CZ303594B6 - Thermally insulated tank for the accumulation of thermal energy of the liquid heat transfer medium - Google Patents

Abstract

In the present invention, there is disclosed a thermally insulated tank (1) consisting of an internal reservoir (3) made of plastic sheet and arranged inside a peripheral jacket (4) with a floor (5) and a lid (12), and comprising at least one inflatable chamber (6) with a gas charge (7), at least one internal supporting jacket (8) arranged between the chambers (6) and the internal reservoir (3), and means for controlling pressure of the gas charge (7) in the chamber(s) (6). In preferred embodiment the thermally insulated tank (1) comprises an assembly of inflatable chambers (6), wherein the gas charge (7) of the chambers (6) has at a given height level the same or higher pressure if compared with hydrostatic pressure of the liquid heat-transfer fluid (2) at a given height level of the internal reservoir (3). The thermally insulated tank (1) of the present invention can be made as both elevated structure and underground structure whereby large-volume underground thermally insulated tanks (1) can be buried in considerable depth.

Description

Thermally insulated tank for accumulation of thermal energy of liquid heat transfer medium

Technical field

The invention relates to a thermally insulated tank for storing thermal energy of a liquid heat transfer medium. The construction is designed especially for tanks of larger volumes executed as separate underground or aboveground structures.

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BACKGROUND OF THE INVENTION

A number of solutions for small-scale storage tanks suitable for indoor installation are known. In particular, there are storage tanks for electric or gas hot water heaters which, in addition to the insulation and accumulation function, also have a heating function, i.e. a water heater. that they are provided with a heat source. The design of the tanks is usually double-shell, with thermal insulation placed in the enclosure space. These structures are unsuitable for outdoor use in tanks of larger sizes because of the rapid corrosion of sheet metal shells and the necessity of their strength dimensioning to large dimensions, which makes the tanks constructed in this way inexpensively resp. incapable of competing.

A common state of the art in outdoor tanks is masonry or concrete, usually underground, provided with waterproofing and thermal insulation of walls and floors, usually of polystyrene. These tanks are satisfactory in terms of strength and storage, but the problem remains their high price, which depends on the price of building materials (concrete, masonry blocks, insulation) and a considerable range of construction work, including formwork, scaffolding, etc.

The patent CZ 228 757 discloses a tank consisting of a plastic bag resting on a layer of insulating blocks and surrounded by a cylindrical shell also made of insulating blocks. The tank is provided with a flat cap which is in the collar of the plastic bag. From above, the tank is covered with lightweight thermal insulation mats. The plastic bag takes its final shape only after it has been filled with heat transfer medium, and fits against the insulating block shell. The tank is designed primarily for above-ground use, and the cladding of blocks is protected against the influence of hydrostatic pressure by an external light element formed by a system of steel hoops.

An alternative to the system under CZ 228757 is a tank sold under the trade names SUNPOWER and SUN SAVÉ, which differs from the solution described above only in that it uses special polystyrene fittings approximately in the shape of the letter "Z" locks for detachable connection.

Although the solutions described above represent significant improvements over a tank made by a conventional construction process, they still remain at a relatively high level of cost, while a craft construction skill is still needed for the construction of an insulating block shell.

Another disadvantage of the known construction solutions, especially in the underground reservoirs of larger volumes, is that they need very massive construction foundations which must eliminate subsoil movements due to thermal differences, frost, etc. These massive foundations significantly increase the cost of the entire construction of the reservoir.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to further improve tanks based on an assembly of an inner plastic bag or plastic tub and an outer backing and heat insulated floor to provide a solution that overcomes the drawbacks of the known solutions described above. the needs of professional construction professions, and would also be suitable and affordable for large-scale and large-volume tanks where there would be no need for a robust and deep foundation.

- 1 GB 303594 B6

SUMMARY OF THE INVENTION

This is achieved by constructing a thermally insulated tank according to the present invention.

The container consists in a known manner of an inner reservoir of plastic foil disposed within the peripheral shell with the floor and the lid, the principle being that the outer shell and / or the floor and / or the lid comprises at least one inflatable gas-filled chamber, at least one inner a support shell disposed between the chambers and the inner reservoir, and means for controlling the filling pressure in the chamber.

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In a preferred embodiment of the tank according to the invention, the cladding and the floor comprise a plurality of inflatable chambers, wherein the floor chamber filling has a higher pressure than the chamber filling in the cladding. The chambers at a given height level are always pressurized to a higher pressure than the hydrostatic pressure of the heat transfer medium at a given height level. A further advantageous embodiment is that the inner reservoir and the inner backing are adjacent to each other with the possibility of sliding relative to one another, and the considerable advantage of the tank according to the invention is that chambers can also move during the movement of the subsoil. and the position of the ground or rock below the tank, and at the same time the movement of the chambers is not transmitted to the inner reservoir. Ultimately, this solution also allows the construction of relatively large tanks, essentially without foundation.

The inner backing is preferably a fiberglass-based mat that is sufficiently strong yet light, non-corrosive and adapts to the uneven surface of the chamber assemblies in the cladding or the floor, or may be formed of another static support material.

In one variant of the preferred construction, the tank is formed as an above-ground cylindrical structure, wherein the inner reservoir, inner support cladding, cladding and floor have a circular cross-section, and the outer wall of the cladding is formed by a cylindrical outer support cladding based on glass fibers or in the case of smaller loads, ie smaller tank sizes, it is sufficient if it is made of sheet metal. The inner support shell is provided with a fiber reinforcement forming a statically supporting reinforcement grid.

In a second variant of the preferred construction, the tank is designed as a substantially conical ground structure which is arranged in the ground or underground, wherein at least one waterproofing layer is arranged between the skirt and the ground to separate the chamber or chamber assembly from the surrounding subsoil penetration of moisture and ground water into the tank. In a preferred embodiment, the waterproofing layer supplemented with a reinforcing layer is arranged between at least one, two or more clay layers, which act as a protection against both groundwater and water leakage in case of leakage, puncture and the like.

The chamber assemblies may have different forms and configurations, but it is preferable for the manufacture and tightness of the chambers that the chambers consist of cylindrical bodies arranged in at least two layers both in the floor area and in the area of the cladding. This arrangement is also advantageous in terms of statics and the transmission and distribution of the load transmitted from the inner reservoir. Since voids are formed between the cylindrical chambers, it is preferable that these chambers between the chambers are filled at least in the floor area with a filler, for example of polyurethane or other suitable material, or cylindrical or other smaller chambers of smaller shape filling the gap.

From the standpoint of chamber composition and compactness of the embodiment, another embodiment is preferred, wherein the chambers consist of cuboid bodies arranged in at least two layers both in the floor area and in the area of the cladding. The chambers as such are made of plastic-based materials (foils) which, by their composition, ensure airtightness when painting to the surface and their periphery or part of the outer side of the inner backing consists of reinforcing glass, polyester, basalt or other fabric. fiber reinforcement, which ensures the transmission and distribution of compressed air forces to prevent the chamber from bursting. The chambers cannot be infinitely drawn by internal gas pressure, but their maximum volume is given by the maximum circumference of the fabric sheath in section.

Regardless of the selected shape and size of the chambers in the layers, it is advantageous if an interleaving mat is placed between the individual chambers of the chambers, allowing an even better distribution of the load and the transmission of forces.

Finally, it is preferred that the means for controlling the filling pressure in the chambers comprises a pressure source to which a manifold is connected with at least two pressure control valves connected to at least two pressure distributors from which lines connected via check valves exit into the individual chambers. Thus, each pressure distributor can be adjusted to a different pressure value by means of a pressure reducing valve, and the chambers at the respective more exposed points of the assembly can, for example, be pressurized to a greater value than the chambers subjected to less load.

The advantages of the thermal insulating tank according to the invention are that it is suitable for the construction of over 15 ground and in particular underground tanks of large volumes without the need to build a massive building foundation. The reservoir is a low-cost and easy-to-implement solution that can be built without the need for professional construction professions and is able to provide the required thermal insulation and waterproofing parameters in the long term.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view of a conical underground tank with cylindrical chambers and a lid formed with a chamber housing; FIG. Fig. 3 is a cross-sectional view of the placement of a waterproofing and reinforcing layer between two clay layers; Fig. 4 is a horizontal cross-section of an overhead cylindrical tank; Fig. 5 is a schematic representation of the distribution of pressure into chambers from pressure distributors.

DETAILED DESCRIPTION OF THE INVENTION

It is to be understood that the specific embodiments of the invention described and illustrated below are presented by way of illustration and not by way of limitation of the examples to the examples.

Those skilled in the art will find, or will be able to ascertain, using routine experimentation, more or less equivalents to specific embodiments of the invention specifically described herein. These equivalents will also be included within the scope of the following claims.

1 to 3 show examples of the implementation of underground reservoirs J with different design variants.

In Fig. 1, the underground tank I is of approximately conical shape. The cladding 4 and the floor 5 are separated from the ground 10 in the trench by a waterproofing layer 11 formed by a building waterproofing membrane.

The upper part of the tank J is covered by a lid 12 formed by a light box 23. The cladding 4 is connected to the floor 5 and is in the shape of a wide open letter "U" in section. The floor 5 consists of two superimposed layers of inflatable cylindrical chambers 6 of plastic film, the peripheral shell 4 is composed of three layers of inflatable cylindrical chambers 6. Also, the housing 23 forming the lid 12 is filled with cylindrical chambers 6 arranged in three layers. The chambers 6 are filled with air, whereby the floor chamber chamber load 7 has a higher pressure than the chamber chamber pack 7 in the envelope 4. The pressures in the chamber 6 are kept constant by the means shown in Fig. 5 and will be described below, the pressure at each height level is higher than the hydrostatic pressure of the heat transfer medium 2. A glass fiber interleaving tank 15 is disposed between the individual layers of the chambers 6 in the area of the floor 5 and in the area of the envelope 4. The floor mat 15 is also disposed between the bottom layer of the chambers 6 in the floor 5 and the waterproofing layer 11. In the region of FIG.

In the space between the cylindrical chambers 6, a filler 22 formed of expandable polyurethane foam is arranged. The filler 22 serves to reinforce the floor 5 and increase its load-bearing capacity. The actual space of the tank 1 for the storage of the heat transfer medium 2 defines an inner supporting casing 8, in which the inner reservoir 3 formed by a bag or a tub of multilayer plastic foil is inserted. The inner backing 8 of the fiberglass-based mat adapts its shape flexibly to the edges of the chambers 6, the inner reservoir 3 is shaped in the same way. The inner reservoir 3 and the inner backing 8 are adjacent to each other with the possibility of sliding relative to each other. Upper Parts.

FIG. 2 also shows an underground tank I of substantially stepped conical shape, as opposed to FIG. 1, except that the chambers 6 are cuboid-shaped bodies arranged in three layers in the area of the floor 5 and stairly constructed in the area of the envelope. 6 are separated by partitions inside the larger inflatable body. Here, too, an interleaving mat 15 can be arranged between the individual layers of the chambers 6, but this is not shown in FIG. Another difference is that the lid 12 is a lightweight compact plate 24 formed by a frame with a polystyrene filling.

Fig. 3 shows an improved embodiment of the waterproofing layer 11, which can be used for both the tank 1 shown in Fig. 1 and the tank 1 shown in Fig. 2 and other types of underground tanks. The waterproofing layer 11 is supported by a reinforcing layer 13, and both are placed between two clay layers 14, which serve as a safety envelope preventing both the penetration of groundwater and the leakage of the heat transfer medium 2 in the event of an internal reservoir 3 defect. extends around the entire tank 1 both in the area of the floor 5 and in the area of the cladding 4.

FIG. 4 shows another embodiment of the tank I, wherein the tank f is constructed as a cylindrical above-ground structure, wherein the inner reservoir 3, the inner abutment 8, the outer skirt 4 and the floor 5 have a circular cross-section, and the outer wall of the outer skirt 4 is The floor 5 and the lid 12 can in this embodiment be formed of conventional insulating materials, for example based on polystyrene, and only the peripheral sheath 4 consists of a plurality of layers of cylindrical chambers 6 with an air filling 7 connected to the device. The above-ground tank I according to this embodiment is provided with an outer supporting sheath 9, which forms the envelope of the chambers 6 and keeps the tank I whole. It is a cylindrical strip of fiberglass-based glass fiber mats or surface-treated sheet metal, which in a circular cross-section eliminates opposite hydrostatic forces acting on the tank I from the heat transfer medium 2 in the inner reservoir 3. The inner reservoir 3 is similar to the underground reservoirs 1 It consists of a multilayer plastic foil tubing and is mounted in an inner backing sheath 8 of glass-fiber mat which forms a support for the inner reservoir 3 and transfers the load further to the peripheral sheath 4.

FIG. 5 shows a means for controlling the pressure of the charge 7 in the chambers 6, which comprises a pressure source 16 consisting of a conventional compressor from which compressed air is supplied to a manifold 17 and subsequently to three pressure reducing valves 18. These are mounted at the inlets of the three pressure distributors 19 forming preferably one compact body, each pressure distributor 19 being separate and in each of which a different operating pressure value is set by means of the pressure reducing valve 18. Each pressure manifold 19 is also provided with a plurality of outlets to which conduits 20 connected via check valves 21 are connected to individual chambers 6. The design of the check valves 21 and their location in the chambers 6 may vary depending on the design of the chambers 6 and their spatial arrangement. The arrangement of the lines 20 is also made according to the spatial disposition of the tank 1, but the lines 20 exiting the pressure manifold 19 with higher pressure are supplied to the higher pressure chamber chambers 6 arranged in an area exposed to greater pressure exposure. The control of the constant pressure level of the charge 7 in the chambers 6 takes place automatically by switching the compressor 16 according to the pressure drop in the pressure distributors 19 as the pressure is supplied to the chambers 6.

-4GB 303594 B6

Industrial applicability

The thermally insulated tank for storing the thermal energy of the liquid heat transfer medium according to the invention is particularly useful as a larger tank designed as a separate underground or above-ground structure and intended in particular for the accumulation of heated water from solar systems or other heating devices.

Claims (13)

15 1. A thermally insulated tank (1) for storing thermal energy of a liquid heat transfer medium (2), consisting of an inner reservoir (3) of plastic foil disposed within a peripheral shell (4) with a floor (5) and a lid (12), characterized in that the peripheral shell (4) and / or the floor (5) and / or the cover (12) comprises at least one inflatable chamber (6) with a gaseous charge (7), at least one inner support shell (8) arranged between the chambers ( 6) and an internal reservoir 20 (3), and means for controlling the pressure of the charge (7) in the chamber (6). Thermally insulated tank according to claim 1, characterized in that the skirt (4) and the floor (5) comprise an assembly of inflatable chambers (6), wherein the filling (7) of the chambers (6) in the floor (5) and the filling (7) the chambers in the cladding (4) at a given height level are equal to or higher 25 above the hydrostatic pressure of the liquid medium (2) at a given height level of the inner reservoir (3). Thermally insulated tank according to claim 1, characterized in that the inner reservoir (3) and the inner opaque jacket (8) abut one another with the possibility of sliding relative to one another. Thermally insulated tank according to claim 1 or 2, characterized in that the inner abutment (8) is made of a fiberglass-based mat or of another statically supporting material, Thermally insulated tank according to one of Claims 1 to 4, characterized in that 35 is constructed as an above-ground cylindrical structure, wherein the inner reservoir (3), the inner opaque jacket (8), the peripheral jacket (4) and the floor (5) have a circular cross-section, and the outer wall of the peripheral shell (4) is formed by a cylindrical outer abutment shell (9), at least the outer side of the inner abutment shell (8) or chambers (6) comprising a fiber reinforcement forming a static supporting reinforcement grid. Thermally insulated tank according to claim 5, characterized in that the outer opaque jacket (9) is made of a glass fiber mat or of sheet metal. Thermally insulated tank according to one of Claims 1 to 4, characterized in that the 45 is constructed as an earth cone of substantially conical shape, arranged in the ground or underground, at least one of which is arranged between the skirt (4) and the ground (10). a waterproofing layer (11). Thermally insulated tank according to claim 7, characterized in that at least one reinforcing layer (13) and at least one clay layer (14) are arranged together with the waterproofing layer (11) between the skirt (4) and the ground (10). . Thermally insulated tank according to one of Claims 2 to 8, characterized in that the chambers (6) are formed by cylindrical bodies arranged in at least two layers both in the region 55 of the floor (5) and in the area of the skirt (4). - 5 GB 303594 B6 Thermally insulated tank according to claim 9, characterized in that the spaces between the chambers are filled at least in the area of the floor (5) with a filling (22). 5 Thermally insulated tank according to one of Claims 2 to 8, characterized in that the chambers (6) are formed by cuboid bodies arranged in at least two layers both in the area of the floor (5) and in the area of the envelope (4). Thermally insulated tank according to claim 9, 10 or 11, characterized in that an interleaving mat (15) is also arranged between the individual layers of the chambers (6). Thermally insulated tank according to one of claims 1 to 12, characterized in that the means for controlling the pressure of the charge (7) in the chambers (6) comprises a pressure source (16) to which a manifold (17) is connected with at least two pressure reducing valves ( 18) connected to at least two 15 m and pressure distributors (19), from which ducts (20) connected via check valves (21) extend to individual chambers (6).