Hydrostatic Cylinder with Gas Pressure Accumulator

Abstract

A hydrostatic cylinder with a gas pressure accumulator, which is preferably designed as a piston accumulator, and which is arranged concentrically on the outer circumference of the cylinder is disclosed. A gas pressure is produced via a constant pressure source and is limited or is essentially constant in the gas pressure accumulator and also a constant pressure medium pressure is independent of the degree of filling of the gas pressure accumulator.

Claims

1. A cylinder assembly, comprising: a hydrostatic cylinder defining an outer circumference; and an annular gas pressure accumulator arranged on the outer circumference of the hydrostatic cylinder, wherein the annular gas pressure accumulator defines a gas chamber and a pressure medium chamber, wherein the annular gas pressure accumulator includes a resilient or movable separation element that is configured and arranged to separate the gas chamber from the pressure medium chamber, and wherein the gas chamber is configured to be connected to a constant pressure source.

2. The cylinder assembly as claimed in claim 1, wherein: the annular gas pressure accumulator is a low-pressure accumulator, and the pressure medium chamber has a low-pressure connection.

3. The cylinder assembly as claimed in claim 1, wherein the resilient or movable separation element is an annular piston.

4. The cylinder assembly as claimed in claim 1, wherein: the cylinder assembly has an intermediate pipe which is finely processed at both sides and which forms an outer wall of the hydrostatic cylinder and an inner wall of the annular gas pressure accumulator.

5. The cylinder assembly as claimed in claim 1, wherein: the annular gas pressure chamber includes an inlet and a non-return inlet valve, the inlet is configured to be connected to the constant pressure source, and the non-return inlet valve is arranged between the constant pressure source and the inlet.

6. The cylinder assembly as claimed in claim 1, wherein: the annular gas pressure chamber further includes (i) an outlet, and (ii) a non-return outlet valve connected to the outlet, and the non-return outlet valve is pretensioned by a spring.

7. The cylinder assembly as claimed in claim 6, wherein a force of the spring is configured to be adjustable.

8. The cylinder assembly as claimed in claim 1, further including a first cylinder flange and a second cylinder flange that are spaced apart from each other, wherein: the annular gas pressure accumulator is positioned between the first cylinder flange and the second cylinder flange.

9. The cylinder assembly as claimed in claim 8, wherein: the annular gas pressure accumulator is a low-pressure accumulator, the pressure medium chamber has a low-pressure connection, and the low-pressure connection is arranged or formed on the first cylinder flange.

10. The cylinder assembly as claimed in claim 9, wherein the annular gas pressure chamber includes an inlet and a non-return inlet valve, the inlet is configured to be connected to the constant pressure source, the non-return inlet valve is arranged between the constant pressure source and the inlet, and the inlet is arranged or formed on the second cylinder flange.

11. The cylinder assembly having a gas pressure accumulator as claimed in claim 10, wherein: the annular gas pressure chamber further includes (i) an outlet, and (ii) a non-return outlet valve connected to the outlet, the non-return outlet valve is pretensioned by a spring, and the outlet is also arranged or formed on the second cylinder flange.

12. The cylinder assembly of claim 5, wherein the non-return inlet valve is configured to close in the direction toward the constant pressure source.

13. The cylinder assembly of claim 6, wherein the non-return outlet valve is configured to close in the direction toward the outlet.

Description

[0020] With reference to the Figures, two embodiments of the invention will be described in detail. In the drawings:

[0021] FIG. 1 is a schematic longitudinal section of the cylinder according to the invention with a gas pressure accumulator according to a first embodiment, and

[0022] FIG. 2 is a longitudinal section of the cylinder according to the invention with a gas pressure accumulator according to a second embodiment.

[0023] FIG. 1 shows a cylinder 2 which is constructed as a differential cylinder. The cylinder 1 is formed by means of an intermediate pipe 2 on the inner circumference of which a piston 4 is displaceably guided. The piston 4 separates two working chambers 5 of the cylinder 1 from each other.

[0024] On the outer circumference of the intermediate pipe 2, a gas pressure accumulator 6 which is in the form of a piston accumulator is arranged concentrically with respect to the cylinder 1. It has an annular piston 8 which is displaceably guided between an outer circumference of the intermediate pipe 2 and an inner circumference of an outer pipe 10. Since the piston 4 is guided in a sealing and displaceable manner along the inner circumference of the intermediate pipe 2 and since the annular piston 8 is guided in a sealing and displaceable manner, on the one hand, along the outer circumference of the intermediate pipe 2 and, on the other hand, along the inner circumference of the outer pipe 10, the three mentioned circumferential faces are finely processed.

[0025] The annular piston 8 of the gas pressure accumulator 6 separates a gas chamber 12 from a pressure medium chamber 14. So that the gas pressure accumulator 6 always has or applies a pressure which is constant or constant within limits independently of the filling level in the pressure medium chamber 14 thereof, a constant pressure source 20 is connected to an inlet 16 of the gas chamber 12 via a non-return valve 18. The non-return valve 18 opens from the constant pressure source 20 to the inlet 16. When pressure medium from the pressure medium chamber 14 is discharged into the connected closed system (not illustrated) and the annular piston 8 moves (in FIG. 1 to the left) so that the volume of the gas chamber 12 increases, the constant pressure source 20 conveys additional gas into the gas chamber 12.

[0026] Also in order to achieve pressure relationships which are constant or constant within limits, there is connected to an outlet 22 of the gas chamber 12 a non-return valve 24 which is pretensioned by means of a spring and whose opening direction is directed from the outlet 22 to the environment. As a result of the spring, a degree of equivalent limit pressure (for example, 3 bar) in the gas chamber 12 must be exceeded before the non-return valve 24 opens and gas can flow away. This limit pressure can be adjusted by means of an adjustment apparatus of the spring and can also be adjusted later. If additional pressure medium is conveyed into the pressure medium chamber 14 and the annular piston 8 is moved (in FIG. 8 to the right) so that the volume of the gas chamber 12 decreases, therefore, gas can flow away via the outlet 22.

[0027] FIG. 2 shows a second embodiment of the combination according to the invention comprising the cylinder 1 and gas pressure accumulator 6 as a longitudinal section.

[0028] The following components and functions correspond to those of the first embodiment of FIG. 1: the cylinder 1 is a differential cylinder and is formed by means of the intermediate pipe 2 on the inner circumference of which the piston 4 is displaceably guided. The piston 4 separates the two working chambers 5 of the cylinder 1 from each other. On the outer circumference of the intermediate pipe 2, the gas pressure accumulator 6 which is constructed as a piston accumulator is arranged concentrically with respect to the cylinder 1. It has the annular piston 8 which is displaceably guided between an outer circumference of the intermediate pipe 2 and the inner circumference of the outer pipe 10. Since the piston 4 is guided along the inner circumference of the intermediate pipe 2 in a sealing and displaceable manner and since the annular piston 8 is further guided in a sealing and displaceable manner along, on the one hand, the outer circumference of the intermediate pipe 2 and, on the other hand, the inner circumference of the outer pipe 10, the three mentioned circumferential faces are finely processed. The annular piston 8 of the gas pressure accumulator 6 separates the gas chamber 12 from the pressure medium chamber 14. So that the gas pressure accumulator 6 always applies or has a pressure which is constant or constant within limits regardless of the filling level in the pressure medium chamber 14 thereof, a constant pressure source is connected to the inlet 16 of the gas chamber 12 via the non-return valve (both not illustrated in FIG. 2). The non-return valve opens from the constant pressure source to the inlet 16. When pressure medium from the pressure medium chamber 14 is discharged into the connected closed system and the annular piston 8 moves (in FIG. 2 to the left) so that the volume of the gas chamber 12 increases, the constant pressure source conveys additional gas into the gas chamber 12. Also in order to achieve pressure relationships which are constant or constant within limits, there is connected to the outlet 22 of the gas chamber 12 the non-return valve 24 which is pretensioned by means of the spring and whose opening direction is directed from the outlet 22 to the environment. As a result of the spring (not shown in FIG. 2), a degree of equivalent limit pressure in the gas chamber 12 must be exceeded before the non-return valve 24 opens and gas can flow away. This limit pressure can be adjusted by means of an adjustment apparatus (not shown in FIG. 2) of the spring and also be adjusted subsequently. If additional pressure medium is thus conveyed into the pressure medium chamber 14 and the annular piston 8 is moved (in FIG. 2 to the right) so that the volume of the gas chamber 12 decreases, gas can flow away via the outlet 22.

[0029] Additionally or alternatively to the first embodiment from FIG. 1, in the second embodiment according to FIG. 2 the following components and functions are provided:

[0030] A pressure-chamber-side cylinder flange 26 and a gas-chamber-side cylinder flange 28 can be seen and in each case internally close the corresponding end face of the cylinder 1 and in each case externally close the corresponding end face of the gas pressure accumulator 6. To this end, the intermediate pipe 2 and the outer pipe 10 are configured to be approximately of the same length. Consequently, the number of components with respect to the prior art is decreased.

[0031] The outlet 22 with the non-return valve 24 and the inlet are constructed or arranged at the gas-chamber-side cylinder flange 28. Two tank connections T are formed on the pressure-chamber-side cylinder flange 26.

[0032] Finally, a seal 30 on the outer circumference of the annular piston 8 and a seal 32 on the inner circumference of the annular piston 8 are illustrated.

[0033] Since the cylinder 1 is a differential cylinder, it has two working connections A, B (not shown). They are in each case arranged or formed on one of the cylinder flanges 26, 28.

[0034] There is disclosed a hydrostatic cylinder having a gas pressure accumulator which is preferably constructed as a piston accumulator and which is arranged concentrically on the outer circumference of the cylinder. Via a constant pressure source, a gas pressure which is constant within limits or substantially constant is produced in the gas pressure accumulator and consequently also a constant pressure medium pressure regardless of the filling level of the gas pressure accumulator.