CS254931B1 - Distribution of a sand hydrostatic converter - Google Patents

Abstract

The solution concerns a distribution of a piston hydrostatic converter with an even number of pistons, which is arranged in such a way as to enable a rapid change in pressure above the piston when transitioning to a different pressure level between the input and output lines. The distribution consists of a fixed link, in which the first and second kidney-shaped grooves are formed, as well as a movable link, in which the space above each piston is terminated by a third kidney-shaped groove located in the distribution plane. The essence of the solution is that the input and output sides of the kidney-shaped grooves are perpendicular to the longitudinal sides of these grooves. The radius of curvature of the input and output sides with the longitudinal sides is less than half the width of the kidney-shaped groove.

Description

The present invention provides an even number of piston hydrostatic transducer manifolds configured to allow rapid pressure change over the piston when changing to a different pressure level between the inlet and outlet conduits.

In the piston hydrostatic transducer systems used so far, the rise and fall of the pressure over the piston is controlled by means of dimming grooves located on the inlet sides of the twin-groove grooves of the stationary link. In terms of reducing the radiated acoustic power, satisfactory results are obtained at low rates of pressure rise and fall, often at the expense of flow efficiency. However, in so far ¹ used transducers with an odd number of pistons can not be removed from the physical principle of alternating course budiaccj force from the piston when the driving force is defined as the sum of the instantaneous power of the individual pistons.

This drawback removes the even piston hydrostatic transducer manifold distribution consisting of a fixed link, in which a first and a second ladder-like groove is formed as well as a movable one, in which the space above each piston is terminated by a hit ladder-like groove located in the manifold plane. the essence is that the inlet and outlet sides of the first and third twin grooves are perpendicular to the longitudinal sides. The inlet and outlet sides of the second groove are also perpendicular to the longitudinal sides. In an alternative embodiment, the inlet side of the second ladder groove coupled to the damping groove is formed. that with the longitudinal sides, the animal has an angle other than 90 °. The radii of curvature of the inlet and outlet slopes with the longitudinal sides are less than half the width of the respective ladder groove.

An advantage of an even piston hydrostatic transducer manifold distribution is that it allows very rapid pressure build-up and drop, resulting in a reduction in radiated sound power levels as a result of a decrease in the amplitudes of the driving force harmonics compared to a manifold with slower build-up and pressure drop.

The accompanying drawings show an exemplary embodiment of a manifold of a piston hydrostatic transducer according to the invention. 1 shows a distribution with the piston position at the bottom dead center shown; FIG. 2 shows a detail of an embodiment of a ladder groove, FIG. 3 shows the slide P on the slide surface of the stationary backdrop and in FIG. 4 caress the sine rom A on the sliding surface of the moving backdrop.

The flow of the piston hydrostatic conduit operating in the function of a reversible flow generator consists of a fixed gate 4 in which the first and second ladder grooves 5, 6 are formed, as well as a movable gate 8 in which the space above each piston 11 is terminated The number of third grooves 7 is similar to the number of pistons 11 even. The first, second and third tunnel grooves 5, G, 7 are designed such that the light inlet side 1 and the outlet side 2 are perpendicular to the longitudinal sides 3. In the case that the manifold is to be used for the pump without reversing the flow, 1 of the second ladder groove 6 is provided with a damping groove or an inlet side 1 that is not perpendicular to the longitudinal sides 3, thereby practically replacing the damping groove 10. When the movable link 8 rotates in the direction indicated by the arrow 9, the inlet sides 1 secure the first and third ladder grooves. 5 and 7, a rapid pressure rise over the piston 11, wherein the inlet sides 1 of the second and third ladder grooves B and 7 provide a rapid pressure drop over the piston 11. The pressure rise and drop rates are proportional to the length of the inlet side 1 and with a minimum radius of curvature of 12 of contact side 1 and lateral side 3 the pistons having an even oscillation at such a rapid build-up and pressure drop. Theoretically, the pressure changes, respectively. at the same rate of rise and fall of pressure over the dead center pistons 11, the excitation force imparting to the transducer body is constant, which means that it does not generate sound power.

Claims (5)

1. An even piston hydrostatic transducer manifold distribution comprising a fixed link in which a first and a second ladder-like groove is formed as well as a movable blade in which the space above each piston is terminated by a hit by a ladder-like groove located in the distribution plane; that the inlet sides (1) and the outlet sides (2) of the first I-24 grooves (5) and the third F-24 grooves (7) are perpendicular to the longitudinal sides (3). Distribution according to Claim 1, characterized in that the inlet side (1) and the outlet side (2) of the second ladder groove (6) are perpendicular to the longitudinal sides (3). Distribution according to items 1 and 2, characterized in that the inlet side (1) of the second 1 'twin groove (6) is connected to the damping groove (10). Distribution according to Claim 1, characterized in that the inlet side (1) of the second F-groove (6) is at an angle other than 90 ° to the longitudinal sides (3). 234931 5 6 5. The distribution according to items 1 and 2 characterized by the sides (3) is smaller than a half, in that the radius of curvature (12) of the input widths of the respective F-groove, the slopes (1) and the exit slopes (2) is longitudinal.