FR2628179A1 - Twin-wall panel, insulated by depressurising interior by vacuum pump - has inter-wall stiffening by props or by open cell infilling, with air extracted through connections with adjacent panels by vacuum pump - Google Patents

Abstract

The two outer walls (1,2) of stiff insulating material, are separated around their peripheries by framework of sealed strips (5,6,7,8). These may have male or female profiles suitable for sealed attachment to adjacent panels. Air extraction connections (9) in the walls, or opt. in the side-frame, link up with adjacent panels, in series or parallel, terminating in the connection to a vacuum pump. The walls are stiffened by props (4) whose various lengths produce an outward curvature to the walls to increase resistance to external atmospheric pressure. USE/ADVANTAGE - For ovens, furnaces, refrigerators, freezers, living spaces and acoustic walls. Vacuum pump may be switched on by timer or pressure-probe to maintain low pressure and thereby give highest insulation for given thickness of panel.

Description

() FRENCH REPUBLIC Publication no .: 2,628,179 (use only

  for NATIONAL INSTITUTE. INDUSTRIAL PROPERTY N of national registration 88 02 745 (N of national registration: 8 8 02 745 PARIS

(Int CI ': F 16 L 59/06.

@ A1 PATENT APPLICATION

  ) Date of filing: March 2, 1988. Q Applicant (s): Société HDG ENERGIE, SA. FR.

) Priority

@ Inventor (s): Denis Consigny.

  Date of public availability of the

  application: BOPI "Patents" n 36 of September 8, 1989.

  6 References to other national documents appearing

  rentés: Q Holder (s): Agent (s) Modular insulation panels including a cavity maintained in depression and insulation process integrating

such signs.

  57 The field of application of the invention is the insulation of living or non-living volumes. E ô The insulating panels according to the invention comprise two

  flat sides 1 and 2 separated by a frame and spacers 4 l s ........

  so that a cavity 3 is formed inside these. -

  panels. Each cavity 3 of a panel can be connected by ..

  sealingly by a fitting 10 to a cavity 3 of a panel ,, - 'neighbor or to a vacuum pump 11. l l, 2 qf = These panels have good insulating qualities.! when the cavity 3 is at atmospheric pressure, these 3 insulating qualities become excellent when the cavities 3 I are put under vacuum by the pump 11. i '' i The invention also relates to the process consisting in isolating G, by means of '' a plurality of panels according to the invention, a given volume which can be for example a freezer, unl A

storage tank or building.

  CO IN L D Sale of booklets at IMPRIMERIE NATIONALE, 27, rue de la Convention -75732 PARIS CEDEX 15 "Modular insulation panels comprising a cavity maintained in depression and insulation process

incorporating such panels ".

  The field of application of the invention is the thermal and / or acoustic insulation of volumes

habitable or not.

  When it is useful, even essential,

  to isolate a volume from the atmosphere are extreme

  many. So much so that the insulating products and panels industry is present in most countries and

  represents an extremely large volume of activity.

  The main applications of insulation are the preservation of food or products in specific refrigerated enclosures, the conservation of heat in ovens or heat-insulated storage devices and the improvement of comfort in living quarters. Currently the insulation functions are obtained from rigid panels or injected products whose thermal conductivity and inversely proportional to their thickness and is a function of

  characteristics of their constituent material (s).

  Glass wool, rock wool, vermiculite and polystyrenes are mainly known,

  products frequently used for thermal insulation.

  The cost price of these panels is high and their performance remains limited by space constraints: to obtain very effective insulation, it should be possible to provide thicknesses of at least 10 cm, and ideally thicknesses of one meter . It is found in fact that with a conventional insulating material, with a useful thermal conductivity of 0.037 w / mc, it is necessary to use a thickness of 100 cm to obtain a thermal resistant wall of 2.7 m2 c / w and 200 cm for

  lead to a thermal resistance of 5.4 m2 c / w.

  It is also found that the manufacture, transport and implementation of conventional insulators is delicate and expensive taking into account the amount of material to be used to achieve a satisfactory result. Finally, whether one insulates from the inside or from the outside, these conventional insulation methods have the disadvantage, given the thickness necessary to obtain a satisfactory result, of achieving a volume ratio. occupied by

  the isolated object / unfavorable usable volume.

  In an attempt to resolve these drawbacks, products with particularly low thermal conductivities have been proposed on the one hand (examples: polyisocyanurates, formophenolic foams) and on the other hand the insulation functions have been integrated into the walls of the volumes to be protected, in particular in the case applications

for buildings.

  We know that the ideal insulator, both in terms of its thermal performance and its acoustic performance is absolute vacuum. The absence of material in fact prohibits any heat transmission by

  conduction and any transmission of sound vibrations.

  However, the vacuum is not used as an insulator in industrial or domestic applications because it is extremely difficult and expensive to produce a non-cylindrical cavity which is capable of sustainably maintaining a pressure markedly lower than atmospheric pressure. Over time, it can be seen that progressive infiltrations lead to an increase in the pressure inside the cavity. In addition, cylindrical cavities, the production of which could possibly be envisaged with a high manufacturing cost, can be juxtaposed only by their generator, which prohibits the production of a

effective continuous insulation.

  Consequently, the object of the invention is to produce plant components and plants which provide concrete solutions and

  performing to the difficulties mentioned above.

  In this regard, a first object of the invention is to produce particularly efficient insulating panels while keeping a small thickness, compatible with the insertion of these panels into the walls of an oven, refrigerator or freezer or in

still habitable volumes.

  An additional objective is to reduce the cost price of the insulating panels and to facilitate their

transport and their implementation.

  Another object of the invention is to obtain a variable degree of insulation of a given volume from a plurality of panels surrounding this volume. This variable insulation is obtained by adjusting the value of the relative vacuum created in the cavities provided in the panels. An essential characteristic of the invention is in fact to produce panels of parallelepiped shape of a small thickness compared to their length and to their width, having on almost all of their surface a recess, which recess opens out through an orifice on a connector for sealingly connecting the cavity of each panel either to the cavity of a neighboring panel, or to a pump. The triggering of this pump, obtained either by a time switch, or even by a pressure probe located in the vacuum circuit, achieves indeed, with low energy consumption, a vacuum in the whole circuit and cavities which constitute the essentiality of

insulating panels.

  The value of the vacuum produced in the insulators of the panels is adjusted according to the degree of insulation desired without exceeding the mechanical limits of the panels. The problem of the mechanical strength of the panels is also of primary importance, since a flat panel of 1.1 m2 comprising a cavity of 1 m2 of surface would undergo, on each of its faces, a force of one ton. It is therefore essential to obtain a high pressure resistance at the faces

  planes of the panel according to the invention.

  To obtain this result, one of the characteristics of the invention consists in using the inertia provided by plates made of high density insulating material with a thickness corresponding to approximately 1/3 that of the total panel. In addition, high density insulating materials are also placed in a spacer so as to keep the spacing between the two plates constant, even after placing in vacuum.

of the cavity.

  Another characteristic of the panel according to the invention is that it comprises the means of effecting a tight seal between the cavity which it contains and that (s) of one or more identical panels to which this panel is juxtaposed, this such so that a plurality of adjoining panels constitutes a single circuit formed by cavities and fittings. This circuit leading to a

vacuum pump.

  Other characteristics and advantages of the invention will appear on the following reading of an embodiment of the invention, given for illustrative purposes only and the appended drawings in which: FIG. 1 represents a panel according to

  the invention from the front, from the side and from below.

  Figure 2 shows a panel according

the invention with hidden fittings.

  FIG. 3 shows a detail of the connection of the panels to each other, and different embodiments of

the interior cavity.

  FIG. 4 represents a freezer isolated at

  by means of panels according to the invention.

  FIG. 5 represents a domestic hot water storage tank isolated by means of panels according to the invention. figure 6 represents a dwelling house

  insulated by means of panels according to the invention.

  The insulating panel according to the invention comprises two plane faces, parallelepiped, of thickness less than their length and their width. These two faces (1) and (2) are made of a compact insulating material having high inertia and great resistance to pressure forces. This inertia and this resistance are obtained either by a single material (example high density formophenolic foam, carbon fiber-Kevlar), or by a complex associating several materials in the thickness of each of the two plates (examples: two metal walls or ABS, foam core

  insulation with or without metal or ABS spacers).

  These two plates (1) and (2) are interconnected by a frame composed of profiles (5), (6), (7) and (8), placed between these two plates around the periphery thereof. , so that the assembly constituted by the plates (1) and (2) and the elements of the frames (5), (6), (7) and (8) provides a hollow cavity (3) &

  the interior of the panel thus formed.

  The profiles (7) and (5) can advantageously be curved on their outer face while the profiles (6) and (8) have a hollow intended to

  receive the bending carried out on the parts (5) and (7).

  Other types of covering of the panels, one in relation to the other, can be obtained by means of specific profiles given to the external sides of the profiles (5), (6), (7) and (8) which may, for example, have 45 ° angles or an "L" profile making a precise adjustment between two neighboring panels

  and limiting air infiltration between two panels.

  In addition, to increase the resistance to pressure that the external walls of the panel undergo, in particular on (1) and (2), it will be possible to have spacers (4) made of high density insulating material, intended to keep the difference between these two plates including after depression of the

cavity (3).

  In an advantageous embodiment of the invention, the assembly constituted by the elements (1), (2), (4), (3), (6), (7) and (8) could be made of one piece per molding. Otherwise, all combinations of these elements can be obtained in one piece, the sub-assemblies thus produced being then assembled to

  obtain a panel according to the invention.

  It will also be advantageous to obtain by construction a prestressing of the faces (1) and (2), prestressing the value of which will be chosen according to the inertia of these plates, the nature and the arrangement of the spacers (4) as well than the value of the maximum vacuum to which the cavity (3) will be subjected when the panel is in service. This prestressing has the effect of fighting against the bringing together of the plates (1) and (2) when the cavity (3) is placed under vacuum. It is obtained for example by using a decreasing thickness of the spacers (4) from the center towards the periphery of the panel and a slight inclination of the profiles (5), (6), (7) and (8) whose thickness will be slightly more important inside the panel than outside (inclinations symbolized by

Angles).

  In all cases the cavities (3) must emerge outside the panel through an orifice or fitting (9) intended to make the connection between a panel and one or more identical panels pressed against the volume to be insulated, so that the same pressure can be maintained in the entire circuit composed by the interior cavities (3) contained in a plurality of panels according to the invention and the interconnection fittings (10). These connections (10) and orifices (9) can be produced by any known means. They can in particular be located either on the faces (1) or (2), or even inside the profiles (5), (6), (7) or (8) so as to obtain a sealed connection between the cavities (3)

  contained in two neighboring panels.

  Figure 2 shows an exemplary embodiment of the profile (5), (6), (7) and (8) integrating the orifices (9) and the fittings (10) obtained by clipping a panel onto its neighbor. For reasons of convenience, several

  orifices (7) can be made on each panel.

  These holes will either be sealed or

  connected to the openings of a neighboring panel.

  In a variant of the invention, the interior cavity (3) may consist of a plurality of veins, for example cylindrical formed in the

insulating material.

  FIG. 3a represents an embodiment in which these veins (13) are obtained by extrusion of the insulation. At the two ends of the panel, two covers (14) are fixed in a sealed manner perpendicular to the axis of the veins (13) so that all of the veins and recesses (15) formed in the covers (14) constitute a single and same circuit equivalent to a cavity (3). Several embodiment and arrangement of these veins can be made, as shown in Figures 3b (a single bundle of vein obtained by extrusion or molding of the insulation) and 3c (insulator having after shaping an anarchic bundle of veins

communicating with each other).

  It will be noted that the panel according to the invention has good insulating qualities, comparable to that of a conventional panel of the same thickness, including when the cavity (3) is not placed under vacuum. This feature makes it possible to trigger the vacuum setting of the cavity (3) only when the insulation needs are high and to possibly "shunt"

  a panel whose sealing would be insufficient.

  Figures (4), (5) and (6) show three

  preferred applications of the invention.

  Figure (4) shows the insulation of a freezer by means of a panel according to the invention. These panels are placed on the entire walls of the freezer, including the bottom and the lid. They can be integrated into the walls and be part of the supporting structure of the freezer. Each elementary panel is connected to one or more of its neighbors by at least one connector (10), shown here in a visible manner to facilitate understanding. The connections making the connection between the insulators of the trunk and those of the cover have a size and an arrangement such that they allow the opening of the cover. At least one point of the circuit consisting of all of the cavities (3) and the fittings (10) is tightly connected to a vacuum pump (11). This vacuum pump is triggered either manually or, preferably, by a pressure switch (12) located for example on the connection connecting the pump (11) to one of the panels and triggering the pump as soon as the pressure in the circuit is higher at P1 stopping it as soon as this pressure is less than P2. We will take for example P1 =

0.05 bars and P2 = 0.1 bars.

  Figure (5) shows the insulation of a domestic hot water storage tank by means of panels according to the invention. The realization and the operation are identical to those illustrated in figure (4), except that the panels have a curvilinear shape which marries

  the external shape of the balloon to be isolated.

  Figure (6) shows the insulation of a building by means of panels according to the ivention. Again, there are the panels, the fittings (10) and the pump (11). It will be noted that specific panels, of size different from that of the standard panels can be produced to insulate in particular the doors and the flaps providing for fittings (10) of length to allow the opening and closing of these elements. Likewise, it is possible to produce panels according to the invention, the faces (1) and (2) of which will be made of transparent materials (glass, polymetyl metacrelate, etc.) so as to replace the panes usually used in the (16) Other applications of the panels according to the invention and other variants in the mode of use thereof may be practiced without

  however, depart from the scope of the present invention.

  The invention also relates to the method which consists in thermally and / or acoustically insulating a given volume by means of a plurality of panels comprising at least one cavity (3), which cavities are interconnected by the fittings (10) so forming one or more sealed circuits, each of these circuits being connected to a vacuum pump (11) whose action

  is to lower the pressure in these circuits.

Claims (9)

  1. Thermal and / or sound insulation panel characterized in that it comprises at least one interior cavity (3) opening out through at least one orifice (7) to the outside of the panel.   2. Modular thermal and / or sound insulation panel according to claim (1) characterized in that it comprises the sealed connection means between an interior cavity (3) with which it is provided and one or more interior cavities (3) d one or more panels similar neighbors.   3. Panel according to claims 1 and 2   characterized in that it is made of insulating material high density.   4. Panel according to claims 1 and 3   characterized in that it comprises two flat faces (1) and (2) of thickness equal to approximately one third of the thickness of the panel and in that these two flat faces are subjected to a prestress tending to spread their centers each other.   5. Panel according to claim 1 characterized in that it comprises spacers (4) made in high density insulating material.   6. Panel according to any one of   claims 1 to 5 characterized in that it comprises two   faces (1) and (2) made of transparent or translucent material. 7. Panel according to claim 1 characterized in that at least the central part is made of insulating material and is obtained by extrusion or molding and is provided with a plurality of recessed veins communicating with each other. 8. A method of thermal or sound insulation of a volume, characterized in that it consists in surrounding this volume by means of adjoining panels comprising an interior cavity (3), each cavity being tightly connected by a fitting (10) to a cavity (3) of a neighboring panel, at least one of the cavities (3) being connected   tight to a pump & vacuum (11).   9. Isolation method according to claim 8 characterized in that the triggering of the pump & vacuum is obtained by a single switch (12) tightly connected to the circuit consisting of a plurality of cavities   interior (3) integrated & insulating panels.   ONa I.- 1 c '.- f'-I -, _ o t Ii't __ _ Co ooo -gi I Hc O., t <I, e II L i'ri '- I ----'- o. ' IIII .- ,, 2/6 _ Ai ELL   o a ppe A ^ 31 [nai 2_ l '1 "l IV7 (! IX i Il, t I' t I, I t À I I IlI II I: I ij I ' FIG.2I - -.-__: - z - - -: IF CI 'I. * I 91. I Vv there '. - --ri t ,, sZgZ___ THERE IF- - --   III --- I g.- e- CJ. "Na, '\ a? - - - - M \ ^ ^ 1, at, \ S% '' ELA I '' N Bare. LI ', I ', L / 6 IIG 5 F 15 1, AT At 10 FI. 6/6 t ', _ --_. F.6 I ,, Lrr.J --1 you: ", 6..CLMF: