RU2162564C1 - Pressure bottle made from composite materials and method of manufacture of such bottles - Google Patents

Abstract

FIELD: high-pressure vessels. SUBSTANCE: proposed bottle has multilayer load-bearing shell made from intersecting unidirectional threads and polymer binder and inner protective polymer envelope. Besides that, bottle is provided with capillary porous member located between framework and envelope; this member is made in form of circular reticular cellular structure with tetrahedral cells between intersecting strips located at intervals in circular and axial directions. Bottle is also provided with at least one layer of anti-adhesive material laid between framework and capillary porous member. Method of manufacture of such bottle includes supply of excessive pressure to protective polymer envelope, winding intersecting unidirectional threads impregnated with polymer binder forming layers of load-bearing framework and heat treatment of bottle; prior to winding, capillary porous member is laid on protective layer and at least one layer of adhesive material is laid on it. EFFECT: enhanced reliability. 4 cl, 6 dwg

Description

 The invention relates to pressure vessels for a fluid, mainly liquefied gas, and more specifically to high pressure cylinders and methods for their manufacture, the shells of which are made of composite material and coated inside with an airtight shell.

 Basically, vessels of this type are intended for storage and transportation of liquefied gas in domestic conditions or use as a replaceable container of compressed gas in vehicles to power an internal combustion engine.

 Known pressure cylinder made of composite materials containing a multilayer power frame made of intersecting unidirectional filaments and a polymeric binder, and an internal protective metal shell with radial corrugations, in which the corrugations of the corrugations are filled with incompressible plasticized material, practically non-engaging with the external power frame, which provides displacement of the internal power frame shell when they are stretched. The filling substance resists the straightening of the corrugations on the inner shell and the increase in the peripheral distance between adjacent ridges when it is stretched. US patent 3446385 C. B 65 D 7/42, 1966.

 However, as the test results showed, with such a design of the cylinder in its cylindrical part, high stresses are created in the annular direction, the inner protective metal shell is not affected by axial loads, and such cylinder designs are not suitable for storing gases under high pressure and cyclic loads of up to a thousand or more times due to the failure to ensure compatibility of the work of the inner layers - the inner protective metal shell and the multilayer power frame of the intersecting one directed filaments and a polymer binder, leading to delamination between them and premature destruction of the layers.

 A known method of manufacturing a pressure cylinder from composite materials which includes winding onto a protective metal shell with radial corrugations of intersecting unidirectional threads impregnated with a polymeric binder, with the formation of layers of the power frame, its heat treatment taking into account the choice of the temperature regime of curing the binder and curing the binder under excessive pressure of the working medium in metal shell. (V. A. Kalinichev, M. S. Makarov. Coiled fiberglass, Moscow, Chemistry, 1986, p. 218-224).

 The disadvantages of this method include the difficulty of providing conditions for joint deformation during repeated loading of the metal shell and the multilayer power frame, since this manufacturing technique does not ensure the compatibility of the metal shell and the multilayer power frame.

 Closest to the proposed invention in terms of essential features is a pressure cylinder made of composite materials containing a multilayer power frame made of intersecting unidirectional threads and a polymer binder, and an internal protective polymer shell, as well as a method of manufacturing a pressure cylinder made of composite materials, including winding on under pressure, the protective polymer shell of the crossed unidirectional threads impregnated with polymer a binder to form a layer of the power frame, and its heat treatment.

 (WO 92/20954 A1, F 17 C 1/16, 10.26.1992).

 The disadvantages of this cylinder and the method of its manufacture are the extreme complexity of its design and, accordingly, the manufacturing technology, as well as its significant mass.

 In addition, although the known cylinder provides for certain measures to protect its integrity under external influences, however, it essentially lacks means to prevent the effect of increased internal pressure on the tightness of the cylinder. The internal design of the container is such that, at elevated pressures, the detachment of the internal sealing shell from the power frame and, as a consequence, a violation of the tightness of the balloon, are not excluded.

 The main objective of the invention is the creation of a pressure cylinder from composite materials and the method of its manufacture, respectively, of such a design and such technological methods that would create a highly efficient product that can reliably absorb and carry multi-cycle loads at the highest pressures without damage and destruction of its load-bearing elements.

 The technical result that can be achieved by implementing the inventions is to ensure the reliability of sealing under conditions of joint deformation of the inner protective polymer shell and the multilayer power frame of the cylinder at high pressures and increased cyclic loading, improving the quality of manufacture and reliability of products.

 The problem is solved and the technical result is achieved due to the fact that in the pressure cylinder made of composite materials containing a multilayer power frame made of intersecting unidirectional threads and a polymer binder, and an internal protective polymer shell, it is new that the cylinder is equipped with located between the frame and a capillary-porous shell element made in the form of an annular mesh-cell structure covering the shell with tetrahedral cells between the intersecting jumpers located at intervals in the annular and axial (meridional) directions.

 And in addition, the cylinder is equipped with at least one layer of release material, for example, a type of polyethylene or fluoroplastic film, located between the frame and the capillary-porous element.

 The lintels of the capillary-porous element are made in the form of intersecting dry unidirectional strands of threads, crosswise applied, sequentially, or selectively interlaced in the annular and axial directions.

 The size of the interval between the jumpers is 5-10 sizes of the width of the jumper, for example, the diameters of the bundle.

 Additionally, the problem can be solved due to the fact that the crossed unidirectional strands of threads are made in the form of a shell-core structure, in the core of which there is a bundle of fastened threads, and the shell of the bundles is made in the form of a braid of crimping threads applied to the bundle along spatial spirals, respectively from glass, basalt or organic fibers, or combinations of them with a volume ratio of the core and shell from 1: 0.05 to 1: 0.2.

The problem is also solved by the fact that in the known method of manufacturing a pressure cylinder from composite materials, including applying excess pressure to the protective polymer sheath, winding intersecting unidirectional threads impregnated with a polymer binder, with the formation of layers of the power frame, and heat treatment of the cylinder, before winding on a protective polymer a capillary-porous element is applied to the shell and at least one layer of release material is laid on it, and heat treatment is carried out at the next constituent conditions: raising the temperature of the external environment to a level above at 20-30 ^o C maximum temperature polymerization mode binder, and kept at that temperature for the time necessary to achieve on an inner layer circuit carcass antiadhesive material melting temperature, and then dropping the temperature of environment to the melting temperature of the release material and at the same time raise the internal overpressure to the level of 25-30% of the operational and final term treatment is carried out under these conditions to complete the polymerization power skeleton binder.

 In FIG. 1 shows a general view of a composite pressure cylinder.

 In FIG. 2 shows a section along AA in an enlarged scale.

 In FIG. 3 shows a crosswise arrangement of threads.

 In FIG. 4 shows sequential weaving of threads.

 In FIG. 5 shows selective weaving of threads.

 In FIG. Figure 6 shows the structure of the sheath-core-type strands.

 The pressure cylinder made of composite materials contains a multilayer power frame 1 made of intersecting unidirectional filaments 2 and 3 and a polymer binder 4, and an internal protective polymer shell 5, and the cylinder is equipped with a capillary-porous element 6 located between the frame 1 and the shell 5, made in the form covering the sheath 5 of an annular mesh-cellular structure with tetrahedral cells 7 between intersecting jumpers 8, 9 located at intervals in the annular and axial (meridional) n directions.

 The size of the interval between the jumpers is 5-10 sizes of the width of the jumper or the diameter of the bundle.

 In addition, the container may be provided with at least one layer of release material 10, such as a polyethylene or fluoroplastic film, located between the frame 1 and the capillary-porous element 6.

 The jumpers 8, 9 are made in the form of intersecting dry unidirectional tows of 11 threads, cross-shaped, sequentially or selectively interwoven in the circular and axial directions.

 In this case, the crossed unidirectional tows 11 of the threads can be made in the form of a shell-core structure, in the core 12 of which there is a bundle of bonded threads 13, and the shell 14 of the tows 11 is made in the form of a braid from the strands 13 deposited onto the bundle along spatial spirals of compression threads 15, respectively made of glass, basalt or organic fibers, or combinations of them with a volume ratio of the core and shell from 1: 0.5 to 1: 0.2.

 A method of manufacturing a pressure cylinder from composite materials consists in applying a capillary-porous element 6 made on the protective polymer shell 5, which is under excess pressure of a working medium, for example air or liquid such as water or oil, made in the form of a ring-shaped mesh-square structure covering the shell cells 7 between the intersecting jumpers 8 and 9 located at intervals in the annular and axial directions.

 Then, on the capillary-porous element 6, to weaken the bond of the protective polymer shell 5 with the power frame 1, at least one layer of release material 10, for example, a type of polyethylene or fluoroplastic film, is laid.

 After that, the winding is produced on the thus obtained assembly of intersecting unidirectional threads 2 and 3, impregnated with a polymer binder 4, with the formation of layers of the power frame 1.

In the manufacturing process, the cylinder is subjected to heat treatment, for example, in a special chamber, under the following conditions: raise the temperature of the external environment to a level that exceeds by 20-30 ^o C the maximum temperature of polymerization of the binder, for example 140 ^o C, and maintain at this temperature, approximately 160-170 ^o C, for example, 5-10 minutes (depending on the balloon size), i.e. the time necessary to achieve on an inner layer circuit carcass temperature of about 90-120 ^o C melting antiadhesive material, then dumped vayut ambient temperature to a temperature, for example 110 ^o C, the melting antiadhesive material 10 and simultaneously raise the internal pressure to a level of 25-30% of the operating and final heat treatment is carried out at these conditions until cured binder force frame 1.

 The operation of a pressure cylinder made of composite materials is carried out in the same way as any other cylinder. In this case, the entire pressure load during repeated cyclic loading, repeated during operation, is perceived by the multilayer power frame through the capillary-porous element, which provides increased reliability.

Claims (4)

 1. A pressure cylinder made of composite materials containing a multilayer power frame made of intersecting unidirectional filaments and a polymer binder, and an internal protective polymer shell, characterized in that the cylinder is equipped with a capillary-porous element located between the frame and the shell, made in the form of an annular enveloping shell mesh-cellular structure with tetrahedral cells between the crossing bridges located at intervals in the annular and axial directions, however, the container is also provided with at least one layer of release material located between the frame and the capillary-porous element.  2. The cylinder according to claim 1, characterized in that the size of the interval between the jumpers is 5 to 10 sizes of the width of the jumper, while the jumpers of the capillary-porous element are made in the form of intersecting dry unidirectional bundles of threads, crosswise applied, sequentially or selectively interlaced in a circular and axial directions.  3. The cylinder according to claim 2, characterized in that the intersecting unidirectional strands of threads are made in the form of a shell-core structure, in the core of which there is a bundle of fastened threads, and the shell of the bundles is made of a braid made of filaments deposited on the bundle along spatial spirals of compressing threads, respectively made of glass, basalt or organic fibers, or combinations of them with a volume ratio of the core and shell from 1: 0.05 to 1: 0.2. 4. A method of manufacturing a pressure cylinder from composite materials, including applying excess pressure to the protective polymer shell, winding intersecting unidirectional threads impregnated with a polymeric binder, forming layers of the power cage and heat treating the cylinder, characterized in that capillary-porous is applied to the protective shell before winding the element and at least one layer of release material is laid on it, and the cylinder is heat treated under the following conditions: raise the temperature External Expansion environment to a level above 20 - 30 ^o C maximum temperature polymerization mode binder, and kept at this temperature, then dumped ambient temperature for the time necessary to achieve on an inner layer circuit carcass antiadhesive material melting temperature to the melting point of the antiadhesive material and at the same time raise the internal overpressure to the level of 25-30% of the operational and the final heat treatment is carried out under these conditions until the polymerization of the binder power frame.

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