RU45503U1 - HIGH PRESSURE CYLINDER - Google Patents

Abstract

The utility model relates to pressure vessels for a fluid, mainly for compressed or liquefied gas, and more specifically to high pressure cylinders. Basically, cylinders of this type are intended for storage and transportation of compressed or liquefied gas for domestic or industrial needs or use as a replaceable gas tank in vehicles for powering propulsion systems. The objective of the proposed utility model is to create a dissipative, highly efficient vessel capable of reliably absorbing and carrying multi-cycle loads at the highest pressures without damaging and destroying its load-bearing elements with a significant increase in the ratio of gas weight to cylinder weight. The technical result is achieved in the proposed utility model by creating a high-pressure cylinder, consisting of a body, the bottom of which has a bottom, and a gas inlet is installed in the neck, an internal metal sealing shell (liner) coaxially placed in it, the shell being connected to the gas inlet, in which According to the utility model, the liner is rigidly connected to the body and is made in the form of longitudinal paths rigidly connected to each other, some ends of the paths are hermetically fixed to the bottom of the body, and others are connected to the gas house, wherein the inner diameter of paths from the center to the periphery monotonically decreases and increases the thickness of their walls.

Description

The utility model relates to pressure vessels for a fluid, mainly for compressed or liquefied gas, and more specifically to pressure vessels.

Basically, cylinders of this type are intended for storage and transportation of compressed or liquefied gas for domestic or industrial needs or use as a replaceable gas tank in vehicles for powering propulsion systems.

Known combined fiberglass cylinder with a thin-walled sealing metal shell (liner) not bearing external load and capable of perceiving significant deformations, both in the longitudinal and in the circumferential direction (see RF patent No. 2094695, class F 17 C 11/00, 1994 g).

In a known construction, the liner is connected to the gas inlets and has corrugations located both in the longitudinal and in the circumferential direction. The cavities formed by the corrugations located in the longitudinal direction on the outer surface of the liner are filled with an elastic material, for example, an elastomer.

The disadvantages of the known design are:

- limited applicability, both in the composition of the gas used (hydrogen, helium, neon, etc.) and in the applied pressure;

- the degree of dissipation of the known design does not meet the safety requirements for pressures exceeding 50 MPa.

The closest in technical essence to the proposed solution is the design of a high-pressure cylinder, consisting of a body in the lower part of which the bottom is made, and a gas inlet is installed in the neck, coaxially placed in it of the internal metal sealing shell (liner), and the shell is connected to the gas inlet ( Serensen S.V. Zaitsev G.P.

"The bearing capacity of thin-walled structures made of reinforced plastics with defects" Kiev, Naukova dumka, 1982, p.261).

In a known container, the housing is made of fiberglass, the sealing liner is a supporting element, i.e. he takes part in the perception of external load from the influence of the pressure of the working environment.

With a single loading of the cylinder with the internal pressure of gas or compressed air, a metal sealing liner has certain advantages compared to a liner made of non-metallic materials, since allows for minimal gas diffusion, and its permeability can be easily controlled.

With multiple cylinder loads (500-1500 cycles), the reliability of the metal liner is significantly reduced due to a sharp difference in the elastic moduli of the metal and fiberglass of the durable shell of the balloon.

Under the influence of multi-cycle loads, the metal liner undergoes fatigue creep in the form of permanent deformation and prematurely fails, while the high-pressure cylinder loses its tightness.

The disadvantages of the known design of the cylinder include the fact that the metal liner, as a supporting element, has a thickness equal to 0.4-0.6 thickness of the fiberglass body, i.e. thickness commensurate with the thickness of the body.

Therefore, the metal liner has a significant mass, has a low corrosion resistance in aggressive environments and a high creep rate at an elevated gas storage temperature.

The objective of the proposed utility model is the creation of a dissipative high-performance balloon capable of reliably absorbing and carrying multi-cycle loads at the highest pressures without damage and destruction of its load-bearing elements when

a significant increase in the ratio of gas weight to cylinder weight.

The technical result is achieved in the proposed utility model by creating a high-pressure cylinder, consisting of a body, the bottom of which has a bottom, and a gas inlet is installed in the neck, an internal metal sealing shell (liner) coaxially placed in it, the shell being connected to the gas inlet, in which , according to the proposed utility model, the liner is rigidly connected to the body and is made in the form of longitudinal paths rigidly connected to each other, one ends of the paths are hermetically fixed to the bottom of the body, and the other is connected are connected with the gas inlet, while the inner diameter of the paths from the center to the periphery decreases monotonically, and the thickness of their walls increases.

The utility model is also characterized in that the liner has a zone adjacent to the inner wall of the housing, the size of which is equal to 1 / 5-1 / 20 of the outer diameter of the vessel and in which the diameter of the paths decreases from the center to the periphery, and the wall thickness increases according to the formula:

δ≥1 / 3D,

where D is the detectable diameter of the path,

δ is the thickness of the wall of the tract with an elastic limit of the liner material of at least 200 kg / mm ² .

This allows the use of a cylinder for ionized gases with a small atomic radius, placed in a cylinder under high pressure (with high density).

The implementation of the supporting elements (liner and body) metal and repeatedly dissipative can significantly increase the safety of storage and transportation of gases.

The implementation of the paths in the form of tubes and / or capillaries can reduce the radial stress in the walls of the housing and as a consequence prevent its sudden destruction.

The proposed design of the cylinder allows you to get the optimal ratio of the weight of the filled gas to the weight of the vessel due to its

operation at high pressures.

Providing the housing, external and internal surfaces of the paths with a protective coating against the penetration of diffusively active gases into them, protects the proposed structure from destruction by intergranular and intergranular corrosion.

Filling the longitudinal paths with sorption material provides additional protection of the housing from rupture due to the solubility of the gas in the crystal lattice of the sorbent.

The proposed utility model is illustrated by the following description and drawings, where

Figure 1 shows the design of the proposed container;

Figure 2 is a section aa of figure 1

Figure 3 is an enlarged view of B

Figure 4 is an enlarged view;

Figure 5 shows the difference between the inner diameters d, the outer diameters D and the thicknesses δ of the walls of the paths located in the center of the cylinder.

In Fig.6 - the difference between the inner diameters d, the outer diameters D and the thicknesses δ of the walls of the paths located in the middle of the radius inside the body of the container.

7 shows the difference between the inner diameters d, the outer diameters D and the thicknesses δ of the walls of the paths located at the periphery from the center of the balloon.

The high-pressure cylinder consists of a housing 1, in the lower part of which a bottom 2 is made, and in the neck 3 a gas inlet 4 is installed, an internal sealing shell of metal (liner) coaxially placed therein.

The liner is made in the form of longitudinal paths 5, which can be used tubes and / or capillaries, rigidly connected to each other, for example, by diffusion welding.

Some ends of the 6 paths are hermetically fixed to the bottom 2 of the housing, and the other open ends 7 are connected to the gas inlet 4. The gas inlet is connected to

the ends of the ends of 7 tracts by grinding or grinding.

The liner is rigidly connected to the housing 1, for example, by diffusion welding. In this case, the housing 1, in the case of using a cylinder for storage or transportation of ionized gases with a small atomic radius, can be made of metal.

The enlarged sections of the cross-section aa of the balloon in FIG. 5, FIG. 6, FIG. 7 show the difference between the inner diameters d, the outer diameters D and the thicknesses δ of the walls of the paths located at different distances from the center of the balloon.

From the center to the periphery, the tracts are arranged so that their inner diameter decreases monotonously.

This means that the inner diameter of the peripheral path located near the inner wall of the housing is smaller than the inner diameter of the path located in the center of the cylinder, and all intermediate paths located at the same radius from the central path to the peripheral one have a monotonously decreasing inner diameter from the center.

The selected ratio has been experimentally confirmed at cylinder pressures up to 1500 MPa.

The liner has a zone 8 adjacent to the inner wall of the housing, the width of which is from 1/5 to 1/20 of the outer diameter of the cylinder and in which the inner diameter of the paths decreases from the center to the periphery, and the wall thickness increases according to the formula δ5> 1 / 3D.

In practice, it is proved that only the selected values of the width of the zone allow you to create the design of the cylinder with the specified technical properties.

Zone 8 carries the main radial stresses, preventing the cylinder body from destruction.

The regularity of reducing the internal diameter of the tract and its wall thickness from the center to the periphery is maintained "when making the neck

vessels, while the form of tracts 5 and inter-channel 9 takes on a bottle shape.

In the proposed design, the housing, the external and internal surfaces of the paths can be provided with a coating 10 that protects them from diffusion-active gases.

In the proposed utility model, sorbent material 11 located in the channels of the tracts 5, as well as in inter-channel channels 9 can also be used.

Filling the proposed high-pressure cylinder is as follows:

Previously, before compressing the gas into a cylinder, it is subjected to evacuation (up to lO ^-2 top), then gas is pumped and the cylinder is sealed with a shut-off valve 12.

The gas injected into the cylinder is placed in the channels of the tracts 5 and inter-channel channels 9. If the design of the cylinder involves the use of a sorbent, in this case the gas injected into the vessel is placed in the sorbent.

In the case of filling the channels of paths and intertract channels with a sorbent, the introduction of the sorbent into the channels is carried out after their evacuation. The sorbent is introduced into the channels once before the first gas filling.

The open ends of the tracts 7, as well as inter-channel channels 9 of the liner are connected to the gas inlet 4, which ensures the flow of gas from the liner to the gas inlet and then, when the valve 12 is open, the gas exits through the opening 13.

Experiments were conducted and the results showed that the proposed design of the cylinder allows you to get the maximum ratio of the weight of high-density gas to the weight of the cylinder for gas pressure (helium, hydrogen) up to 1500 MPA equal to four to one for the volume of the balloon not more than 500 cm ³ .

Claims (6)

1. A high-pressure cylinder, consisting of a body, in the lower part of which the bottom is made, and a gas inlet is installed in the throat, an internal sealing shell of metal (liner) coaxially placed in it, the shell being connected to the gas inlet, characterized in that the liner is rigidly connected to the casing and is made in the form of longitudinal paths rigidly connected to each other, while some ends of the paths are hermetically fixed to the bottom of the casing, and the other are connected to the gas inlet, and the inner diameter of the paths monotonously decreases from the center to the periphery and, as the wall thickness increases. 2. The cylinder according to claim 1, characterized in that the liner has a zone adjacent to the inner wall of the housing, the size of which is equal to from 1/5 to 1/20 of the outer diameter of the cylinder and in which the inner diameter of the paths decreases from the center to the periphery, and the thickness walls increases by the formula: δ> 1/3 · D, where D is the outer diameter of the tract; δ is the thickness of the wall of the tract with an elastic limit of the liner material of at least 200 kg / mm ² . 3. The cylinder according to claim 1, characterized in that the housing is made of metal. 4. The cylinder according to claim 4, characterized in that the paths are made in the form of tubes and / or capillaries. 5. Cylinder according to claims 1 and 4, characterized in that the casing, the external and internal surfaces of the paths are provided with a coating against the penetration of diffusion-active gases into them. 6. The cylinder according to claim 1, characterized in that the channel channels and inter-channel channels are filled with sorption material.