in FIG. in fig. 4 is a diagram of a speed stabilizer in the active state.

String reversible stabilizer speed of the hydraulic drive includes a housing 1, cylindrical channels 2 and 3, in which cylindrical bores 4-13 are made. In the cylindrical channel 3 there is a pusher 14 with windows 15-17, a feeding nozzle 18 with a cylindrical collar 19 and a conical output shank 20, a separator 21 with a radial partition with a central conical bore 22 and radial windows 23, a moving inlet part 24 of the receiving nozzle with a conical inlet the shank 25 and the cylindrical collar 26, the spring 27 and the fixed outlet 28 of the receiving nozzle with a cylindrical collar 29. In the cylindrical channel 2 are located the plunger 30, the feeding nozzle 31 with the cylindrical collar 32 and the horses Comic output shank 33, divider 34 with radial partition and central conical bore 35 and radial windows 36, movable input part 37 of the receiving nozzle with conical input shank 38 and cylindrical bead 39, spring 40 and fixed output part 41 of the receiving nozzle with cylindrical bead 42.

The jet reversible stabilizer of the hydraulic drive speed also contains solenoid valves 43 and 44 and a source 45 of pressure. The receiving nozzles are connected to the load by the consumer 4 The cylindrical bores 7 and 12 are connected to the drain port 47.

Jet reversible stabilizer speed of the hydraulic drive works as follows.

Let the signal be given to the solenoid valve 43. In this case, pressure is supplied to the end of the pusher 14, under

0

five

0

five

, 0

five

40

45

55

the action of which the pusher 14 moves downward (Fig. 4). Together with it, the feed nozzle I 18, the separator 21 and the movable part, 24 of the receiving nozzle, which is pressed against the fixed part 28 of the receiving nozzle, simultaneously move against the force of the spring 27. With the displacement of the feeding nozzle 18, the flange 19 opens the exit from the channel connected to the source 45 pressure. Fluid through rectangular holes in the pusher 14 enters the feed nozzle 18. It converts the potential energy of pressure into the kinetic energy of the jet. The jet, the passage through the conical opening 22 of the separator 21, enters the receiving nozzle 24. Here, the kinetic energy of the jet is converted back into potential energy of pressure. Since the diffuser of the receiving nozzle 24 is made with a taper angle of 0.1-0.2 rad and an expansion ratio of at least 60, this ensures the stabilization of the flow rate over a wide range of load pressure. The fluid drained from the consumer 46 of the hydraulic motor through the fixed part 41 of the receiving nozzle is drained into the bore 13 connected by a channel with the bore 6. Since the separator 21 has radial holes 23, it enters the cavity between the conical shank 20 of the feed nozzle and the separator 21. From here it is through the conical bore 22, it is ejected by a jet of liquid flowing from the feeding nozzle 18 and enters the moving part 24 of the receiving nozzle.

Claims (1)

Invention Formula The jet reversible stabilizer of the hydraulic drive speed contains a discharge channel, a housing in the first cylindrical channel of which a first pair of supply and receiving nozzles is located, the last of which is made in the form of a diffuser with a taper angle of 01702 radians and an expansion rate of at least 60, that, in order to increase efficiency by reducing unproductive fluid leaks and reducing the resistance of the receiving nozzle to reverse flow with a negative flow rate through it, electromagnetic lplany, formed in the housing a second cylindrical bore with a second pair of supply nozzles and the receiver, the supply nozzle of each pair is made movable, receiving the nozzle of each pair consists of a fixed and a movable INPUT OUTPUT There are five cylindrical bores in each cylindrical channel, each feeding nozzle contains a cylindrical bead and a conical output shank, the movable part of each receiving nozzle contains a conical input shank and a cylindrical bead, the stationary output part of the receiving nozzle also contains a cylindrical bead, in the first cylindrical bore Each cylindrical channel is equipped with a pusher that abuts against the cylindrical bead of the supplying nozzle, the end of which is adjacent to the cutting edge rastochTsi cylindrical minutes, the third and fourth cylinder bores between the cylindrical shoulders of the supply nozzle and the movable part of the table located soogny nozzles par- divider radial pe- regorodkoy provided with a central tapered bore smaller diameter facing towards the receiving nozzle, and radial windows reported The internal cavity of the separator with the third and fourth cylindrical bores, in the fifth cylindrical bore between the cylindrical flanges of the movable and fixed parts of the receiving nozzle is a spring, each first cylindrical bore is connected to a pressure source by means of a corresponding electromagnetic valve, both second cylindrical. The bores are connected directly to the pressure source, each third of the cylindrical bores are connected to a fifth cylindrical bore of another cylindrical channel, and both fourth cylindrical bores are connected to a drain channel. five Aa 2 Fig.Z Fig f