Thermally insulating casing for tank and tank device including such a casing
The multi-part insulating enclosure with vacuum panels and magnetic assembly addresses thermal insulation and assembly issues, offering superior performance and eco-friendly features.
Patent Information
- Authority / Receiving Office
- FR · FR
- Patent Type
- Patents
- Current Assignee / Owner
- VIESSMANN CLIMATE SOLUTIONS SE
- Filing Date
- 2024-05-28
- Publication Date
- 2026-06-05
AI Technical Summary
Existing insulating envelopes for tanks, particularly water storage tanks, suffer from insufficient thermal insulation, lack of eco-design and recycling capabilities, rigidity, and are difficult to assemble and maintain, with loose wrapping allowing air circulation by convection.
A multi-part insulating enclosure with composite side wall parts featuring vacuum insulation panels and compressible material, magnetic and mechanical assembly, and flexible cladding for enhanced thermal insulation, rigidity, and ease of assembly and disassembly.
Provides superior thermal insulation, rigidity, and ease of assembly/disassembly, while facilitating recycling and reducing air circulation, with a flexible and aesthetically customizable design.
Smart Images

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Abstract
Description
Title of the invention: Thermally insulating casing for a tank and tank device comprising such a casing
[0001] The present invention relates to the field of liquid storage tanks having external thermal insulation, added and formed by assembling several parts.
[0002] It relates to a thermally insulating envelope for such tanks and a tank device comprising such an envelope.
[0003] Many embodiments of multi-part insulating enclosure for tank, in particular for water storage tank, are already known.
[0004] These enclosures generally comprise at least two complementary side wall sections, joined together by butting their opposite lateral edges to form a hollow cylindrical body with a round, square, or other cross-section (the lateral assembly edges of the side wall sections extend along the longitudinal direction of the profiled cylindrical body). They also optionally comprise two plate-shaped bodies closing the two opposing upper and lower openings of said cylindrical body. These various elements together constitute, by mutual assembly, an insulating shell that is either open or only partially closed (in the absence of one or both of the upper and lower closing plates), or closed (when both closing plates are present), and which is intended to surround and enclose said tank.
[0005] However, these known insulating envelopes or shells, as well as the tank devices which include them, have several limitations and shortcomings and there is a demand for solutions to overcome them.
[0006] Thus, it has been noted in particular that these known insulating envelopes or shells do not provide sufficient thermal insulation in relation to expectations and new regulations (due to their constitution, the assembly of their constituent elements and their loose wrapping of the tank allowing air circulation by convection), do not fit into an eco-design or recycling approach, do not allow flexibility in terms of external appearance and do not provide a sufficiently rigid and robust shell.
[0007] Moreover, they are often tedious to assemble and disassemble (when disassembly is possible) and do not sufficiently facilitate maintenance.
[0008] The present invention aims to meet at least partially the requirements set out above and to overcome at least some of the limitations and shortcomings mentioned.
[0009] To this end, the invention relates to a multi-part insulating enclosure for a tank, in particular for a water storage tank, comprising at least two complementary side wall parts, joined together by butting their opposite lateral edges to form together a hollow cylindrical body, with a round or non-round cross-section, and, optionally, at least one plate-shaped body closing one or each of the two opposing upper and lower openings of said cylindrical body, the various aforementioned parts together constituting an insulating shell, optionally closed by at least one of the two bodies, intended to surround and enclose said tank, with the lateral assembly edges of the side wall parts extending along the longitudinal direction of the cylindrical body,
[0010] insulating envelope characterized in that each side wall part has a composite structure with a main body made of a rigid foamed or cellular material and provided with at least one cavity or recessed area at the level of the inner face of the side wall part facing the tank, and in that at least one vacuum insulating panel, extending over a portion of the surface of the side wall part concerned, is disposed in said at least one cavity or recessed area, preferably in a fitted manner, said insulating envelope also comprising at least one layer of compressible material arranged to be located at least between the main bodies of the side wall parts and the tank.
[0011] The invention will be better understood from the following description, which relates to preferred embodiments, given by way of non-limiting examples, and explained with reference to the accompanying schematic drawings, in which:
[0012] [Fig-1] is a perspective view of an insulated tank device comprising an insulating shell-like envelope according to an embodiment of the invention;
[0013] [Fig.2] is an exploded view of the tank device shown [Fig.1];
[0014] [Fig.3] is a vertical cross-sectional view along AA and an elevation view of the device reservoir of the [Fig.l];
[0015] [Fig.4] is a view similar to that of [Fig.1], a part of the side wall of the insulating shell removed;
[0016] [Fig.5] is a view of the reservoir device similar to that of [Fig.1], of the upper portions of two side wall sections being removed;
[0017] [Fig.6] is an elevation view of a portion of a side wall forming part of the insulating casing of the tank device shown in figures 1, 2 and 4;
[0018] [Fig.7] is a cross-sectional view along BB of the lateral wall portion shown [Fig.6];
[0019] [Fig.8A] and [Fig.8B] are cross-sectional views along CC of the side wall portion shown [Fig.6], illustrating two embodiment variants;
[0020] [Fig.9A] is a perspective view, in accordance with a first embodiment of the invention, of a male assembly means (without magnet or ferromagnetic element) intended to be integrated into a part of the side wall constituting the insulating envelope of the tank device shown in figures 7 and 8, and figures [Fig.9B] and [Fig.9C] are elevation views in two different directions of the means shown [Fig.9A];
[0021] [Fig.1OA] is a perspective view, in accordance with a first embodiment of the invention, of a female assembly means (without magnet or ferromagnetic element) intended to be integrated into a part of the side wall constituting the insulating envelope of the tank device shown in figures 7 and 8, and figures [Fig.1OB] and [Fig.1OC] are elevation views in two different directions of the means shown [Fig.1OA];
[0022] [Fig. 11] is a view at a different scale of detail Y of [Fig.5];
[0023] [Fig. 12] is a view at a different scale of detail W of [Fig.3];
[0024] [Fig. 13] is a view at a different scale of detail Z of [Fig. 5], in accordance with the first variant of the realization of the male and female assembly means represented in figures 9 and 10 and achieving the magneto-mechanical assembly link between parts of the side wall;
[0025] [Fig. 14] is a top view of a plate-shaped body, intended to close the lower opening of the insulating casing of the tank device illustrated in figures 1 to 5, according to a first embodiment of the invention;
[0026] [Fig.15A] and [Fig.15B] are top and perspective views respectively of a plate-shaped body, intended to close the lower opening of the insulating envelope of the tank device illustrated in figures 1 to 5, according to a second embodiment of the invention;
[0027] [Fig. 16] is a top view of one of the three identical constituent parts of the plate-shaped body shown in figures 15;
[0028] [Fig. 17] is a view at a different scale of detail Z of [Fig. 5], in accordance with a second embodiment of the male and female assembly means providing the magneto-mechanical assembly link between side wall parts, and,
[0029] [Fig. 18] is an exploded view detail illustrating the placement of a male assembly means shown [Fig.17] at the assembly edge of a side wall part.
[0030] Figures 1 to 5 illustrate a multi-part insulating casing (1) for a tank (2), particularly for a water storage tank. This casing (1) comprises at least two complementary side wall parts (3), joined together by butting their opposite lateral edges (31, 32) to form a hollow cylindrical body (4), with or without a round cross-section, and, optionally at least one plate-shaped body (5, 6) closing one or both of the two opposing upper and lower openings of said cylindrical body (4). The aforementioned various parts (3) together constitute an insulating shell (11), optionally closed by at least one of the two bodies (5, 6), intended to surround and enclose said reservoir (2). The lateral assembly edges (31, 32) of the side wall parts (3) extend along the longitudinal direction (DL) of the cylindrical body (4).
[0031] According to the invention, each side wall part (3) has a composite structure with a main body (34) made of a rigid foamed or cellular material and having at least one cavity or recessed area (341) at the level of the inner face (35) of the side wall part (3) facing the tank (2), and at least one vacuum insulating panel (36), extending over a portion of the surface of the side wall part (3) concerned, is disposed in said at least one cavity or recessed area (341), preferably in a fitted manner, said insulating envelope (1) also comprising at least one layer (7) of compressible material arranged to be located at least between the main bodies (34) of the side wall parts (3) and the tank (2).
[0032] Thanks to these features, and in particular the presence of vacuum-insulated panels (36), the invention provides an insulating tank casing (1) with significantly higher thermal insulation performance than existing casings of equal thickness. Because of their integration within the thickness of the main body (34) and their inner covering by the layer (7) of compressible material, these relatively fragile panels (36) are well protected. Furthermore, this at least one layer (7) of compressible material, by filling the space between the rigid main body and the outer face of the tank (2), prevents any chimney effect (air circulation by convection between the tank and the casing).
[0033] As shown in [Fig. 8B], the main body (34) advantageously consists of a plate configured to house said at least one vacuum insulation panel (36) and providing peripheral assembly edges (31, 32, 38, 39) to the considered side wall portion (3). These various assembly edges (31, 32, 38, 39) comprise two opposing lateral edges (31, 32) for assembly between side wall portions (3), an upper edge (38) for assembly with the plate-shaped body (5) closing the upper opening of the cylindrical body (4), and a lower edge (39) for assembly with the plate-shaped body (6) closing the lower opening of the cylindrical body (4). Said assembly edges (31, 32, 38, 39) are associated with respective peripheral edges (343) on the inner face (35) of the main body (34), which delimit between them the cavity or recessed area (341) housing said at least one vacuum insulating panel (36).
[0034] The layer (7) is advantageously at least slightly compressed when the side wall portions (3) are joined together by butting their opposite lateral edges (31, 32) and establishing hybrid mechanical-magnetic assembly links (33) to form the hollow cylindrical body (4). Thus, this layer (7) not only prevents air circulation along the outside of the tank, but also compensates for manufacturing and assembly clearances and ensures flexible contact under pressure between the hollow cylindrical body (4) and the tank (2) with a surface distribution and adaptation of said pressure.The thickness of this compressible layer (7), for example between 10 mm and 30 mm, preferably on the order of 20 mm (in the uncompressed state), is determined in such a way, in relation to the respective diameters of the reservoir (2) and the cylindrical body (4), that all the side wall parts (3) can be assembled butt-jointed to form said body (4) while at least partially compressing said layer (7) between these parts (3) and the wall of the reservoir (2).
[0035] According to a first embodiment, the layer (7) of compressible flexible material, for example a non-woven synthetic fiber, located between the main body (34) of each side wall part (3) and the reservoir (2) consists of a layer independent of the side wall parts (3), formed of a continuous sheet of compressible material wound on at least one turn, preferably several turns, around the reservoir (2).
[0036] According to a second embodiment, shown in particular in Figures 8, each side wall portion (3) comprises a side (71) of compressible flexible material attached to its inner face (35), for example a side (71) of non-woven material of synthetic fibers, this side (71) covering at least said inner face (35) and the vacuum insulation panel(s) (36) incorporated in the portion of side wall (3) considered, and a lateral band of said side (71) advantageously extending over a part of the thickness of at least one of the two lateral assembly edges (31, 32) of the portion of side wall (3) considered, these different side (71) forming by abutting juxtaposition of the side wall portions (3) which include them, the layer (7) of compressible flexible material.This side (71) advantageously also partially on part of the edge of one of the lateral assembly edges (31, 32), being compressed during the joining of the two relevant lateral wall parts (3) (see [Fig. 13]).
[0037] In order to mechanically reinforce the butt joint and promote thermal insulation in the contact plane (PC), the two opposite lateral assembly edges (31 and 32) of each side wall portion (3) have The respective recesses (312, 322) are mutually complementary, forming, when two lateral wall parts (3) are joined by butting, an assembly interface (IA) which is surface-contiguous, with at least one profiled baffle formed along the longitudinal direction (DL) of the cylindrical body (4). This results in at least two contact half-planes (PC) at each assembly interface (IA), offset from each other by said recesses.
[0038] According to a first variant of the external appearance of the insulating envelope (1), shown in Figures 2, 6, 7 and 13, each side wall part (3) comprises a cladding wall (37) attached to the outer face (344) of its main body (34) and secured to the latter at the two opposing lateral assembly edges (31 and 32) by folded lateral portions (371), the latter being advantageously pinched between the lateral assembly edges (31 and 32) of the abutting side wall parts (3) forming the cylindrical body (4).
[0039] Providing a cladding panel (37) in the form of an attached part, removably connected to the main body (34), not only allows for standardization in the manufacture of the side panel components (3), but also for a wide range of aesthetic options and for modifying the external appearance of the insulating shell (11) over time. Finally, this arrangement also facilitates recycling at the end of its life.
[0040] The folded side portions (371) have cutouts for the passage of the assembly means (311, 321). Advantageously, these means ensure the attachment of the folded side portions (371) of the cladding panels (37) to the side edges (31, 32) thanks to their screw or nail-head shapes.
[0041] According to a second embodiment of the external appearance of the insulating envelope (1), shown for example in [Fig.8A], the main body (34) of each part of the side wall (3) has at its external face (344) a skin, where appropriate with a treated surface, forming an integrated cladding wall (37).
[0042] In both variants, the cylindrical body (4) is advantageously made up of two to six lateral wall parts (3), preferably of four.
[0043] Preferably, in order to provide the desired rigidity and thermal insulation, the main body (34) of the side wall parts (3) is formed of a graphite-enhanced cellular foam material, advantageously polystyrene or polyurethane, with a density of at least 25 g / L. The same is favorable for the plate-shaped body (5) closing the upper opening of the cylindrical body (4), when this body (5) is present.
[0044] The vacuum insulation panel or panels (36) may in particular consist of a panel comprising a multilayer plastic / aluminum envelope enclosing A mineral powder, such as silica powder, is hermetically sealed. When this coating is vacuum-sealed, it transforms into a rigid, formable mat, for example, a curved concave / convex panel. Panels of this type are notably marketed by the company va-Q-tec.
[0045] These panels (36) are housed in corresponding cavities in the main bodies (34), foamed around them to form the side wall sections (3), or hollowed out in a suitable manner. The panels (36) advantageously extend over the entire height of the tank (2) around the latter and have, for example, a thickness of between 15 and 30 mm, preferably in the range of 18 to 20 mm. The main bodies (34) may, for example, have a thickness of in the range of 100 to 120 mm.
[0046] For the purpose of creating an insulating shell (11) closed at least at the level of the upper opening of the cylindrical body (4), said plate-shaped body (5) is fitted onto or into the cylindrical body (4) at the upper assembly edges (38) of the side wall portions (3) that compose it, and said plate-shaped body (5) has peripheral formations (51) cooperating by engaging conjugate shapes with formations (381) of the upper assembly edges (38), for example, inverted rib / groove pairs or complementary step-outs, to create a baffle configuration. Furthermore, at least one flange (52) of a flexible, compressible material, for example, a (discoidal) flange of a non-woven synthetic fiber material, is associated with the plate-shaped body (5), on its inner face facing the reservoir (2), separately or not.A covering cover (9) may optionally cover the body (5) externally, being, for example, of the same material as the covering walls (37). It may also, where appropriate, cover the upper edges (38) of the bodies (34) and the side wall sections (3). Furthermore, a (discoidal) plate having the same composition as a vacuum insulation panel (36) may optionally be interposed between the side (52) of compressible flexible material and the plate-shaped body (5).
[0047] As shown in Figures 1 to 6, the abutting lateral assembly edges (31 and 32) of at least two side wall parts (3) have cutouts (313, 323) which cooperatively form passage openings (42) in the cylindrical body (4) for conduits or similar tubular elements (8), at least one of the side walls (3) possibly also being provided with at least one such passage opening (42).
[0048] The cylindrical body (4) can be made up of either a single row of side wall parts (3) or at least two rows of side wall parts (3), superimposed in the longitudinal direction (DL). Consequently, the insulating casing (1) can be adapted to tanks of varying sizes in the direction (DL), the lateral wall parts (3) superimposed in two successive rows being advantageously interlocked with each other with their respective upper (38) and lower (39) edges.
[0049] As shown in Figures 1 to 6, the abutting lateral assembly edges (31 and 32) of at least two side wall parts (3) have cutouts (313, 323) which cooperatively form passage openings (42) in the cylindrical body (4) for conduits or similar tubular elements (8), at least one of the side walls (3) possibly also being provided with at least one such passage opening (42).
[0050] The cylindrical body (4) can be made up of either a single row of side wall sections (3) or at least two rows of side wall sections (3), superimposed in the longitudinal direction (DL). Consequently, the insulating casing (1) can be adapted to tanks of varying sizes in the direction (DL), the superimposed side wall sections (3) of two successive rows being advantageously nested with each other with their respective upper (38) and lower (39) edges.
[0051] The cylindrical body (4) can of course have cross-sections of various shapes, along a plane perpendicular to its longitudinal direction (DL), but preferably it has a circular cross-section. In this latter case, each part of the lateral wall (3) will have a suitable curved shape.
[0052] In accordance with another aspect of the invention, appearing from Figures 2 to 8, 13 and 17 more particularly, each assembly edge (31, 32) of a side wall part (3) comprises at least two magnetic locking assembly means (311 or 321) cooperating respectively with at least two corresponding complementary magnetic locking assembly means (321 or 311) present on the assembly edge (32, 31) of the other or another side wall part (3) with which it is assembled with edge-to-edge butting.
[0053] Thanks to these additional features of the invention, the resulting insulating casing (1) is easy to mount on the tank (2) and easily removable (partially, for example for maintenance, or totally, for replacing the casing for final recycling or for a change in appearance). Furthermore, these mounting / dismounting operations can be carried out without the use of separate fasteners or assembly parts and without requiring any tools. In addition, the invention makes it possible to supply an insulating casing (1) in kit form, ready for assembly (where applicable, on the installation site), and whose packaging can be optimized with a limited number of parts, namely, for the hollow cylindrical body (4), only the side wall sections (3) with their integrated magnetic locking assembly means (311, 321).
[0054] Advantageously, and as shown in Figures 8, the magnetically locking assembly means (311, 321) are provided to be of two different types, and each of the two assembly edges (31 and 32) of a side wall portion (3) comprises assembly means (311 or 321) of only one of the two types. By equipping each of the two opposing lateral assembly edges (31 and 32) of each side wall portion (3) with assembly means of one type that can cooperate with complementary coincident means of the other type present on the abutting edge, the assembly of the hollow cylindrical body (4) is facilitated and any assembly errors are avoided.
[0055] Preferably, each assembly joint (33) formed by the cooperation of a pair of assembly means (311 and 321) of different types consists of a mechanically engaged joint of conjugate shapes combined with a magnetic joint, which advantageously locks said engagement. Thus, each assembly joint (33) is a double joint integrating two joints of different natures, the magnetic joint automatically ensuring the locking of the mechanically engaged joint. The assembly between two lateral wall parts (3) is achieved by means of at least two of the aforementioned assembly joints (33) (of the magnetomechanical type), advantageously at least three, and preferably at least four, distributed along the abutting lateral edges (31 and 32).
[0056] To facilitate assembly, and in particular guidance during the final approach movement between two side wall sections (3) to be joined, each assembly joint (33) exhibits, through its mechanical engagement of conjugate shapes, a self-centering capability, enhanced at least at the end of the mutual engagement of the two assembly means (311 and 321) involved by the action of the magnetic connection. Thus, possibly even during, and especially at the end of, the reciprocal engagement of the assembly means (311 and 321), the assembly movement will be assisted and the final engagement secured, then locked, by magnetic attraction.
[0057] According to an advantageous feature of the invention, evident from [Fig. 13] and Figures 8, each mechanically engaged connection locks the assembly between two side wall portions (3) considered in the contact plane (PC) of their respective mutually abutted assembly edges (31 and 32), and each magnetic connection locks the mechanically engaged connection and secures the assembly between the two side wall portions (3) considered in a direction perpendicular to said contact plane (PC). Such an embodiment of the assembly connections (33) combines the achievement of high structural rigidity of the composite cylindrical body (4), with the possibility of disassembly and reassembly with controlled, repeatable, and non-destructive force.
[0058] As can be seen from Figures 8 to 10, 13 and 17, and in accordance with a favorable embodiment of the invention, the magnetic locking assembly means (311, 321) are of two different types, a first type (311) consisting of an added male part, protruding from the surface of the assembly edge (31) on which it is mounted and comprising at least one magnet (3111) or ferromagnetic element (3112), preferably at its free end (3110), and a second type (321) consisting of an added female part, conjugate in shape to the shape of the male part (311), defining a recess in relation to the surface of the assembly edge (32) on which it is mounted and comprising at least one magnet (3211) or ferromagnetic element (3212), preferably at its bottom (3110).
[0059] The magnetic attraction force at the contact between each magnet / ferromagnetic element pair is preferably greater than about 20kg, for example in the order of 25kg to 35kg (Neodymium magnet).
[0060] For their attachment to the side wall sections (3), and in accordance with a first embodiment illustrated in particular in Figures 8 to 10 and 13, each magnetically locking assembly means (311, 321) may include a thread (3113, 3213) for screw mounting in the relevant assembly edge (31, 32). Each assembly means (311, 321) is then substantially in the form of a screw with a tapered head.
[0061] In accordance with another embodiment of the invention (see Figures 17 and 18), allowing for less destructive disassembly, each magnetically locking assembly means (311, 321) may include an anchor pin (3114, 3214), lockable in the mounted position by a transverse nail (3115, 3215), preferably rotatably mounted and equipped with an eccentric (3116, 3216). Each assembly means (311, 321) may further include a fastening pin (3117, 3217) attaching the folded lateral portion (371) of the cladding panel (37) to the relevant lateral edge (31, 32). As shown in Figures 17 and 18, the nail (3115, 3215) can be provided with a butterfly to facilitate its rotation and the lateral edge (31, 32) and the side of the layer of compressible material (71) include a hole for the placement of said locking nail (3115, 3215).Figures 8 to 10, 13 and 17 illustrate, in accordance with an advantageous practical embodiment of the invention, that the magnetic locking assembly means (311, 321) are of two different types, a first type (311) consisting of a male frustoconical piece, projecting from the surface of the assembly edge (31) on which it is mounted and comprising at least one magnet (3111) or ferromagnetic element (3112), preferably at its apex (3110), and a second type (321) consisting of a female frustoconical piece, of complementary shape with respect to . the shape of the male part (311), defining a recess relative to the surface of the assembly edge (32) on which it is mounted and comprising at least one magnet (3211) or ferromagnetic element (3212), preferably at the level of its base (3210), said assembly means (311, 321) further having either a thread (3113, 3213), for example a screw-forming part, or an anchoring pin (3114, 3214), lockable in the mounted position by a transverse nail (3115, 3215), for their mounting in the assembly edge (31, 32) concerned.
[0062] In relation to the first variant of figures 8 to 10 and 13, the edge (32) receiving the female part (321) is milled before screwing the latter, in order to create a cavity to receive this part (321) with flushness.
[0063] In order to be able to constitute a closed insulating shell (11) and to ensure good insulation, combined with easy assembly and disassembly possibilities despite the presence of the feet (21) of the tank (2), the plate-shaped body (6) sealing the lower opening of the cylindrical body (4) consists of a rigid foamed or cellular material, is provided with openings (61) for the passage of the support feet (21) of the tank (2), advantageously at least three, and is composed of at least two mutually complementary constituent parts (62), the assembly line(s) (63) between constituent parts (62) passing through said passage openings (61).
[0064] As shown in [Fig. 14], the plate-shaped body (6) can consist of only two constituent parts (62) of different shape, but preferably it consists of three identical constituent parts (62) and advantageously includes three passage openings (61) for the three feet of the tank.
[0065] The plate-shaped body (6) is made of at least two constituent parts as described above, allowing for its installation, as well as its partial or total disassembly, while the tank (2) is resting on its feet (21). This installation should normally take place before the cylindrical body (4) is installed around the tank (2), but can also take place after partial assembly of said body (for example, after assembly of three of the four side wall sections that can form said body).
[0066] In order to achieve effective insulation in the lower region of the cylindrical body (4) and to obtain a closed insulating shell (11) at this level, the plate-shaped body (6) is peripherally fitted into the cylindrical body (4) at the lower assembly edges (39) of the side wall portions (3) that compose it. For this purpose, said plate-shaped body (6) comprises peripheral formations (64) cooperating by means of conjugate form engagement with formations (391) of the lower assembly edges (39), for example, inverted rib / groove pairs or complementary offsets, to create a baffle configuration, optionally including at least one side of flexible material compressible, for example a non-woven synthetic fiber sidewall, being associated with the plate-shaped body (6), on its inner face turned towards the reservoir (2), separately or not.
[0067] Advantageously, the plate-shaped body (6) also consists of a graphite-enhanced alveolar foam material, advantageously polystyrene or polyurethane, with a density of at least 25g / L.
[0068] As shown in Figures 15, the plate-shaped body (6) may, in the case of a tank (2) with a domed bottom, have a complementary concave shape for surface and centered contact with this bottom. In addition, grooves for connecting conduits (8) may be present.
[0069] Alternatively, the plate-shaped body (6) can also be made of a flexible fibrous material, such as, for example, a polyester fiber mat cut to the shape and size of the lower opening, and thus be made in one piece.
[0070] Advantageously, the various side wall parts (3) mentioned above and the two plate-shaped bodies (5, 6) together constitute an insulating envelope (1) in the form of a ready-to-assemble kit.
[0071] The invention also relates to a thermally insulated tank device comprising a tank (2) provided with an insulating envelope, characterized in that said insulating envelope is an insulating envelope as described above.
[0072] Of course, the invention is not limited to the embodiments described and shown in the accompanying drawings. Modifications remain possible, particularly with regard to the composition of the various elements or by substitution of technical equivalents, without departing from the scope of protection of the invention.
Claims
1. Demands Insulating casing (1) in several parts for a tank (2), in particular for a water storage tank, comprising at least two complementary side wall parts (3), joined together by butting their opposite lateral edges (31, 32) to form together a hollow cylindrical body (4), with a round or non-round cross-section, and, optionally, at least one plate-shaped body (5, 6) closing one or each of the two opposite upper and lower openings of said cylindrical body (4), the various parts (3) referred to above together constituting an insulating shell (11), optionally closed by at least one of the two bodies (5, 6), intended to surround and enclose said tank (2), with the lateral assembly edges (31, 32) of the side wall parts (3) extending along the longitudinal direction (DL) of the cylindrical body (4),each side wall portion (3) having a composite structure with a main body (34) made of a rigid foamed or cellular material and having at least one cavity or recessed area (341) on the inner face (35) of the side wall portion (3) facing the tank (2), and at least one vacuum insulation panel (36), extending over a portion of the surface of the side wall portion (3) concerned, being disposed in said at least one cavity or recessed area (341), preferably in a fitted manner, insulating envelope (1) characterized in that said insulating envelope (1) also comprising at least one layer (7) of compressible material arranged to be located at least between the main bodies (34) of the side wall portions (3) and the tank (2), and in that the two opposing lateral assembly edges (31 and 32) of each side wall portion (3) have respective recesses (312,322) mutually complementary, forming, when two lateral wall parts (3) are joined by butting, an assembly interface (IA) which is surface-contiguous, with at least one baffle being formed, profiled along the longitudinal direction (DL) of the cylindrical body (4).
2. Insulating envelope (1) according to claim 1, characterized in that the main body (34) consists of a plate configured to house said at least one vacuum insulating panel (36) and providing peripheral assembly edges (31, 32, 38, 39) to the considered side wall portion (3), and in that these assembly edges (31, 32, 38, 39) comprise two opposing lateral edges (31, 32) for assembly between side wall portions (3), an upper edge (38) for possible assembly with the plate-shaped body (5) closing the upper opening of the cylindrical body (4) and a lower edge (39) for possible assembly with the plate-shaped body (6) closing the lower opening of the cylindrical body (4), said assembly edges (31, 32, 38, 39) being associated with peripheral edges (343) respective at the level of the inner face (35) of the main body (34),which delimit between them the cavity or recessed area (341) housing said at least one vacuum insulating panel (36).
3. Insulating envelope (1) according to claim 1 or 2, characterized in that the layer (7) of compressible material which is flexible, for example a non-woven material of synthetic fibers, located between the main body (34) of each side wall part (3) and the tank (2), consists of a layer which is independent of the side wall parts (3), and is formed of a continuous sheet of compressible material wound on at least one turn, preferably several turns, around the tank (2).
4. Insulating envelope (1) according to claim 1 or 2, characterized in that each side wall portion (3) comprises a flank (71) of compressible material which is flexible and attached to its inner face (35), for example a flank (71) of non-woven material of synthetic fibers, and in that this flank (71) covers at least said inner face (35) and the vacuum insulating panel(s) (36) incorporated in the side wall portion (3) considered, a lateral band of said flank (71) advantageously extending over a portion of the thickness of at least one of the two lateral assembly edges (31, 32) of the side wall portion (3) considered, these different flanks (71) forming by butted juxtaposition of the side wall portions (3) which comprise them, the layer (7) of flexible compressible material.
5. Insulating envelope (1) according to any one of claims 1 to 4, characterized in that each side wall part (3) comprises a covering wall (37) attached to the outer face (344) of its main body (34) and secured to the latter at the two lateral assembly edges (31 and 32) opposite by folded lateral portions (371), the latter being advantageously pinched between the lateral assembly edges (31 and 32) of the abutting side wall parts (3) forming the cylindrical body (4).
6. Insulating envelope (1) according to any one of claims 1 to 4, characterized in that the main body (34) of each side wall part (3) has at its outer face (344) a skin, optionally with a treated surface, forming an integrated cladding wall (37), the cylindrical body (4) advantageously being made up of two to six side wall parts (3), preferably of four.
7. Insulating envelope (1) according to any one of claims 1 to 6, characterized in that the main body (34) is formed of a graphite-enhanced cellular foam material, advantageously polystyrene or polyurethane, with a density of at least 25g / L.
8. Insulating envelope (1) according to any one of claims 1 to 7, characterized in that the plate-shaped body (5) closing the upper opening of the cylindrical body (4) consists of a graphite-enhanced cellular foam material, advantageously polystyrene or polyurethane, with a density of at least 25 g / L, in that said plate-shaped body (5) is fitted onto or into the cylindrical body (4) at the upper assembly edges (38) of the side wall portions (3) composing it, and in that said plate-shaped body (5) comprises peripheral formations (51) cooperating by conjugate form engagement with formations (381) of the upper assembly edges (38), for example, inverted rib / groove pairs or complementary offsets, to create a baffle configuration, at least one flank (52) of a compressible flexible material, for example, a flank of material non-woven synthetic fibers,being associated with the plate-shaped body (5), on its inner face turned towards the reservoir (2), separately or not.
9. Insulating envelope (1) according to any one of claims 1 to 8, characterized in that the lateral assembly edges (31 and 32) abutting at least two lateral wall parts (3) have cutouts (313, 323) which together form passage openings (42) in the cylindrical body (4) for conduits or similar tubular elements (8), at least one of the lateral walls (3) possibly also being provided with such a passage opening (42).
10. Insulating envelope (1) according to any one of claims 1 to 9, characterized in that the cylindrical body (4) is made up of at least two rows of side wall parts (3), superimposed in the longitudinal direction (DL).
11. Insulating envelope (1) according to any one of claims 1 to 10, characterized in that the cylindrical body (4) has a circular section along a plane perpendicular to its longitudinal direction (DL).
12. Insulating envelope (1) according to claim 1 to 11, characterized in that each assembly edge (31, 32) of a side wall part (3) comprises at least two magnetically locking assembly means (311 or 312) cooperating respectively with at least two corresponding complementary magnetically locking assembly means (312 or 311) present on the assembly edge (32, 31) of the other or another side wall part (3) with which it is assembled with edge-to-edge butt joining.
13. Insulating envelope (1) according to claim 12, characterized in that the magnetically locking assembly means (311, 312) are of two different types, in that each of the two assembly edges (31 and 32) of a side wall part (3) comprises assembly means (311 or 321) of only one of the two types and in that each assembly link (33) formed by cooperation of a pair of assembly means (311 and 321) of different types consists of a mechanical engagement link of conjugate shapes combined with a magnetic link.
14. Insulating envelope (1) according to claim 13, characterized in that each assembly link (33) has, through its mechanical engagement of conjugate shapes, a self-centering ability, favored at the end of mutual engagement of the two assembly means (311 and 321) by the action of the magnetic link.
15. Insulating envelope (1) according to claim 13 or 14, characterized in that each mechanically engaged connection blocks the assembly between two side wall parts (3) considered in the contact plane (PC) of their respective mutually abutted assembly edges (31 and 32) and in that each magnetic connection locks the mechanically engaged connection and blocks the assembly between the two side wall parts (3) considered in a direction perpendicular to said contact plane (PC).
16. Insulating envelope (1) according to any one of claims 12 to 15, characterized in that the magnetic locking assembly means (311, 321) are of two different types, a first type (311) consisting of an added male piece, projecting from the surface of the assembly edge (31) on which it is mounted and comprising at least one magnet (3111) or ferromagnetic element (3112), preferably at its free end (3110), and a second type (321) consisting of an added female piece, conjugate in shape to the shape of the male piece (311), defining a recess in relation to the surface of the assembly edge (32) on which it is mounted and comprising at least one magnet (3211) or ferromagnetic element (3212), preferably at its bottom (3110).
17. Insulating envelope (1) according to claim 12 to 16, characterized in that each magnetic locking assembly means (311, 321) includes a thread (3113, 3213) for its mounting by screwing into the relevant assembly edge (31, 32).
18. Insulating envelope (1) according to any one of claims 12 to 16, characterized in that each magnetic locking assembly means (311, 321) comprises an anchor pin (3114, 3214), lockable in the mounted position by a transverse nail (3115, 3215), preferably rotatably mounted and equipped with an eccentric (3116, 3216), each assembly means (311, 321) comprising optionally a fastening pin (3117, 3217) hooking the folded lateral portion (371) of the cladding wall (37) to the relevant lateral edge (31, 32).
19. Insulating envelope (1) according to any one of claims 12 to 18, characterized in that the magnetically locking assembly means (311, 321) are of two different types, a first type (311) consisting of a male frustoconical piece, protruding from the surface of the assembly edge (31) on which it is mounted and comprising at least one magnet (3111) or ferromagnetic element (3112), preferably at its apex (3110), and a second type (321) consisting of a female frustoconical piece, complementary in shape to the male piece (311), defining a recess in the surface of the assembly edge (32) on which it is mounted and comprising at least one magnet (3211) or ferromagnetic element (3212), preferably at its base (3110), said assembly means (311, 321) further having either a thread (3113, 3213), for example a screw-like portion, or an anchoring pin (3114, 3214), lockable in the mounted position by a transverse pin (3115, 3215), for their mounting in the edge assembly (31, 32) concerned.
20. Insulating envelope (1) according to any one of claims 1 to 19, characterized in that the plate-shaped body (6) sealing the lower opening of the cylindrical body (4) consists of a rigid foamed or cellular material, is provided with openings (61) for the passage of the support feet (21) of the tank (2), advantageously at least three, and is composed of at least two mutually complementary constituent parts (62), the assembly line(s) (63) between constituent parts (62) passing through said passage openings (61).
21. Insulating envelope (1) according to claim 20, characterized in that the plate-shaped body (6) is made up of three identical constituent parts (62) and advantageously has three passage openings (61).
22. Insulating envelope (1) according to claim 20 or 21, characterized in that the plate-shaped body (6) is peripherally fitted into the cylindrical body (4) at the lower assembly edges (39) of the side wall portions (3) composing it, and in that said plate-shaped body (6) comprises peripheral formations (64) cooperating by conjugate form engagement with formations (391) of the lower assembly edges (39), for example, inverted rib / groove pairs or complementary offsets, to create a baffle configuration, optionally at least one flank of compressible flexible material, for example, a flank of non-woven material of synthetic fibers, being associated with the plate-shaped body (6), on its inner face facing the reservoir (2), separately or not.
23. Thermally insulated tank device comprising a tank (2) provided with an insulating jacket, characterized in that said insulating jacket is an insulating jacket (1) according to any one of claims 1 to 22.