SK277948B6 - Gas holder - Google Patents

Abstract

Gas holder (1) contains minimum two flexible blowing up, mainly impermeable balloon segments from flexible material created as at least one internal membrane (3, 3') with internal space (5) for storage of gas and external membrane (2) where in space between them is created the pressure regulating chamber (4,4') filled with auxiliary gas, at which the lower edges (9,8) of internal and external membrane (3,3' and 2) are fixed to base (12), in its middle part, where in base (12) the leading and draining piping (7, 6) of storage gas is located. On top of external membrane (2) is in its wall created the leading opening (33) of lead of auxiliary gas, connected by hose (32) with blower (31), which is located on extension (30) of base (12), in which the lower edges (9,.8) of internal and external membrane (3, 3' and 2) are fixed, mutually separated with radial distance by metallic plate (15) and sealed with floor membrane (20). On top of external membrane (2) is fixed the measuring element (25) for measuring of gas contents. In leading and draining piping (7, 6) the safety valve (28) for protecting of gas holder anti pressure above atmospheric is located.

Description

Technical field

The invention relates to a gas tank having at least two flexible inflatable, in particular impermeable balloon parts of a flexible material, such as a plastic or rubber foil or a textile backing provided with a plastic or rubber coating, for example a polyester fabric with a polyvinyl chloride coating. a pressure regulating chamber filled with auxiliary gas is formed in the space between them, and wherein the lower edges of the inner and outer diaphragms are fixed to the base of the gas tank in which the gas supply and discharge lines are located. In the context of biogas production, the importance of relatively small-capacity gas tanks associated with gas generators and appliances is also increasingly important, allowing gas retention, storage and supply in cases where gas production and consumption take place at different times. .

BACKGROUND OF THE INVENTION

Balloon containers made of cylindrical or spherical segments, in particular of plastic fiber fabrics coated with plastic coating, are used as gas tanks. Further known are storage bags of the same material, stacked and connected to each other, in which gas is stored under the influence of an external load by means of a weight.

In simple balloon containers without a load by the weight, the gas pressure for most appliances cannot be kept within a sufficiently narrow tolerance range regardless of the respective filling condition of the container. In the container bags loaded with a weight, the gas pressure inside the container can be maintained, with the volume of the container changing, at approximately constant height by means of a larger or smaller weight. There is a substantial cost for the necessary load device, which usually comprises a platform with a weight with a vertical parallel guide. In low-pressure gas containers, the gas pressure should normally be 10 to 50 mbar, so the loading of the container bags per m ^{2 of} horizontal surface shall be 100 to 500 kg. The gas pressure in these containers, while standing in the open air, is further strongly influenced by external forces, such as wind pressure or snow load.

Attempts have therefore been made to produce a gas tank at the lowest cost, from which gas at approximately constant pressure could be drawn, and its operation would be little affected by external forces. As is known, the transient solution is a gas tank in which an outer flexible inflatable balloon package and at least one flexible inflatable balloon membrane are formed within the outer shell, which divides the inner space of the outer shell into a pressure regulating chamber lying between the outer shell and a membrane filled with auxiliary gas, in particular air, and at least one gas storage space to which the gas storage supply and discharge lines are connected. In the operation of this gas tank, an auxiliary gas, most often air, is injected into the pressure control chamber through an inlet located at the bottom of the chamber until a predetermined desired pressure is reached and the diaphragm transmits this pressure to the gas which is in storage. By means of the positive pressure in the pressure control chamber, the stable shape of the outer casing of the gas tank can be maintained over a wide range, so that the wind pressure or the pressure drop can be maintained. also, the snow has no significant effect on the gas pressure in the storage area. In this case, both the balloon outer envelope and the balloon diaphragm are open downwardly and the edges of their open walls are fixed to the base plate by means of common clamping means between which a gasket is inserted.

Even if a gas tank has already been created which is well usable in practice, there may nevertheless be difficulties because the outer casing or the container can be used. the outer diaphragm is fixed together with their lower edges to the base, and in the lower part of said pressure chamber there is an inlet and, in particular, an auxiliary gas outlet. By contacting the inner diaphragm on the outer diaphragm in its lower part, this auxiliary gas connection point may be closed, which may prevent the inlet of the auxiliary gas in particular. In addition, contact of the membranes while inflating them can result in a strong frictional contact between the outer and inner membranes, which can not only prevent the passage to its final shape, but also cause extra stress on the membrane material.

SUMMARY OF THE INVENTION

These drawbacks are largely eliminated by a gas tank with two flexible inflatable, in particular impermeable, balloon pieces, of a flexible material, for example a plastic or rubber foil or a textile backing provided with a plastic or rubber coating, for example a polyester fabric with a polyvinyl chloride coating, a diaphragm with an inner gas storage space and an outer diaphragm, wherein a pressure control chamber filled with auxiliary gas is formed in the space between them, and wherein the lower edges of the inner and outer diaphragms are fixed to the gas tank base in which the gas storage supply and discharge lines are located; According to the invention, the principle is that at the top of the outer diaphragm is formed in its wall an inlet opening of the auxiliary gas supply, where the lower edges of the inner and outer diaphragms are fixed to each other separately with radial r ozstupom.

The inlet and outlet pipes exit into the interior and are located in the central part of the foundation, which is provided with a floor membrane to seal the interior and the pressure control chamber against the base, where the floor membrane is made of plastic or rubber foil or textile backing with plastic or rubber a coating, in particular a polyester fabric with a polyvinyl chloride coating.

The inner diaphragm has a hollow cylindrical shape at its bottom, which passes into the spherical section at the top.

The inner membrane is formed by the interwoven inner plastic woven fabric segments and the outer membrane is formed by the interwoven outer plastic fabric woven segments, the welds extending from the top of the inner and outer membranes to the base to which the lower edges of the inner and outer membranes are fixed and sealed by metal

276 boards anchored to the foundation.

The lower edge of the inner diaphragm is fixed to the metal plate by cross-sectional clamping bars U which are fixed to the base by anchor bolts glazed into anchors formed in the base and the lower edge of the outer diaphragm is fixed to the metal plate by flat bars shaped to the curvature of the outer diaphragm, welded to the metal plate, the lower edge of the outer membrane being tightly fixed between the flat bars and the metal strips by clamping screws glazed in the flat bars.

A measuring member is mounted at the top of the outer membrane to measure and control the amount of gas content in the inner membrane and to measure the instantaneous distance of the inner membrane from the outer membrane.

The measuring member is formed by a flexible device on which a steel rope with an explosion-proof angular rotation controller is wound.

A pressure relief valve with a liquid pattern is located in the discharge line and in the supply line.

The outer membrane is provided with heating at its bottom. The heating consists of an electric heating, in particular an electric heating coil or electric heating foil, wherein the heating is located on the inner surface of the outer membrane.

In an alternative embodiment, the electric heating is located on the inner surface of the outer membrane by means of a carrier additional membrane mounted on the inner surface of the outer membrane.

In another embodiment, the heating is formed by hot-air heating.

The outer membrane is at least in its upper part covered by a support structure disposed on the basis of which a space is formed between and the outer membrane in which a hollow cone is located to cover the outer membrane, which is fixed to the support structure.

The position of the auxiliary gas inlet opening and the re-arrangement of the shape, resp. the size of the membranes largely prevents said closure of the auxiliary gas connection point. In this way, the inlet and outlet of the auxiliary gas is fully ensured. Also, a high friction stress between the membranes is eliminated, so that additional freedom in the choice of material is created. Thus, the gas chamber can absorb the same stresses as the outer diaphragm, which can represent an extraordinary safety factor. The separate attachment of the lower edges of the membranes according to the invention has the further advantage that the inner membrane can be mounted on the foundation before the outer membrane is fixed, and therefore the attachment points of the inner membrane are easily accessible and well controlled. The central opening of the inlet and outlet ducts from the foundation to the interior largely prevents lateral deformation of the inner membrane, which also counteracts the frictional contact of the membranes. The angular rotation controller transmits the instantaneous distance of the inner diaphragm further to the control room as an electrical value. The angular rotation converter is mounted on the shaft to which the steel wire is wound or pulled. from which it is unwound. The instantaneous height of the top of the inner diaphragm, and hence the gas tank content, is transmitted from the angular rotation controller. The pressure relief valve is connected to the gas tank in an irreversible manner and serves to remove excess gas and thereby protect the outer diaphragm from overpressure. The heating provided at the top of the outer diaphragm, for example at about one third of its total height, serves to prevent the gas tank from overloading even under heavy snowfall. A hollow cover cone which covers the upper part of the outer membrane, for example in about one third of its total height, provides not only protection against snow but also, in certain circumstances, protection of the gas tank against wind.

Overview of the figures in the drawing

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a partial cross-sectional side view of the gas tank and FIG. 2, in FIG. 1 is indicated by a broken line design with an inner membrane, the bottom of which is designed as a hollow cylinder. The left part of FIG. 1 is a cross-sectional view along line I-I of FIG. 2, left part of FIG. 2 shows the gas tank in plan view after removing the inner and outer membranes. Fig. 3 shows an overpressure relief valve that is connected or connected to a pressure relief valve. connected to the inlet and outlet pipes. Fig. 4 and 5 show a measuring member for measuring the gas content of a gas tank. Fig. 6 is a partial plan view and FIG. 7 to 9 are cross-sectional details of the attachment of the outer and inner diaphragms to the foundation. FIG. Figure 7 is an enlarged cross-sectional view of A-A; 8 shows section B-B and FIG. 9 is a section along line C-C of FIG. 6. In FIG. 10 shows variants of an embodiment with devices for protecting the gas tank against the high load of the outer membrane, in particular by heavy snow.

DETAILED DESCRIPTION OF THE INVENTION

The gas tank 1 by the pressure according to FIG. 1, 2 and 10 comprise at least two inflatable, in particular impermeable, balloon panels of a flexible material, such as plastic or rubber foil or a textile backing provided with a plastic or rubber coating, for example a polyester fabric with a polyvinyl chloride coating, which are formed as at least one an inner diaphragm 3, 3 'with an internal gas storage space 5 and an outer diaphragm 2, wherein a pressure control chamber 4, 4' is formed in the space between them, filled with auxiliary gas, the lower edges 9, 8 of the inner and outer diaphragms 3, 2 being fastened to the base 12 in which the inlet and outlet pipes 7, 6 of the stored gas are located. At the top of the outer diaphragm 2, an auxiliary gas supply opening 33 is formed in its wall, the lower edges 9,8 of the inner and outer diaphragms being fixed to the base 12 separately from each other with radial spacing.

The inlet and outlet ducts 7,8 extend into the interior gas storage space S and are located in the central part of the base 12 which is provided with a floor membrane 20 to seal the interior space 5 and the pressure control chamber 4, 4 'against the base 12 where the floor membrane 20 is formed from a plastic or rubber foil or a textile backing with a plastic or rubber coating, in particular a polyester fabric with a polyvinyl chloride coating. The inner diaphragm 3 'of the special embodiment has in its lower part the shape of a hollow cylinder, which passes in the upper part into a spherical section.

The inner membrane 3, 3 'is formed by mutually welded inner plastic segments 21, made mainly of a plastic coated fabric, and the outer membrane 2 is also formed by mutually welded but outer plastic segments 22 made of the same fabric, the welds extending from the top of the inner and the outer membranes 3,3 'and 2 to the base 12, to which the lower edges 9,8 of the inner and outer membranes 3, 2 are fixed detachably and sealed by means of a metal plate 1 anchored to the base 12.

The lower edge 9 of the inner diaphragm 3 is fixed to the metal plate 15 by means of a clamping ring 10 and clamping bars 14 of a cross-section U between which it is clamped, the metal plate 15 and clamping bars 14 being fixed to the base 12 by anchor jigs 18 and anchor bolts 17 '. The lower edge 8 of the outer diaphragm 2 is fixed to the metal plate 15 by a clamping fixture 11 consisting of metal strips 13 and flat bars 19 adapted to the curvature of the outer diaphragm 2, wherein the flat bars 19 are welded perpendicular to the a metal plate 15, which is further welded to the base 12 by anchoring means 16, the lower edge 8 of the outer membrane being tightly fixed between the flat bars 19 and the metal strips 13 by clamping screws 13 'screwed in the flat bars 19. 3 'is further clamped between the clamping bar 14 and the metal plate 15, which further serves to tightly clamp or clamp the metal plate 15. clamping the floor membrane 20. To improve the sealing of the outer and inner membranes 2, 3 against the flat bars 19, respectively. For the metal plate 15, additional external and internal sealing strips 23 and 24 are used.

Mounted at the top of the outer membrane 2 is a measuring member 25 for measuring and controlling the amount of gas content in the inner membrane 3, 3 'and for measuring the instantaneous distance of the inner membrane from the outer membrane 2. The measuring member 25 is formed by a resilient device 26. a rope 27 with an explosion-proof angular rotation transducer which transfers the instantaneous distance of the inner diaphragm 3, 3 'from the outer diaphragm 2 as an electrical value to the control room. An angular rotation converter is provided on the shaft of the resilient device 26.

To protect the inner diaphragm 3,3 'resp. The overpressure relief valve 28 is provided in the gas supply and discharge piping 7, 6 of the outer gas diaphragm 2 with a liquid, in particular a water draft, which is inextricably connected to the gas tank 1 and serves to drain the excess gas. The liquid template provides an overload protection due to pressure build-up, is frost-insensitive and has no wear parts.

The gas tank 1 is additionally suitably provided with a water conduit 29 for draining the resulting condensate.

Air is generally used as the auxiliary gas. The air supply is provided by an air blower 31 located on the base extension 30 and connected by a hose 32 to an inlet opening 33.

The outer membrane 2 is preferably provided with heating in its upper part. The heating is formed by an electric heating 34, in particular an electric heating coil 35 or an electric heating foil disposed on the inner surface of the outer membrane 2. The electric heating 34 is in one embodiment placed on the inner surface of the outer membrane 2. The electric heating 34 is in one of of an exemplary embodiment positioned on the inner surface of the outer membrane by means of an additional membrane 36 mounted on the inner surface of the outer membrane. In another embodiment, the heating is formed by hot-air heating.

In a further embodiment, the outer membrane 2 is at least in its upper part covered by a supporting structure 37 positioned on the basis of 12, between which and the outer membrane 2 is formed a space in which a hollow cover cone 38 is located to cover the outer membrane 2 The supporting structure 37 may be formed as a tripod.

Clamping rings, respectively. the fixtures 10, 11, the metal strips 13, the clamping strips 14, the flat bars 19 can also be formed from segments that are welded in the region of the cutting plane C-C.

The position of the auxiliary gas inlet 33 and the new arrangement of the inner and outer membranes 3,3 'and 2 reliably prevent the auxiliary gas connection point from closing and thus fully ensure its inlet and outlet. There is also no significant stress due to frictional contact between the inner and outer membranes 3, 3 'and 2. Separately fastening the lower edges 9, 8 of the inner and outer membranes 3, 3' and 2 has the advantage that the inner membrane 3, 3 'can be mounted on base 12 prior to the attachment of the outer membrane 2, and therefore the attachment points of the inner membrane are readily accessible and controllable. The central inlet and outlet piping 7.6 from the base 12 into the interior 5 prevents lateral deformation of the inner and outer diaphragms 3,3 'and 2. By arrangement of the membranes and the supply and storage gas supply, the inner diaphragm 3, 3' has a smaller outer dimension as the outer membrane 2, and thus there is no direct contact between their walls.

The instantaneous height of the top of the inner diaphragm 3 'from the outer diaphragm 2, and hence the gas reservoir content, in the form of an electrical value, is transmitted from the angular rotation controller to the control room. The heating provided on the upper part of the outer diaphragm 2, for example in about one third of its total height, serves to prevent the gas tank 1 from being overloaded by snow even under heavy snowfall. The hollow cover cone 38, which covers the upper part of the outer membrane 2, for example at about one third of its total height, provides not only snow protection but also protection of the gas tank 1 against wind pressure.

Claims (13)

PATENT CLAIMS Gas tank having at least two flexible inflatable, in particular impermeable balloon pieces, of a flexible material, for example of plastic or rubber foil or of a textile backing provided with a plastic or rubber coating, for example of polyester fabric with a polyvinyl chloride coating, a gas storage space and an outer diaphragm, in which a pressure control chamber filled with auxiliary gas is formed in the space between them, and wherein the lower edges of the inner and outer diaphragms are fixed to the base of the gas tank in which A storage gas supply and discharge pipeline, characterized in that at the top of the outer diaphragm (2) an auxiliary gas inlet opening (33) is formed in the wall thereof, wherein the lower edges (9, 8) of the inner and outer diaphragms (2) 3, 2) are attached to the base (12) separately from each other with a radial spacing. Gas tank according to claim 1, characterized in that the inlet and outlet ducts (7,6) exit into the interior space (5) and are located in the central part of the base (12) provided with a floor membrane (20) for sealing the interior space (5) and the pressure control chamber (4) against the base (12), wherein the floor membrane (20) is formed from a plastic or rubber foil or a textile backing with a plastic or rubber coating, in particular a polyester fabric with polyvinyl chloride coating. Gas reservoir according to claim 1 or 2, characterized in that the inner membrane (3) has in its lower part a hollow cylinder shape which passes at the top into a spherical section. Gas tank according to one of Claims 1 to 3, characterized in that the inner membrane (3) is formed by welded inner plastic segments (21) provided with a fabric and the outer membrane (2) is formed by mutually welded outer plastic segments (22) provided with a fabric, the welds extend from the top of the inner and outer diaphragms (3,2) to the base (12), to which the lower edges (9, 8) of the inner and outer diaphragms (3,2) are fixed detachably and sealed by a metal plate (15) anchored to base (12). Gas tank according to claim 4, characterized in that the lower edge (9) of the inner membrane (3) is fastened to the metal plate (15) by cross-sectional clamping strips (14) which are fastened to the base (12) by anchor shortcuts. (17 *) screwed into the anchors (17) formed in the base (12) and the lower edge (8) of the outer membrane (2) is fixed to the metal plate (15) by flat rods (19) adapted to the curvature of the outer membrane (2) the flat bars (19) are perpendicularly welded to the metal plate (15), the lower edge (8) of the outer membrane (2) being tightly fixed between the flat bars (19) and the metal strips (13) by clamping shortcuts (13) screwed into the flat bars (19). Gas tank according to claims 1 to 5, characterized in that a measuring member (25) is mounted on the top of the outer membrane (2) for measuring and controlling the amount of gas content in the inner membrane (3) and for measuring the instantaneous distance of the inner membrane (3). ) from the outer membrane (2). Gas tank according to claim 6, characterized in that the measuring member (25) is formed by a resilient device (26) on which a steel rope (27) with an explosion-proof angular rotation device is wound. Gas tank according to one of Claims 1 to 6, characterized in that a pressure relief valve (28) with a liquid pattern is arranged in the discharge line (6) and in the supply line (7). Gas tank according to one of Claims 1 to 8, characterized in that the outer membrane (2) is provided with heating in its upper part. Gas tank according to claim 9, characterized in that the heating consists of an electric heater (34), in particular an electric heating coil (35) or an electric heating foil, located on the inner surface of the outer membrane (2). Gas tank according to claim 10, characterized in that the electric heater (34) is located on the inner surface of the outer membrane (2) by means of a carrier additional membrane (36) mounted on the inner surface of the outer membrane (2). Gas tank according to claim 9, characterized in that the heating is formed by hot-air heating. Gas tank according to claims 1 to 12, characterized in that the outer membrane (2) is at least in its upper part covered by a supporting structure (37) located on the base (12) between it and the outer membrane (2). a space in which a hollow cone (38) is located to cover the outer membrane (2), which is fixed to the support structure (37).