DE19906800A1 - Pressure fluid accumulator - Google Patents

Abstract

The invention relates to a pressure means storage device, comprising a housing (1), the inside of which is divided into two chambers (3, 4) by a media separation element (2). The first chamber (3) is filled with a gas and the second chamber (4) is filled with a liquid. A bottom valve (6) which allows the second chamber (4) to be filled with the liquid and prevents said second chamber (4) from being completely emptied is provided in a hydraulic connection (5), the closing body (7, 40) of said valve being activated by the media separation element (2). According to the invention, the closing body (7, 40) can be moved by means of the media separation element (2 or 16) into a position in which it performs the function of a hydraulic piston. This prevents the bottom valve from being damaged and any unwanted leakage of the liquid, hereby considerably increasing the functional reliability.

Description

The invention relates to a pressure medium accumulator with a Housing, the interior of which is separated by a media separation element is divided into two chambers, the first chamber with one Gas and the second chamber with a liquid pressure medium ge fills and a floor in a hydraulic connection valve is provided, the closing body through the media Separation element can be actuated and the filling of the two enables and a th chamber with the pressure medium prevents complete emptying of the second chamber.

Such a pressure medium reservoir is from the international patent application WO 98/37329 known. The Media separation element is in the known Pressure accumulator through a metallic bellows formed, with the hydraulic connection facing Face of the closing body of the bottom valve by means of is connected to a spring. To effectively shut off the hydraulic connection is the Closing body with a rubber-elastic sealing element Mistake.

Is less advantageous in the prior art Pressure fluid accumulator to see that when the Closing body on the floor closing gap from Pressure medium flows through, so that damage or Destruction of the sealing element and thus failure of the Pressure  medium storage threatens. The is also disadvantageous Perceived pressure medium leakage through a Expansion of the bellows caused by temperature fluctuations can be caused.

It is therefore an object of the present invention Pressure fluid accumulator of the type mentioned at the outset to improve that both damage to the Bottom valve as well as an unwanted pressure medium outlet is prevented and thus a significant increase in Functional reliability is guaranteed.

This object is achieved in that the Closing body through the media separation element in a Location is feasible in which it functions as a hydraulic piston satisfied. This is achieved that the closing body when the Bellows face to the bottom in the hydraulic Flow is introduced without obstructing it, and then, floating in the hydraulic flow to the system a stop to come, causing the hydraulic connection in the form of a locked hydraulic piston is closed.

To concretize the idea of the invention, that the closing body in a hydraulic connection provided bore is performed and with at least one Sealing element is provided against the wall of the Seals the bore. The bore is preferably as Stepped bore formed, the sealing element with the Smaller diameter section of the bore cooperates.  

Advantageous further developments of the subject matter of the invention are listed in subclaims 4 to 19.

The invention is described in the following description of four embodiments with reference to the enclosed drawing explained in more detail. In the drawing shows:

Fig. 1 shows a first embodiment of the accumulator according to the invention in axial section,

Fig. 2 the bottom valve used in the embodiment of FIG. 1 in the open standing in axial section to,

FIGS. 2a and 2b, the bottom valve of FIG. 2 in the transition state or in the closed state,

Fig. 3 shows a second embodiment of the accumulator according to the invention in axial section,

FIGS. 4a to 4c, the bottom 3 in the embodiment of valve used in the axial section in various stands to Fig., And

Fig. 5 shows a third embodiment of the bottom valve in axial section.

The first embodiment of the pressure medium reservoir according to the invention shown in FIG. 1 has a housing 1 , the interior of which is divided into two pressure spaces or chambers 3 , 4 by means of a media separation element 2 . The media separation element 2 is preferably formed by a thin-walled metallic bellows, which on the one hand is pressure-tightly connected to a cover 15 closing the housing 1 and on the other hand is closed by a plate 16 . The interior of the bellows 2 forms the first chamber 3 , which can be filled with a gas, which is generally under high pressure, via a filling connection (not shown) provided in the cover 15 . In the lower part of the housing 1 , a hydraulic connection 5 is formed, in which a bottom valve 6 is arranged, the closing body 7 of which projects into the second chamber 4 . The bottom valve 6 is preferably designed such that on the one hand it enables the second chamber 4 to be filled with a pressurized liquid pressure medium, for example a brake fluid, and on the other hand prevents the second chamber 4 from being completely emptied. In addition, there is a compression spring 17 in the first chamber 3 , which is clamped between the cover 15 and the previously mentioned plate 16 and thus prestresses the bellows 2 in the direction of the bottom valve 6 . This ensures that the hydraulic pressure prevailing in the second chamber 4 is always higher than the gas pressure prevailing in the first chamber 3 . In order to finally center the bellows 2 in the housing 1 , a slotted ring 18 is provided which engages around the bellows 2 and, in the assembled state, bears against the wall of the housing 1 .

As can be seen in particular from FIG. 2, the hydraulic connection 5 provided with a filling or outlet opening 13 has a bore 10 which is designed as a stepped bore and has a first section 11 of larger diameter and a second section 12 of smaller diameter. The transition region between the two sections 11 , 12 is preferably formed by a conical ring surface 9 . The previously mentioned closing body 7 is guided in the stepped bore 10 or 11 , 12 , a collar 19 provided with at least one passage 20 being provided for guidance in the first bore section 11 , while a second collar 21 is used for guiding in the second bore section 12 has a plurality of radial flow channels 22 . The flow channels 22 together with the passage 20 mentioned above form a flow connection between the second chamber 4 and the filling or outlet opening 13 of the hydraulic connection 5 . An end face of the second collar 21 facing away from the filling or outlet opening 13 forms a flank of a radial groove 23 which receives a sealing element 8 , which in the example shown is formed by a sealing collar. In the open state of the bottom valve 6 shown in FIG. 2, the first collar 19 rests against a stop 24 under the pretension of a compression spring 14 .

The bottom valve 6 is closed in two phases, which are shown in FIGS. 2a and 2b. Shortly before the chamber 4 is emptied, the plate 16 closing the bellows 2 begins to touch the preferably hemispherical end of the closing body 7 . When the pressure medium continues to escape, the closing body 7 is adjusted against the force exerted by the compression spring 14 or pressed down in the drawing until the outer sealing lip of the sealing sleeve 8 comes into contact with the conical annular surface 13 and thus prevents the flow around the closing body 7 . At this moment, the closing body 7 begins to perform the function of a hydraulic piston and is adjusted further downward by the residual pressure prevailing in the chamber 4 . As a result, the sealing element 8 is brought into the bore section 12 , the diameter of which no longer changes. In the previously considered processes, only small pressure differences can occur on the sealing collar 8 , which correspond to the spring, friction and inertial forces acting on the closing body 7 . This situation changes as soon as the closing body 7 has reached its lower stop and is supported on the housing 1 with any force. Due to the large pressure differences then to be held by the sealing collar 8 , the sealing collar 8 is statically loaded with an optimally small and, above all, constant metallic sealing gap. The state just described in which the sealing element 8 fulfills the function of a check valve opening towards the second chamber 4 is shown in FIG. 2b.

The bottom valve 6 is opened in that liquid pressure medium is pumped from the outside into the pressure medium reservoir 1 according to the invention. If the boost pressure exceeds the residual pressure or internal pressure prevailing in the chamber 4 , the outer sealing lip of the sealing collar 8 folds over and allows pressure medium to flow in via the sealing gap delimited by the wall of the bore section 12 , the compression spring 14 simultaneously pushing the closing body 7 back. As a result, the sealing sleeve 8 or its outer sealing lip detaches from the bore wall and clears the way for the inflowing pressure medium. As with closing, the contour of the annular space receiving the sealing collar 8 changes only when the pressure difference applied to the sealing collar is small. The closing body 7 is pressed further upwards by the compression spring 14 until it rests against the plate 16 closing the bellows 2 . When the chamber 4 is filled further, the plate 16 withdraws and the path of the closing body 7 is limited by the upper stop 24 .

In the second embodiment of the subject matter of the invention shown in FIG. 3, a sensor device 30 for sensing the movement of the media separation element 2 is provided in the gas-filled chamber 3 . The sensor device 30 , which is preferably designed as an inductive displacement sensor, represents an independently manageable assembly that can be inserted into an opening provided in the cover 15 . It has a two-part sensor housing 31 , in which essentially a coil 32 and a metallic pin 33 cooperating with the coil 32 are arranged. The two-part sensor housing 31 preferably consists of telescoping housing parts 34 , 35 , the part 34 facing the opening in the cover 15 receiving the coil 32 , while the second housing part 35, which partially encompasses the first housing part 34 , under pressure from a compression spring 36 the plate 16 supports. On the side of the second housing part 35 facing away from the plate 16 , the aforementioned pin 33 is fastened, which is guided in the first housing part 34 and partially projects into a cylindrical space 37 formed within the coil 32 . Electrical connections of the sensor device 30 are formed by the contact pins 38 protruding from the sensor housing 31 . With the aid of evaluation electronics (not shown) connected to the electrical connections, the inductance of the coil 32 can be determined, which changes as a function of the immersion depth of the metallic pin 33 in the cylindrical space 37 surrounded by the coil 32 . From the measured inductance, the position of the plate 16 and therefrom the filling state of the pressure medium reservoir according to the invention are determined with the aid of characteristic curves stored in the evaluation electronics. Within the scope of the inventive concept, electrical measuring means (not shown) can also be provided, which in addition serve to measure the inductance, measure the electrical resistance of the coil 32 and whose measurement variable is used to determine the storage temperature.

In Fig. 3, a modified embodiment of the bottom valve 6 is shown, the closing body 40 is provided with two consecutively arranged sealing elements 41, 42, to reduce the probability of failure.

As shown particularly in FIGS. 4a to 4c, which represent the various phases of the closing process, it can be seen effect the sealing elements again designed as sealing collars 41, 42 with two separate sections 43, designated 44 a formed in the hydraulic connection 5, unspecified, multiply stepped bore together. The closing paths of the two sealing elements 41 , 42 are preferably designed such that the sealing elements 41 , 42 come into abutment with the associated bore sections 43 , 44 at different times. As is particularly evident from FIG. 4b, when the closing body 40 is moved through the aforementioned plate 16, the outer sealing lip of the first sealing sleeve 41 comes into contact first with a first conical ring surface 45 , to which the associated bore section 43 connects. The second sealing sleeve 42 is still at a distance from an associated second conical ring surface 46 , so that the first sealing sleeve 41 is acted upon by the pressure medium flowing through a flow channel 47 formed in the hydraulic connection 5 , by the action of which the closing body 40 continues in the direction of the lower stop is moved. During the mentioned closing movement, the second sealing collar 42 first comes into contact with the conical ring surface 46 assigned to it, in order finally to seal against the assigned bore section 44 in the closed position ( FIG. 4c).

In a third embodiment of the bottom valve shown in FIG. 5, flow cross sections 27 are formed in a preferably cylindrical guide part 26 , which are delimited on the outside by a sleeve 25 forming the aforementioned closing body. In the direction of actuation of the bottom valve behind the flow cross sections 27 there is a sealing sleeve 28 which, after it has been run over by the sleeve 25 , seals against it, so that flow of the pressure medium is no longer possible.

In summary it can be said that all of the above Descriptions of the bottom valve described simply to design and just as easy and inexpensive are to be produced. The bottom valves can be used as Prefabricated, tested modules in metal bellows hydraulic accumulators to be built in. The sealing elements or sleeves are only pressurized in situations where the sealing gap has taken on its final contour and no longer changes. Through this operating principle will damage the sealing elements by shearing of parts of the sealing elements on metallic edges  locked out. Another advantage is that in addition to the open state, the closed state of the Bottom valve is mechanically stable. This has the consequence that transitions caused by thermal expansion an open and a closed state of the Bottom valve are excluded. In particular, at Store the pressure fluid reservoir if the from the outside applied pressure is zero, no liquid emerge.

Claims (19)

1. Pressure medium accumulator with a housing ( 1 ), the interior of which is divided into two chambers ( 3 , 4 ) by a media separation element ( 2 ), the first chamber ( 3 ) being filled with a gas and the second chamber ( 4 ) being filled with a liquid and in a hydraulic connection ( 5 ) a bottom valve ( 6 ) is provided, the closing body ( 7 , 40 ) of which can be actuated by the media separating element ( 2 ) and which enables the second chamber ( 4 ) to be filled with liquid and completely emptied of the second chamber ( 4 ), characterized in that the closing body ( 7 , 40 ) can be brought into a position by the media separation element ( 2 or 16 ) in which it fulfills the function of a hydraulic piston. 2. Pressure fluid accumulator according to claim 1, characterized in that the closing body ( 7 , -) is guided in a bore ( 10 ) provided in the hydraulic connection ( 5 ) and is provided with at least one sealing element ( 8 , 41 , 42 ) which is against seals the wall of the bore ( 10 , -). 3. Pressure fluid accumulator according to claim 2, characterized in that the bore ( 10 ) is designed as a stepped bore, the sealing element ( 8 ) cooperating with the section ( 12 ) of smaller diameter of the bore ( 10 ). 4. Pressure fluid accumulator according to claim 3, characterized in that a conical annular surface ( 9 ) is provided between the section ( 11 ) of larger diameter and the section ( 12 ) of smaller diameter of the bore ( 10 ). 5. Pressure fluid accumulator according to claim 4, characterized in that the closing body ( 7 ) by the media separation element ( 2 or 16 ) can be brought into a position in which the sealing element ( 8 ) comes to rest on the conical annular surface ( 9 ). 6. Pressure fluid accumulator according to claim 1, characterized in that the closing body is formed by a sleeve ( 25 ) which radially limits flow cross sections ( 27 ) formed in a cylindrical guide part ( 26 ) and cooperates with a sealing element ( 28 ). 7. Pressure medium accumulator according to one of claims 1 to 6, characterized in that the closing body ( 7 , 40 , 25 ) is biased against the actuating direction of the bottom valve ( 6 ) by means of a spring ( 14 ). 8. Pressure fluid accumulator according to one of claims 2 to 7, characterized in that the sealing element ( 8 , 41 , 42 , 28 ) is designed as a check valve closing towards the second chamber ( 4 ) in the actuated state of the bottom valve ( 6 ). 9. Pressure fluid accumulator according to claim 8, characterized in that the sealing element ( 8 , 41 , 42 , 28 ) is formed by a sealing sleeve. 10. Pressure fluid accumulator according to one of claims 2 to 5, and 7 to 9, characterized in that the closing body ( 40 ) has two sealing elements ( 41 , 42 ) arranged one behind the other in the actuating direction, which have two separate sections ( 45 , 43 ; 46 , 44 ) of the bore cooperate. 11. Pressure fluid accumulator according to one of the preceding claims, characterized in that the media separation element ( 2 ) is formed by a metallic bellows. 12. Pressure fluid accumulator according to one of the preceding claims, characterized in that a media separating element ( 2 ) in the direction of the bottom valve ( 6 ) to be preloaded elastic part (compression spring ( 17 )) is provided. 13. Pressure medium accumulator according to one of the preceding claims, characterized in that guide means ( 18 ) for centering the media separation element ( 2 ) in the housing ( 1 ) are provided. 14. Pressure fluid accumulator according to one of the preceding claims, characterized in that a sensor device ( 30 ) is provided for sensing its hydraulic filling state. 15. Pressure medium accumulator according to claim 14, characterized in that the sensor device ( 30 ) is designed as an inductive displacement sensor which has a coil ( 32 ). 16. Pressure medium store according to claim 15, characterized in that the inductance of the coil ( 32 ) is determined in an evaluation electronics associated with the pressure medium store. 17. Pressure fluid accumulator according to claim 16, characterized in that the fill level of the pressure medium accumulator is determined in an evaluation electronics associated with the pressure medium accumulator with the aid of characteristics stored in the evaluation electronics from the inductance of the coil ( 32 ). 18. Pressure medium store according to claim 15, characterized in that the direct current resistance of the coil ( 32 ) is determined in an evaluation electronics associated with the pressure medium store. 19. Pressure medium accumulator according to claim 18, characterized in that the temperature in the pressure medium accumulator is ascertained in a characteristic curve stored in the evaluation medium associated with the pressure medium accumulator from the direct current resistance of the coil ( 32 ).