DE2913423A1 - Fluid pressure resilient accumulator - has damper spring acting against member in addition to main one above predetermined pressure - Google Patents

Abstract

The fluid pressure accumulator has a resilient accumulator member, subjected to the pressure of the fluid and of a spring on opposite sides. Above a predetermined fluid pressure, the member (2) is subjected to pressure from one or more damper springs (14) in addition to the main spring (8). Above the pressure concerned, the member can be arranged to bear against a damper spring plate (13), against which the damper spring acts. Damper and main springs can be mounted in series, the main spring being softer.

Description

Fluid pressure accumulator

PRIOR ART The invention is based on a fluid pressure accumulator according to the genre of the main claim. A fluid pressure accumulator is already known, its resilient storage member above a predetermined fluid pressure at one Stop is applied, so that pressure oscillations originating from a pump that occur in the Lines of the fluid system in which the fluid pressure accumulator is integrated and in associated units lead to annoying noises, since in this state the known fluid pressure accumulator can no longer dampen the pressure oscillations. The well-known Fluid pressure accumulators are used, for example, in fuel injection systems of the invention The fluid pressure accumulator according to the invention with the characterizing features the main claim has the advantage that in a fluid pressure system with a fluid pressure accumulator is given the opportunity to cheap Way without additional space requirement for an attenuator in the fluid pressure system to train the fluid pressure accumulator so that it over the entire pressure range of the Fluid also serves to dampen pressure oscillations at the same time.

The measures listed in the subclaims are advantageous Developments and improvements of the fluid pressure accumulator specified in the main claim possible.

DRAWING Four exemplary embodiments of the invention are shown in the drawing shown in simplified form and explained in more detail in the following description. It FIG. 1 shows a first exemplary embodiment of a fluid pressure accumulator, FIG. 2 a second embodiment of a fluid pressure accumulator, Figure 3 a third embodiment a fluid pressure accumulator, Figure 4 shows a fourth embodiment of a fluid pressure accumulator.

Description of the exemplary embodiments The one shown in FIG Fluid pressure accumulator 1 has as a resilient storage member a membrane 2, which between an upper housing half 3 and a lower housing half 4 in a flange 5 is clamped. The membrane 2 separates a storage space 6 in the upper half of the housing 3 from a spring chamber 7 in the lower housing half 4.

A storage spring 8 is also located in the lower housing half 4 arranged, the other hand via a storage spring plate 9 at the membrane 2 attacks. Overflows from the fluid pressure system (not shown) an inlet conduit 11 introduces liquid, e.g., fuel, into the storage space 6 and presses the membrane 2 against the force of the accumulator spring 8 into the spring chamber 7. The storage space 6 is also connected to the fluid pressure system through an outlet line 12 tied together. If the pressure of the liquid in the storage space 6 reaches a certain value Value, the membrane m 2 is bent out so far into the spring chamber 7 that the storage spring plate 9 rests against a damper spring plate 13, on the other hand a damper spring 14 supports. Now occur pressure oscillations in the fluid pressure system, for example by a feed pump, these are dampened by the fact that the movement of the Diaphragm 2 into the spring chamber 7 now still against the force of the damper spring 14 must be done. A limitation of the stroke of the storage spring plate 9 can, for example be done in that a stop edge 15 of the Speicherfe- -dertellers 9 on one Paragraph 16 of the lower housing half 4 or the storage spring plate 9 on a guide sleeve 17 of the damper spring plate 13 comes to rest. The movement of the membrane 2 in the Storage space 6 inside can be limited by a stop plate 18.

In the fluid pressure accumulator according to the second embodiment according to Figure 2 are the same as compared to the embodiment of Figure 1 Parts are identified by the same reference numerals. The second embodiment according to FIG. 2 differs from the first exemplary embodiment according to FIG. 1 in that the accumulator spring 8 and the damper spring 14 are arranged in series are and the accumulator spring 8 is made softer, i.e. a smaller spring constant has, as the damper spring 14. This storage spring 8 and damper spring 14 can be made two separate springs can be combined to form a single spring, or the accumulator spring 8 and the damper spring 14 can represent partial spring areas of an overall spring.

In the present embodiment, the damper spring is 1L, for example frustoconical.

The membrane 2 and thus is above a predetermined fluid pressure the storage spring plate 9 so far into the spring space 7 that the coils the storage spring 8 lie on top of one another and the harder damper spring 14 now continues the damping of pressure oscillations in the storage space 6 takes over.

The third embodiment of Figure 3 differs from aem second A.us Ausführungsbeispiel according to Figure 2 in its design only in that the damper spring 1 @ is cylindrical.

Also in the fourth embodiment of Figure 4 were for parts that remain the same as in the previous exemplary embodiments are the same Reference numerals used. In Figure 4, a fluid pressure accumulator 1 is shown, in which Storage spring plate 9 a recess 20 is provided in which the damper spring 14 supports. On the other hand, the damper spring 14 acts via the also in the recess 20 guided damper spring plate 13 on the membrane 2. Is now a predetermined Fluid pressure of the storage spring plate 9 with its stop edge í5 on the shoulder 16 of the spring chamber 7, so can cause further pressure fluctuations in the liquid amount from the membrane 2 to the damper spring plate 13 and through the damper spring 14 can be taken up and dismantled.

The fluid pressure accumulators according to the invention are particularly suitable in a fuel injection system for internal combustion engines pressure fluctuations dampen and thus avoid disturbing noises.

Fluid pressure accumulator Summary It will be a fluid pressure accumulator proposed the maintenance of certain pressure conditions in a fluid pressure system and serves to dampen pressure vibrations to avoid disturbing noises. The fluid pressure reservoir (1) comprises a membrane serving as a flexible storage element (2), which can be acted upon on the one hand by the fluid and on the other hand by a storage spring (8) is.

The membrane (2) is also above a certain fluid pressure acted upon by a damper spring (14).

L e r s e i t e

Claims (1)

Claims 1. fluid pressure accumulator with a resilient storage member, which can be acted upon on the one hand by the fluid and on the other hand by a Speinher spring is, characterized in that the resilient storage element (2) above a certain fluid pressure in addition to the storage spring (8) against the fluid pressure force can be acted upon by at least one damper spring 14) 2. fluid pressure accumulator according to claim 1, characterized in that the resilient storage element (2) is above the predetermined fluid pressure is pressed against a damper spring plate (13), on which the damper spring (14) is supported. 3. ~ u-atr-back memory according to claim 1, characterized in that Storage spring (8) and damper spring (14) are arranged in series and the storage spring (8) is made softer5 than the damper spring (14). 4. Fluid pressure accumulator according to claim 3, characterized gekennzelchret that Storage spring (8) and damper spring (14) are cylindrical. 5. fluid pressure accumulator according to claim 3, characterized in that the accumulator spring (8) is cylindrical and the damper spring (14) is frustoconical is. 6. Fluid pressure accumulator according to one of claims 3, 4 or 5, characterized characterized in that the storage spring (8) and damper spring (14) are partial areas of an overall spring are. 7. Fluid pressure accumulator according to one of the preceding claims, characterized characterized in that a membrane (2) is used as the resilient storage element (2). 8. fluid pressure accumulator according to claim 1, characterized in that a membrane (2) is used as a flexible storage element (2), to which a storage spring plate (9) engages the accumulator spring (8) and the accumulator spring plate (9) above the predetermined fluid pressure is applied to a stop (16) and a recess (20) has, in which the damper spring (14) is arranged, which extends over a Dampferfederkeller (13) is supported on the membrane (2).