BELLOWS ACCUMULATOR, IN PARTICULAR PULSATION DAMPER

Abstract

The invention relates to a bellows accumulator, in particular a pulsation damper, comprising a bellows (3), which, arranged in an accumulator housing (1), separates two media chambers (27, 28) from each other and the bellows folds (19) of which can be moved at least partially along the inner wall (35) of the accumulator housing (1). Said bellows accumulator is characterized in that the outside diameter of the bellows folds (19) is selected to be slightly smaller than the associable diameter of the inner wall (35) of the accumulator housing (1) in such a way that spaces (37, 41) are formed, which together form a hydraulic damping means for at least one medium.

Claims

1. A bellows accumulator, in particular a pulsation damper, comprising a bellows (3), which, arranged in an accumulator housing (1), separates two media chambers (27, 28) from each other, and the bellows folds (19) of which can be moved at least partially along the inner wall (35) of the accumulator housing (1), characterized in that the outer diameter of the bellows folds (19) is selected to be slightly smaller than the associable diameter of the inner wall (35) of the accumulator housing (1) in such a way that interspaces (37, 41) are formed, which together form a hydraulic damping means for at least one medium.

2. The bellows accumulator according to claim 1, characterized in that the size of the interspaces (37, 41) to achieve the hydraulic damping effect is chosen such that, under consideration of the medium in the gap (37), a sliding guide of the bellows folds (19) is achieved in the accumulator housing (1) in the gap between the outer diameter of the bellows (3) and the inner diameter (35) of the housing (1).

3. The bellows accumulator according to claim 1, characterized in that the sliding guide facilitates a movement of the bellows (3) parallel to the longitudinal axis of the accumulator housing (1) and impedes it in the direction transverse to the longitudinal axis.

4. The bellows accumulator according to claim 1, characterized in that the medium space (27) between the outside of the bellows and the associated inner wall (35) of the accumulator housing (1) contains a medium of high viscosity, such as a phosphoric acid ester oil (HFD-R), whereas the medium on the inside of the bellows (28) is a medium such as nitrogen gas.

5. The bellows accumulator according to claim 1, characterized in that the size of the gap (37), or the gap dimension respectively, is chosen to be between 3.0 mm and 0.15 mm, particularly preferred between 2.0 mm for a low hydraulic damping effect and 0.25 mm for an extremely high hydraulic damping effect.

6. The bellows accumulator according to claim 1, characterized in that the gap (37) between the sliding guide of a corresponding bellows fold (19) is transformed into damping spaces (41) at the assignable inner wall (35) of the accumulator housing (1) at least when the bellows (3) is extended, wherein said damping spaces (41) are delimited by two adjacently located bellows folds (19).

7. The bellows accumulator according to claim 1, characterized in that the height of the bellows (3) in its extended state may be one to one and a half times of its internal diameter.

8. The bellows accumulator according to claim 1, characterized in that the bellows (3) is made from a metallic material and/or that the ends of the folds have tapered cross-sections and/or that the bellows (3) does not require any additional guiding facilities in the vicinity of its sliding guide inside the accumulator housing (1).

9. The bellows accumulator according to claim 1, characterized in that the one end of the bellows is attached to a moveable end body (25), whereas the other end of the bellows (3) is secured to a retaining ring (21) that is fixed to the housing.

10. The bellows accumulator according to claim 1, characterized in that the moveable end body (25) closes off the inside (28) of the bellows (3) with respect to a medium connection (7) of the accumulator housing (1), is circular in shape and is provided with protruding guide members for making contact with inner wall parts (35) of the accumulator housing (1), where media passages extend between the guide members of the end body (25).

Description

[0014] Shown are in:

[0015] FIG. 1 a longitudinal cross-section of an exemplary embodiment of the bellows accumulator according to the invention, wherein the bellows is shown fully extended;

[0016] FIG. 2 an enlarged depiction of the section marked with II in FIG. 1; and

[0017] FIG. 3 a longitudinal cross-section of a further exemplary embodiment, also with fully extended bellows.

[0018] The invention is now explained with reference to the attached drawings by way of examples of pulsation dampers, which are particularly intended to reduce or dampen pressure spikes, which occur at high frequencies in the hydraulic fluid of the hydraulic system of an aircraft. FIG. 1 depicts with the reference number 1 as a whole the accumulator housing of an exemplary embodiment comprising a main housing part 2, which may contain the metallic bellows 3. The main housing part 2 is made in the form of a circular-cylindrical pot with a bottom 5, which is closed except for a centrally located fluid connection 7. At the opposite, upper end, as depicted in FIG. 1, the main part 2 is provided with an increased wall thickness 9, welded to the free end of which is a metallic housing end part 13 along the weld seam 11. Said housing end part 13 has the form of a domed cup, which is closed apart from a centrally located filling opening 15, which is closed by means of a weld nugget 17.

[0019] The metallic bellows 3 that is located inside the main part 2 is welded at its open bellows end, shown at the top in FIG. 1, with its last bellows fold 19 to a metallic retaining ring 21, which is provided with a thickened circumferential edge 23 with which it is secured to the accumulator housing 1 in such a manner that the thickened circumferential edge 23 overlaps the weld seam 11 between main part 2 and end part 13, wherein the welding method used is a full penetration welding process using electron-beam welding (laser welding) so that the circumferential edge 23 of the retaining ring 21 is also welded on. The opposite, lower end of the bellows 3 is closed by a metallic, plate-shaped bottom part 25 to which the lowest bellows fold 19 is welded.

[0020] FIG. 1 depicts the operational state in which the bellows 3 is fully extended and the oil end 27 is empty, wherein the associated fluid connection 7 is closed with a protective screw cap 29. When used in aeronautical engineering systems, the bellows 3 forms the moveable separation element between a viscous hydraulic fluid on the oil side 27, such as a phosphoric acid ester oil (HFD-R), which, as a low-flammability liquid, is permitted for aeronautical applications, and a process medium, such as a process gas, such as nitrogen gas, which is present on the gas side 28 of the accumulator housing 1 under a pre-filing pressure, wherein said gas side 28 is formed by the inner space of the bellows 3 as well as the housing part located above the retaining ring 21.

[0021] To facilitate the guidance of the axial movements of the bottom part 25, which changes the volume of the bellows, said bottom part 25 is guided by a guide ring 33 disposed on its circumferential edge 31 that is made from a synthetic material with good sliding properties, for example tetrafluoroethylene. In order to facilitate the passage of fluid from the oil side 27 that is adjacent to the fluid connection 7 to the outside of the bellows 3 despite the axial guide provided by the guide ring 33, so that also the area of the gap 37 between the outside of the bellows and the inner wall of the housing 35 is part of the oil side 27, the guide ring 33 has the shape of a flat ring that is formed in such a manner as is shown for a guide ring that fulfills a comparable function that is depicted in FIGS. 2 and 3 of the document WO 2011/079890 A1 and referenced with the number 47, cited above as prior art. In accordance with that the guide ring 33 is provided with circumferentially spaced, radially protruding guide sections that are in contact with the inner housing wall 35 and between which are radially recessed gaps that allow the fluid to pass through.

[0022] As is most clearly shown in FIG. 2, a gap 37 is provided between the inner wall 35 of the main part 2 of the accumulator housing 1 and the outer diameter of bellows 3 that is established by the tips of the bellows folds 19, wherein the width of said gap is indicated in FIG. 2 by the arrows 39. In conjunction with the interspaces 41, which are formed between its folds 19 by an at least not fully compressed bellows 3, the volumes of which change accordingly with the movement of the bellows in operation, damping spaces are formed between the outside of the bellows and the inner housing wall 35 as part of the oil side 27. As is apparent from FIG. 2, damping throttles are formed between the tips of the folds 19 and the inner housing wall 35 for the fluid flow that results from the volume changes of the fold interspaces 41 caused by the bellows movement in operation, wherein the chosen gap size determines the throttle cross-section. In addition to the pulsation damping effect due to the movement of the bellows against the pressure cushion of the process gas, a hydraulic damping effect is achieved on the outside of the bellows. For reasons of clarity the folds 19 and the interspaces 41 between the folds 19 are not all marked as such in FIGS. 1 and 2.

[0023] The size of the gap may be selected depending on the desired damping effect; for example a gap of 2.0 mm for a relatively low damping effect or 0.25 mm for a high damping effect. With such small gap sizes and a highly viscous medium on the oil side 27, such as phosphoric acid ester oil, a lubricating film is formed between the inner housing wall 35 and the outside of the bellows 3, wherein said lubricating film acts as axial guidance for the bellows folds 19 inside the housing 1 and provides protection for the folds 19 with respect to vibrational loads. The bellows accumulator according to the invention is thus particularly suitable as a damping device for fluids with high-frequency pressure spikes. The invention is also suitable for use in high-frequency pulsation applications because it is not necessary to attach an additional oscillating mass to bellows 3 for the guidance of the bellows folds 19, as it is necessary in the above-described, known solution which provides a sleeve on the bellows that surrounds the folds.

[0024] FIG. 3 depicts a modified exemplary embodiment in which the accumulator housing 1 is closed at the upper end of the circular-cylindrical main part 2 through a domed cover part 45 that is connected to main part 2. The lower end of main part 2 is closed along the weld seam 47 by a flat housing bottom 49, which corresponds to the bottom 5 of the first exemplary embodiment and which, in likewise manner, is provided with a central filling connection 7 for the hydraulic fluid. The metallic bellows 3 in this exemplary embodiment is open towards the bottom 49 so that the inside of the bellows 3 forms the oil side 27. The retaining ring 21, which is welded to the last bellows fold 19 at the open end of the bellows 3, is formed in this exemplary embodiment by a flat ring, which is fixed along the weld seam 47 to the lower end of the main housing part 2.

[0025] As in the first exemplary embodiment, the bottom part 25, which forms the closed end of the bellows 3 and which is welded to the last bellows fold 19 that faces it, is axially moveable. Again, as in the first exemplary embodiment, the bottom part 25 is fitted at the circumferential edge 31 with the guide ring 33 that is provided with passages so that the gap 37, which is formed, like in the first exemplary embodiment, between the inner housing wall 35 and the outside of the bellows 3 and which in FIG. 2 is indicated by the gap dimension 39, forms together with the interspaces 41 between the folds 19 damping spaces, with damping throttles formed between the tips of the folds 19 and the inner wall 35 for the flow of process gas when the bellows 3 moves, causing volume changes of the interspaces 41. As in the first exemplary embodiment, this causes on the outside of the bellows 3 an additional damping effect. As in FIGS. 1 and 2, the folds 19 and the interspaces 41 between the folds 19 shown in FIG. 3 are not all marked as such for reasons of clarity.