This application is the US-national stage of PCT application PCT/EP2009/006182, filed 26 Aug. 2009, published 4 Mar. 2010 as WO2010/022928, and claiming the priority of Russian patent application 2008134619 itself filed 27 Aug. 2008.
The present invention relates to a high-pressure container with a thin-walled, cylindrical, metallic liner with end walls and an outer stable jacket, which surrounds the liner. Such high-pressure containers serve to store and transport of fluid media (liquid or gas) under pressure.
High-pressure containers are known which are generally exposed to a plurality of load cycles with high pressure. In such containers the material of the sealing jacket, the liner, is particularly significant when it comes to preventing escape of the fluid medium or damage to the seal.
A high-pressure container is known from RU 2094695 C1 which comprises a liner with elongate and annular grooves, which are filled with a resilient material, reinforcing rings and annular reinforcing ribs, which are arranged in the annular grooves on the outside and are displaceable along the ring.
A disadvantage of the known solution lies in the fact that the combination of elongate and annular grooves increases the overall flexural strength of the liner but does not allow the material of the liner and the material of the composite jacket to be simultaneously deformed. Plastic deformation arises in the annular grooves under annular tensile loading and in the axial grooves under axial tensile loading of the liner, when the container is exposed to internal pressure. The introduction of different resilient inserts and additional rigid rings into the indentations of the grooves does not in practice lead to solution of the problem of interest, which is the creation of a highly effective pressure container.
A high-pressure container is known from U.S. Pat. No. 6,547,092 B1 which comprises a thin-walled metallic liner with a set of elongate grooves, wherein the arrangement of reinforcing fibers in the composite jacket is such that the deformation of the composite jacket corresponds to the deformation of the metallic liner. In this case, the grooves in the liner are filled with resilient material, while the liner itself is separated from the composite jacket by an insert of resilient material.
A disadvantage of this solution lies in the fact that exposure to elevated pressures results in deformation of the composite jacket in a predetermined direction, compression and redistribution of the material of the resilient insert and of the material located in the grooves. Because the surface provided with grooves of the liner is not an isometric cylindrical surface of the composite jacket nor a surface concentric thereto, the grooves of the thin-walled liner are arbitrarily deformed, and plastic deformation occurs therein, which leads under multiple load cycles to destruction of the liner.
The object of the present invention is to use structurally simple means to provide a low-weight high-pressure container with a long service life under a large number of load cycles.
This object is achieved by a high-pressure container which comprises a thin-walled, cylindrical, metallic liner with end walls and an outer stable jacket, which surrounds the liner, wherein at least one of the end walls of the liner is gently curved slightly convexly toward an interior of the liner, and a pressure buffer is arranged between the outer surface of the curved end wall and the inner surface of an end wall of the stable jacket, which pressure buffer takes the form, on the side directed toward the curved end wall, of a deformable cushion of viscoelastic material.
The technical result of the invention is to increase the stability of the container by reducing loading of the liner by expanding forces, reducing the weight of the container and its manufacturing costs and ensuring a long service life relative to the number of load cycles during which the container can be used is safely.
The total volume of viscoelastic material of the disks making up the cushion of the pressure buffer preferably exceeds the increase in interior volume of the stable jacket in the event of deformation in an axial direction.
According to one embodiment of the invention, the shape of the surface of the gently curved end wall of the liner is a cone with an opening angle of between 172° and 179°.
According to another embodiment, the shape of the surface of the gently curved end wall of the liner is segment of a sphere with a maximum height of the segment formed by this segment of a sphere of no more than 0.06 of the radius of the cylindrical liner.
According to a further embodiment, the shape of the surface of the gently curved end wall of the liner is in the form of a combination of conical surfaces and flat rings, the segment of a sphere inscribed in this shape of the surface having a segment height of no more than 0.06 of the radius of the cylinder.
Over the entire contact surface, an ellipsoidal end wall of the outer stable jacket and the base of the pressure buffer may be separated from one another by friction-reducing material.
The high-pressure container shown in
The mode of operation of this high-pressure container is explained with reference to the following example.
It is known from geometry that two surfaces are described as isometric if one of them may be transformed into the other without the internal metrics being changed, i.e. surfaces which can merge together solely by deformation of the curvature.
It is likewise known from mechanics that deformation of the surface of a gently curved jacket proceeds without changing the internal metrics and constitutes geometric flexure, which is achieved by a mirror reflection of part thereof relative to a specific plane, or by successive implementation of a series of such reflections, shown schematically in
This transition of the end wall into a deformed state is isometric and is associated with considerable flexure of the end wall.
With the above-mentioned container design at least one of the end walls 8 of the liner 1 is gently curved, its surface in the deformed state being isometric to the surface in the original state. This surface of the end wall 8 of the liner 1 may here be formed of sub-surfaces whose different shape variants are shown in
A pressure buffer 4 is arranged in the space formed between the gently curved end face of the end wall 8 of the liner 1 and the inner surface of the stable jacket 2. The task of the pressure buffer 4 is to transform the effect of the constant internal pressure on the gently curved end wall 8 of the liner 1 into a movement of the rigid base 5 under the action thereof and the creation of a specific contact pressure on the end wall of the stable jacket 2, which is unevenly distributed over its contact surface with the base 5 of the buffer 4. Such a transformation is effected by the resilient contraction and expansion of the material of the disks 7 of the cushion 6 on deformation thereof.
The dimensions of the disks 7 are selected on the condition that the total volume of their material exceeds the increase in volume of the stable jacket 2 on deformation thereof axially.
The essential details of the mode of operation of the liner 1 in this embodiment are as follows: As a pressure develops in the cavity of the container the gently curved end wall 8 of the liner 1 is deformed without expanding or contracting membrane deformation and ultimately, solely due to bending strain, achieves a shape which is isometric to the initial shape. Compression of the viscoelastic material of the disks 7 then takes place, and as a result of its incompressibility the pressure is transmitted via the entire surface of the end wall 8 to the rigid base 5 and through this to the end wall of the stable jacket 2, wherein it is distributed thereover in the form of a contact pressure of uneven profile, the viscoelastic material being virtually incompressible in terms of a reduction in its volume. The stable jacket 2 is also deformed and enlarges the internal volume enclosed thereby. At the same time, the material of the disks 7 is deformed axially and expands into the spaces which arise as a result of deformation of the stable jacket 2. Because the total volume of the material of the disks 7 is greater than the increase in volume on deformation of the stable jacket 2, the flexure of the gently curved end wall 8 of the liner 1 does not, however, achieve the final isometric shape. The axial forces which arise as a result of the internal pressure in the container are only absorbed by the material of the stable jacket 2. No axial expanding forces arise in this respect in the material of the liner 1. The load is transmitted by the base 5 of the pressure buffer 4 as contact pressure between the base 5 and the stable jacket 2 to the material of the stable jacket 2, and the base 5 acts as a rigid whole and undergoes virtually no deformation under the pressure applied. The profile of the end wall of the stable jacket 2 of the container must be selected, on condition of uniform loading of the material, within the limits of the shape of the base 5.
Thus, because the liner 1 does not absorb any axial forces, its wall thickness and the material may be selected on the basis of conditions which are not associated with the deformation of the container on internal pressure in the radial direction. This makes it possible to combine an embodiment of the liner with longitudinal grooves with the stated technical solution and thereby to rule out to a considerable extent loading of the liner by expanding forces, which makes it possible to reduce the weight of the liner and its production costs. In this respect it is also possible to use relatively inexpensive components for the material of the stable jacket, for example glass fibre-reinforced plastics.
The geometry of the surface of the gently curved end wall 8 of the liner 1 is selected as explained in the following example.
As shown above, the basic condition of the action of the end wall 8 of the liner 1 is that the material of the end wall 8 of the liner 1 is not stretched. Deformation may only arise through isometric flexure. Taking account of the given limit and the second condition that the bending strain must not exceed the level of the resilient deformation in the material of the liner 1 (for metals and their alloys: 0.2%), the specific relationships between the shape and the depth of the inward flexure of the gently curved end wall 8 of the liner 1 are determined. It is in particular proposed to use three types of shape: a conical shape, a segment of a sphere and a combination of conical shapes and faces.
A solution is possible as an embodiment of the end wall 8 of the liner 1 in which one part of the end wall 8 is formed as a flat membrane and one part is formed as a cone and/or segment of a sphere.
The mode of operation of the high-pressure container consists in its being filled up to the necessary pressure level with a fluid medium (liquid or gas), stored, transported, emptied and then refilled, the fluid medium being consumed, i.e. it consists of a series of actions and steps with multiple load cycles.
The creation of the proposed device results in the real possibility of using high-pressure containers of composite material having a thin-walled metallic inner jacket. Production and testing of high-pressure containers with the proposed liner for sealing thereof confirmed the high reliability and effectiveness thereof.
The invention may be used in portable oxygen respirators for mountaineers and rescue workers, in mobile refrigeration and fire protection products, in gas supply systems and in automotive engineering.
Number | Date | Country | Kind |
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2008134619 | Aug 2008 | RU | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/006182 | 8/26/2009 | WO | 00 | 3/3/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/022928 | 3/4/2010 | WO | A |
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Number | Date | Country |
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2007051432 | May 2007 | WO |
Number | Date | Country | |
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20110266182 A1 | Nov 2011 | US |