CS257364B1 - Distribution of a piston hydrostatic converter - Google Patents

Abstract

The distribution of the piston hydrostatic converter allows for an equally long period of increase and decrease in pressure above the piston when transitioning to a different pressure level between the input and output lines. The distribution consists of a fixed bottom plate on which a fixed link is placed, in which a first wedge-shaped groove provided with a first damping groove and a second wedge-shaped groove provided with a second damping groove are formed. Behind the first damping groove, a first movable segment is located in the wedge-shaped groove, slidably mounted in a fixed bottom plate, in which a second movable segment is also slidably mounted, located in a second wedge-shaped groove behind the second damping groove. The essence of the solution is that the lower front surface of the first and second movable segments is located in a recess formed in the fixed bottom plate and connected to an auxiliary pressure source.

Description

The invention relates to a design of a manifold of a piston hydrostatic transducer arranged so as to allow an equally long rise and fall time of the pressure over the piston when changing to a different pressure level between the inlet and outlet lines.

In previously used piston hydrostatic transducer manifolds operating as a flow reversible control pump, the control of the rise and fall time over the piston is accomplished by means of movable segments located in the ladder grooves behind the damping grooves and controlled by the pressure from the opposite 1 'twin groove. The disadvantage of such a solution is that the force effect caused by the pressure of the working liquid on the lower face of the movable segment adversely affects the balance of the distribution in the plane of contact of the fixed lower thatch and the stationary backdrop. A solution is also known in which the movable segment is controlled by the pressure of a spring mounted in a recess formed below the bottom face of the segment and connected to the housing of the converter. The disadvantage of such an embodiment is a constant spring pressure, which does not allow full consideration of the operating mode parameters of the converter.

These drawbacks are eliminated by a piston hydrostatic transducer distribution consisting of a fixed lower that is supported by a stationary backing, in which a first ladder-shaped groove is provided with a first damping groove and a second ladder-shaped groove is provided with a second damping groove in the first thrust groove. The first movable segment is displaceably disposed in a fixed bottom plate in which a second movable segment is displaceably mounted in a second tunnel groove after the second cushioning groove according to the invention, characterized in that the lower face of the first and second movable segments is displaceable. The segment is located in a recess formed in the fixed bottom plate and connected to an auxiliary pressure source. The lower face of the first and second movable segments is larger than their upper face interconnected with the transducer plane. The recess is connected to the auxiliary pressure source via the orifice plate.

The advantage of such a distribution system is that the movable segment, which is controlled by the pressure of the auxiliary source, allows to prolong the pressure drop time over the piston up to the value of pressure rise time, taking into account the operating mode parameters of the converter. contact of the stationary backdrop and the fixed bottom thatch. Due to the prolonged pressure drop time, the amplitude of the tipping moment of the tipping moment decreases from the pressure acting on the pivoted thatch of the reversing flow pumps. There is also a decrease in the amplitudes of the harmonic components of the driving force, and thus the radiated sound power is reduced in comparison with a distribution system with a short pressure drop time.

In the accompanying drawings, an exemplary embodiment of a piston hydrostatic transducer assembly according to the invention is shown. 1 is a view of a stationary distribution plane formed by a stationary backdrop, and FIG. 2 shows section A-A of FIG. First

The distribution of the piston hydrostatic transducer, which functions as a hydrogelator with flow reversing, consists of a fixed lower thatch 4 on which the stationary sliding plate 1 is laid. In the stationary sliding plate 1 a first ladder-shaped groove 2 is provided with a first damping groove 5 3, provided with a second damping groove 6. In the first 1'-groove 2, a first movable segment 7 is located after the first damping groove 5, and a second movable segment 8 is located behind the second damping groove 6, the first as well as the second the movable segment 7, 8, with its lower face 9, is located in a recess 11 connected via a guide 12 and an orifice 16 to an auxiliary pressure source 13. As an auxiliary pressure source 13, e.g. a pressure source designed to control the geometric volume of the converter. The first and second movable segments 7, 8 are formed such that the lower face 9 is larger than the upper face 10, their upper and lower positions being defined by the difference in the length of the recess 11 and the length of the lower cylindrical portion terminated by the lower face 9.

As the undrawn piston block rotates in the direction of the arrow 14 indicated in FIG. 1, occurs under high inlet pressure e.g. in the second 1'-twin groove 3 provided to the upper face 10 of the second movable segment 8 to move the segment to the lower limit position. As a result of this displacement, the pressure rise time over the piston at the top dead center is controlled only by the second damping groove 8. In the first 1 ' twin groove 2, the first movable segment 7 is in the uppermost position. In this position, the upper face 10 of the first movable segment 7 acts as an obstacle to the flow of liquid from the space above the piston, thereby increasing the pressure drop time over the piston at the bottom dead center. The pressure drop time is greater, the smaller the height difference between the manifold plane 15 and the top face 10. The orifice 16 serves to damp the movement of the first and second movable segments 7, 8.

Claims (3)

A piston-type hydrostatic transducer manifold comprising a fixed bottom that has a stationary backdrop in which a first twin-groove groove is provided with a first damping groove and a second twin-groove groove is provided with a second damping groove, with the first damping groove in the first damping groove. a first movable segment displaceably mounted in a fixed bottom plate in which the second movable segment is displaceably disposed in the second twin-groove after the second cushioning groove, SUMMARY OF THE INVENTION that the lower face (9) of the first and second movable segments (7, 8) is disposed in a recess (11) formed in a fixed lower plate (4) and connected to an auxiliary pressure source (13). Distribution according to Claim 1, characterized in that the lower end face (9) of the first and second movable segments (7, 8) is heavier than their upper end face (10) connected to the transducer plane of the converter. Distribution according to Claim 1, characterized in that the recess (11) is connected to the auxiliary pressure source (13) via an orifice (16).