DE1014401B - Outlet valve for a pressure accumulator - Google Patents

Description

GERMAN

BI3U0THEK

DESO-GERMAN PATENT OFFICE

The invention relates to an outlet valve for a pressure accumulator with a rigid housing and a movable partition, which is resilient against the pressure at the end of the emptying of the memory Means presses the closure piece of the exhaust valve in its final position.

Usually such accumulators take oil and compressed air. If through the outlet opening of the Pressure accumulator is pressed in on one side of the partition wall oil, this oil moves the partition wall and compresses the already pre-tensioned air on the other side of the partition wall even more. If the pressure of the accumulator is to be used, the shut-off valve between the outlet is opened and a device to be operated is turned on; the partition then moves again under the pressure of the air and presses the oil out of the reservoir through the outlet valve.

If the oil contained in the memory is to be fully utilized, the outlet valve must be open stay until all the oil has left the reservoir. On the other hand, it has to close quickly and tightly, if the oil supply is exhausted; this is particularly true in the event that the partition is soft and elastic, so that it could be pinched in the outlet opening.

Attempts have already been made to keep the exhaust valve open as long as possible by having a relatively strong spring was arranged, which the pressure on the closing member of the valve Should keep balance. But this again creates the risk that the valve will still remain open, when the pressure accumulator is already essentially empty, and that a soft partition wall from the closure piece pinched and damaged.

If, in order to avoid this, a relatively weak spring is arranged, the valve will open immediately close when it is touched by the partition. A considerable amount of the oil remains in the process Memory back. In addition, there is a risk that when removing a large amount of liquid in a short time, as it z. B. may be necessary for hydraulic braking, the outflowing oil a low Pressure generated under the closure piece, while there is a high pressure in the memory. The proportionate weak spring cannot compensate for this pressure difference on the closure piece, and the latter closes almost immediately after the outflow begins. But this can be used to operate Device can no longer be moved.

It has also been proposed to arrange a flexible disc at the container outlet, the Edge of the expanding partition is placed sealingly on the edge of the outlet. To do this you have to Outlet valve for a pressure accumulator

Applicant:
Jean Mercier, New York, NY (V. St. A.)

Representative: Dr.-Ing. W. Lampert, patent attorney,
Stuttgart-Frauenkopf, Distlerstr. 33

Claimed priority:
V. St. v. America 9 December 1953

Jean Mercier, New York, NY (V. St. A.),
has been named as the inventor

but special means, depending on the flow conditions, are provided in the event of an early one Closing of the outlet opening should be prevented.

It is known per se to use load springs for valves connected in lines, which are stretched in the shape of an arc, bent in their center in the opposite direction to the arcuate curvature and are used in such a way that their tension decreases with increasing deflection. The usage such feathers remained restricted to a few special cases, since their special property is common was not considered necessary and the design with wide-stretched spring the use in narrow combined building units forbids.

It is also known to use plate-shaped or rod-shaped, axially loaded and laterally deflecting valves Use springs whose force is not proportional to the axial travel of the movable Spring end or not as much as this stroke increases. In all of these cases, however, only one small part of this travel used, the z. B. by biasing in a certain position and through Stops is limited. These known springs can therefore not give any clue, like the one at the beginning mentioned disadvantages in outlet valves of pressure accumulators can be eliminated.

These disadvantages are avoided according to the invention by such a design of the resilient Means of the exhaust valve that its the movable

709 658/217

Partition counteracting force at least over the major part of the closing path of the closure piece decreases with increasing deformation.

With this measure, one obtains an outlet valve that meets all requirements from a few and sturdy parts and is easy to assemble. There is little against interference vulnerable, remains open until all the oil has left the pressure accumulator - even if it is extremely fast flows out - and yet it closes safely before the Partition wall reached its end position or could be pushed into the outlet opening.

Some embodiments of the invention are shown in the drawing. It shows

Fig. 1 is a longitudinal section through a pressure accumulator ¹ S with a first embodiment of the invention, the

FIGS. 2 to 6 further exemplary embodiments for memory according to the type of FIG. 1 in longitudinal section,

7 shows the embodiment according to FIG. 6 in a different position and

Fig. 8 is a diagram for the operation of the resilient means in the outlet valve.

The accumulator according to Fig. 1 has a housing 11 made of high-strength material, such as. B. steel, cast aluminum or the like, which can withstand high pressures. The housing has the shape of a cylinder with attached Hemispheres; A partition 14 is located between a gas inlet 12 and an outlet opening 13. This consists of a bladder of variable shape and size made of stretchable material, for example Rubber or plastic with similar properties. The bladder is, if not compressed, but is also not stretched, smaller than the cavity of the housing 11. The gas inlet 12 is connected to the interior of the bladder 14.

A valve 15 is arranged to close the opening 13. One of its parts is a sleeve 16 which is fixed in the opening 13.

There are various designs for this attachment possible; the one selected in the example allows the sleeve to be removed without the pressure accumulator at the Damage removal. The sleeve 16 has at its inner end an outwardly directed flange 17, the outside diameter of which is smaller than the diameter of the opening 13. The flange has to the outside a shoulder 18. A retaining member, namely a ring 21, surrounds the sleeve 16 and rests on an edge 22 of the Opening 13. The outer diameter of the ring is larger than that of this opening; but the ring can be deformed for insertion into this opening. The inner diameter of the ring 21 is smaller than the outer diameter of the flange 17, so that the shoulder 18 is supported on the ring.

A sealing ring 23 is inserted between the sleeve 16 and the opening 13 to prevent liquid from escaping prevented between these parts if a ring nut 24 is screwed onto the outer part of the sleeve 16 and so that the flange 17 is pulled against this ring nut.

In the sleeve 16, a disk 31 is attached, in which a longitudinal bore 32 and a larger number of Passages 33 are provided for the oil.

The inner end of the sleeve 16 is conical to a seat 34 for the correspondingly beveled edge 35 of the closure piece 36 is formed. The surface 37 of the closure piece which lies towards the interior of the housing is rounded. A shaft 38 connects to the closure piece, which slides in the Longitudinal bore 32 is guided and protrudes through it to the outside. At the outer end of the shaft 38 a collar 39 is formed which limits the inward movement of the shaft 38.

The shaft 38 and the closure piece 36 are pressed by resilient means 42 into the housing 11, so that the edge 35 remains away from the seat 34 and the interior of the housing 11 with the bore 41 the sleeve 16 is connected.

These resilient means 42 are designed so that they have a considerable force in the rest position on the Exercise shaft 38 and thus keep the breechblock in the open position; however, if they are about a specific Amount are deformed, their force decreases sharply.

In the embodiment of FIG. 1, a pair of leaf springs 42 is used as such a means. The outer ends of the springs sit in abutments through recesses 44 in the wall of the sleeve 16 are formed on opposite sides. Insert the upper ends 45 of the springs in recesses 46 in the lower end of the shaft 38. The embodiment according to FIG. 2 is that according to Fig. 1 is similar; corresponding parts are provided with the same reference number but with a prime, marked.

In this embodiment, the bore 41 'has a sleeve 16' in its inwardly lying portion 47 has a smaller diameter, so that an annular shoulder 48 is formed. In section 47 is a hollow piston 49 slidably guided, which has an outwardly protruding at its lower, open end Flange 51 has. This flange lies in the open position of the hollow piston serving as a closure piece 49 against the ring shoulder 48.

The inner end of the hollow piston protrudes over the

flat inner face 52 of the sleeve I ^ jtQJV '

when it is in the open position. It is closed by an end wall 53. In the jacket of the hollow piston 49 at least one opening 54 is made close to the closed end. She educates in the Open position of the valve the connection between the interior of the housing 11 and the bore 41 'of the Sleeve 16 '.

The hollow piston 49 is pushed inward into its open position by a leaf spring 42 ', which the Leaf springs 42 in FIG. 1 corresponds. The upper end 56 of the leaf spring 42 ′ rests in a recess 57 the inside of the end wall 53, the lower end 58 is held by a recess 59 which is in the center of a perforated disk 61 is located. This perforated disk is screwed into the bore 41 and contains a number of holes 62 for the liquid. The embodiment of FIG. 3 also includes the embodiment of Figure 1 identical or similar parts; they are marked with the same Reference symbols which are supplemented by two dashes. The shaft 38 ", which is attached to a locking piece 36" is seated through the bore 32 ″ of a disk 31 ″ and through the bore 63 of a second disk 64 guided. This second disk is fastened below the disk 31 ″ in the bore 41 ″.

The locking piece 36 "is held in the open position away from its seat 34" by an or as shown in the exemplary embodiment, a plurality of disc springs 65 surrounding the shaft 38 ″ and between the disc 31 "and the closure piece 36" are used. They are each in opposite positions placed on top of one another, so that their spring deflections add up. The disc springs 65 act like the leaf springs 42 and 42 'by being in the position shown

apply considerable force to the latch 36 "holding it in the open position. If but if they are compressed by a certain amount, the force they exert decreases strong.

In the exemplary embodiment according to FIG. 4, a bolt 71 is fastened in the opening 72 of the housing, and preferably by the same means as shown in FIGS.

In the bolt 71 several outlet openings 73 are drilled, which are close to the outer circumference of the inner The end face 74 of the bolt 71 begins and leads to a longitudinal bore 75 of the bolt 71. One for Inside the memory, curved disc 76, which consists of spring steel, is with the help of a screw 77 attached to the inner face 74 of the bolt. Their spring force behaves like that of the springs in FIGS. 1 to 3. The convex underside of the disk lies opposite the end face 74. The diameter the disc 76 is so large that its edge 78 closes the outlet openings 73 when it is removed from the partition is pushed outwards.

In the embodiment according to FIG. 5, the pressure accumulator has a housing 84 made of steel, cast aluminum or similar material, which again has the shape of a cylinder with attached hemispheres. The upper end of the housing has a relatively wide opening 85. It is fitted with a plug 86 closed, which carries a gas inlet 87.

At the lower end of the housing is a tubular extension 88, the bore 89 of the Forms liquid outlet. A flexible partition in the form of a soft and stretchable bladder 91 made of suitable elastic material separates the inlet 87 from the outlet 89. The inlet 87 is with the Connected inside the bladder 91.

A valve 92 is provided to close the outlet. Its closure piece is a hollow piston 93, which is slidably guided in a narrowed section 94 of the bore 89.

At its inner end, the piston 93 has an end wall 95, the edge of which protrudes conically is. A valve seat 96, which has the same shape, is assigned to this edge, so that the flow is closed when these two parts lie on top of each other. Has 95 close to its end wall the hollow piston 93 has several openings 97; in the open position they connect the interior of the housing 84 with hole 89.

The hollow piston 93 is urged inward into its open position with the aid of leaf springs 98, which the springs of FIG. 1 are similar. The upper ends 99 of each spring sit in recesses 101 the underside of the end wall 95; the lower ends 102 of the springs are supported on an annular shoulder 103. This ring shoulder is formed by the upper end of a ring nut 100, which is inserted into the lower end of the extension 88 is screwed. The movement of the hollow piston 93 into the housing is carried out by an annular nut 104 which is screwed onto the outwardly directed end of the hollow piston 93 and lies against a shoulder 106 of the bore 89 in the open position.

The exemplary embodiments according to FIGS. 6 and 7 are essentially the same as that according to FIG. 1; the leaf springs 42 are, however, replaced by spiral springs 111, which behave in the same way as the leaf springs. These Coil springs are also known as "negative springs". They have coiled spirals Spring strips, the original curvature of which is greater than the curvature when wound up. the original curvature decreases from the free end of the spring towards the inside of the coil. the spring force resulting from the bending open of the spring elements when the springs are unwound is therefore relatively large at the beginning and becomes smaller and smaller the more the spring leaf is withdrawn will. The springs can also be designed so that the spring force initially increases and from a decreases again at a certain point.

As shown in FIGS. 6 and 7, a shaft 112, which is seated on a locking piece 113, in the bore 114 of an extension 115 which is located on a perforated disc 116. This disk is fastened in a sleeve 117. Coils 118 and 119 of the spring 111 are rotatable Bolt 121 fastened in the sleeve 117. Between the coils is a smooth piece 122 of the spring 111. It is bent over the end 123 of the extension 115. The lower end 124 of the shaft 112 has a smaller diameter and is inserted through an opening of the spring piece 122. One on this end Screwed nut 125 holds the shaft 112 and the spring piece 122 together. The bore 114 is on The lower end 123 of the extension 115 is expanded to form a recess 126.

When pressure fluid is pressed into the housing, it urges the closure piece 113 of the valve strong inwards. The spring piece 122 strikes the end 123 of the extension 115 and bends in of the recess 126, as shown in FIG. 7. This will reduce the impact of the liquid on the Locking piece 113 caught and prevents the thread of the nut 125 or the end 124 of the Shank 112 is torn off.

In all the exemplary embodiments, the resilient means are in the open position of the closing element under tension. Their mode of operation is described with reference to FIG. 8.

When the resilient means are put under pressure by the expanding bladder, for example, they deform they move from the tense state by a certain distance, which is determined by the abscissa 81 of the Diagram in Fig. 8 is shown.

As the deformation progresses to point A , the force with which the resilient means attempt to prevent the valve from closing increases continuously by amounts measured on ordinate 82. If the resilient means are compressed even further, so that point A is exceeded, the force exerted by the means continuously decreases again.

In the open position of the closing element, the resilient means are pretensioned by a certain distance with a force. This state should correspond to point B of the diagram. There is thus a considerable amount of force available to keep the valve open.

Even if a large amount of the liquid flows out through the outlet and a large pressure difference arises on the different sides of the locking piece, this force is the biased one Medium enough to compensate for this pressure difference and keep the valve open.

If, for example, in the embodiment of FIG. 1, the bladder 14 expands slowly and against the closure piece 36 places, this is not moved until the bladder has expanded so much that it exerts a force on the closure piece which exceeds the force of the leaf spring 42, d. H. until the

By force of the bladder 14, point B ' of FIG. 8 has been reached. Only then does the breech piece begin to move.

At this moment, almost all of the oil has flowed out of the housing 11. If the bladder is still extends a little further and presses even harder on the locking piece, this moves downwards and compresses the springs 42 until they reach the point on the graph.

If the bladder 14 expands further and the springs 42 are compressed even more, the counterforce of the springs 42 decreases. The increasing force of the bladder 14 therefore quickly overcomes the force still applied by the springs 42, and the closure piece 31 is almost instantaneously on ^{its seat 1} S before the bladder 14 can squeeze under its edges.

The springs of the embodiments according to FIGS. 2 to 6 act in the same way.

As can be seen from the description, the valve according to the invention is actually able to Regardless of the speed of the outflowing oil, the outlet of the pressure accumulator is like this to keep open for a long time until almost all of the oil has drained off. On the other hand, it closes an outlet safely when the oil has drained. This is advantageous for all types of accumulators, even if they are used as Partition have a piston; it is particularly advantageous for pressure accumulators with bubbles, their penetration is prevented in the outlet opening in this way.

The housing of the accumulator can have various shapes, e.g. B. also the shape of a sphere. the The abutment of the resilient means can also be projections instead of the recesses.

Claims (25)

Patent claims: 1. Outlet valve for a pressure accumulator with a rigid housing and a movable one Partition, which at the end of the emptying of the memory against the pressure of resilient means Closure piece of the exhaust valve pushes into its final position, characterized by a such design of the resilient means of the outlet valve that their of the movable partition (14) counteracting force at least over the substantial part of the closing path of the closure piece decreases with increasing deformation (Fig. 8). 2. Exhaust valve according to claim 1, characterized in that the resilient means in the Open position of the closure piece are biased with a certain deformation. 3. Outlet valve according to claim 1 or 2, characterized in that the closure piece (36, 113) has a surface (37) that is at most slightly curved on its inward-facing side, against which the unreinforced partition (14) is against during the closing movement without the risk of damage can put (Fig. 1, 3, 6 and 7). 4. Outlet valve according to claim 1 or 3, characterized in that on the closure piece (36, 49, 93) and on a part of the abutment immovably connected to the storage housing (11) are provided, between which the resilient means without special fastening means are used (Fig. 1, 2, 3, 5). 5. Exhaust valve according to one of claims 1 to 4, characterized in that the resilient Means consist of a leaf spring (42) (Fig. 2). 6. Outlet valve according to claim 4 and 5, characterized in that the leaf spring (42) is at least extends almost in the direction of movement of the closure piece (49) (Fig. 2). 7. Outlet valve according to one of claims 1 to 4, characterized in that the resilient Means consist of two leaf springs (42), one end of which is close to one another on the closure piece (36, 93) and their other ends at opposite positions of the storage housing (11) are attached (Fig. 1 and 5). 8. Exhaust valve according to one of claims 1 to 4, characterized in that the resilient Means are designed as a disc spring. 9. Outlet \ ^r entil according to one of claims 1 to 4, characterized in that the resilient means consist of a set of stacked disc springs (65), which are each paired with their bases or their edges facing each other (Fig. 3). 10. Outlet valve according to one of claims 1 to 4, characterized in that the resilient Means are spiral springs (111) which sit on rotatable abutments (121) (FIGS. 6 and 7). 11. Exhaust valve according to claim 10, characterized in that the spiral springs (111) on two fixed and immovable abutments (121) on both sides of the axis of the closure piece (113) are connected by a spring piece (122) which is attached to the closure piece (113) (Fig. 6 and 7). 12. Outlet valve according to one of claims 1 to 11, characterized in that the closure piece (36,49,113) is seated in a sleeve (16, 16 ', 117) which forms the liquid outlet and which is in an opening of the storage housing (11) is attached, and that the resilient means between you Sleeve (16, 16 '117) and the closure piece (36, 49, 113) are inserted (Fig. 1, 2, 3, 6 and 7). 13. Exhaust valve according to claim 12, characterized in that a perforated in the sleeve Disc (61, 31 ") is used, against which the resilient means are supported (Fig. 2 and 3). 14. Exhaust valve according to claim 12 or 13, characterized in that the closure piece (36, 113) has a shaft (38,112) which is fastened in a perforated in the sleeve (16, 117) Disc (31, 31 ", 116) is slidably guided (Fig. 1, 3, 6 and 7). 15. Exhaust valve according to claim 14, characterized in that the abutment for the one Side of the resilient means at the end of the shaft (38, 112) of the closure piece (36, 113) (Figures 1, 6 and 7). 16. Exhaust valve according to claim 14, characterized in that as an abutment for one end of the resilient means the end face (53, 95) of the closure piece (49, 93) is used (Fig. 2 and 5). 17. Exhaust valve according to one of claims 14 to 16, characterized in that the perforated Disc (116) has an extension (115) which serves as a guide for the shaft (112) and with its end as a stop for limiting the opening movement of the closure piece (113) serves (Fig. 6 and 7). 18. Exhaust valve according to one of claims 14 to 16, characterized in that the end of the Shaft (38, 112) carries a collar that interacts with a fixed stop (Fig. 1, 6 and 7). 19. Exhaust valve according to claim 17, characterized in that the extension (115) is recessed at its outwardly directed end around the guide bore (114) and that the shaft (112) of the closure piece (113) with a resilient means (111 ) is connected in such a way that this means lies on the edge of the recess when the closure piece (113) is open, but a resilient piece is still freely movable within this edge up to the shaft (112) , so that the shaft (112) is resilient in the End position is held (Fig. 6 and 7). 20. Exhaust valve according to one of claims 1 to 13, characterized in that the closure piece is a hollow piston (49, 93) closed on one side by an end wall (53, 95), with transverse holes (54, 97) near its end face and an outer flange (51, 104) on the open side, and that this locking piece is guided in a bore which contains a shoulder (47, 106) against which the flange (51, 104) of the locking piece rests in the open position (Fig . 2 and 5). 21. Exhaust valve according to claim 20, characterized in that the edge of the end wall (95) of the closure piece (93) is designed as a seat and cooperates with a fixed seat (96) (Fig. 5). 22. Exhaust valve according to claim 20 or 21, characterized in that as an abutment for the resilient means (42) the inner surface of the end wall (53, 95) of the closure piece (49, 93) is used, so that the resilient means (42) are partly within the closure piece (49, 93) (Figures 2 and 5). 23. Exhaust valve according to claim 1, 2 or 3, characterized in that the closure piece is a towards the interior of the memory (11) curved resilient disc (76), which in their Is attached in the middle and the edge (78) of which protrudes beyond the outlet openings (73) for the liquid, and that the disc under the pressure of the movable partition (14) sealingly on the Outlet openings (73) sets (Fig. 4). 24. Exhaust valve according to claim 23, characterized in that the disc (76) consists of metal (Fig. 4). 25. Exhaust valve according to claim 23 or 24, characterized in that in the housing of the Pressure accumulator (11) a bolt (71) is inserted with a longitudinal bore (75) which is connected to the outlet openings (73) near the edge of the end face of the bolt located inside the container is connected, and that in the middle of this end face, the resilient washer (76) is attached (Fig. 4). Considered publications:
German patent specifications No. 50 959, 198 411,
575, 732 528, 878 132; Austrian Patent No. 30,283;
French Patent No. 317 860;
U.S. Patent No. 2,399,996. Cited earlier rights:
German Patent No. 951 402. 1 sheet of drawings © 709 658/217 8.57