METHOD FOR PRODUCING A DIFFUSING SHEET OF CORK, DIFFUSING CORK WALL, AND ISOTHERMIC CONTAINER COMPRISING SUCH A WALL

Abstract

The invention relates to a method for producing a diffusing sheet of cork for an isothermic container, characterised in that a starting sheet of cork with an initial density is compressed so as to laterally increase the density, and to form hardened outer skins with a higher level of diffusion compared to the initial level, and thereby control the diffusion of the compressed sheet.

Claims

1. Method for producing a diffusing sheet of cork for an isothermic container, comprising a starting sheet of cork with an initial density is compressed so as to laterally increase the density, and to form hardened outer skins with a higher level of diffusion compared to the initial level, and thereby control the diffusion of the compressed sheet.

2. Method for producing a diffusing sheet of cork for an isothermic container according to claim 1, said starting sheet of cork being compressed over the whole of the surface thereof.

3. Diffusing sheet of cork for an isothermic container, produced according to the production method of claim 1.

4. Isothermic container comprising walls, said walls comprising an outer sheet of cork and an inner sheet of cork, with an interstitial space arranged to receive a heat source, the walls being arranged to receive a content comprising said inner sheet is a sheet according to claim 3.

5. Isothermic container according to claim 4, said inner sheet having a higher density than said outer wall.

6. Isothermic container according to claim 4, wherein said walls form a primary isothermic space 5 closed by a bottom and a cover of a packaging with a secondary space for receiving said walls.

7. Isothermic container according to claim 4, which has the shape of a parallelepiped rectangle.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0017] These aspects, as well as other aspects of the invention will be clarified by the detailed description of the invention, reference being made to the appended drawings, whereon:

[0018] FIG. 1 is a cross-section view of the diffusing sheet of compressed cork of the invention;

[0019] FIG. 2 is a top view of the isothermic container of the invention; And FIG. 3 is a perspective view of the container in FIG. 2.

[0020] The figures are not drawn to scale. Similar elements are recorded by similar references on the figures.

DETAILED DESCRIPTION OF SPECIFIC EMBODIMENTS

[0021] In reference to FIG. 1, a starting sheet of cork has been compressed on the surface up to a determined thickness, and so as to have a varying density on the section of the sheet 1. The density within said sheet 1 is higher on the outer surfaces 2 than in the inner part 3 of said sheet 1 to enable a control of the diffusion of the temperature through said sheet.

[0022] During this production method, said starting sheet of cork here is compressed over the whole of the surface thereof.

[0023] The outer surfaces 2 are assimilated to dense casings, having a density situated between 0.6 to 0.85, while the inner part 3 of the diffusing wall 1 has a honeycomb structure with a density of between 0.15 and 0.45. The inner honeycomb part 3 now has a higher insulative power than the outer casings 2. This structure of sheet 1 enables to have a diffusing and insulative power at the same time, thanks to the diffusing power of the outer casings 2 and to the insulative power of the inner honeycomb part 3.

[0024] A determined proportion between the thicknesses of the dense outer casings 2 and the inner honeycomb part 3 must be obtained. This is the same for the ratio between the densities of these two parts. The proportion of the inner honeycomb part 3 must not be increased too much, at the risk that the sheet 1 is too insulative and that the diffusion of temperature through it is done too slowly. On the contrary, the proportion of outer casings 2 must not be increased too much either, at the risk that the sheet 1 is not insulative enough and that the diffusion of temperature through it is made too quickly.

[0025] The dense outer casings 2 also give an adequate rigidity to the sheet in order to give it the support thereof in the container 4. To reach an ideal insulation, the sheet of cork 1 must have a low density. The problem which occurs, is that the sheet 1 is thereby too flexible and is not supported correctly. Two solutions can be considered. A first solution would be to increase the thickness of the sheet 1, which would decrease the useful volume of the container 4, which is a crucial element to optimise in the field of transportation. The second solution would be to increase the density of the sheet 1 such that it supports itself, but the insulation would be decreased and there would be a risk of heat shock. In order to reach one same insulation with a sufficient density to support the sheet 1, the thickness of this sheet 1 must be increased and from then, the useful volume of the container 4 must be decreased.

[0026] To preserve an adequate insulation with a wall thickness as low as possible, a person skilled in the art would, on the other hand, be led to think to use a sheet of low density cork but reinforced by another rigid material. They would not think about compressing the cork wall in order to give it more rigid outer surfaces 2 to keep the inner part 3 insulative.

[0027] The isothermic container 4 in FIG. 2 seen from above, uses inner diffusing sheets 1 of compressed cork. In concrete terms, the isothermic container 4 comprises walls around a volume 5 able to receive the content to hold at a certain temperature. The container 4 is characterised in that each wall comprises an outer sheet of cork 6, a space 7 which could contain, and here containing, at least one heat source 8 and one inner sheet 1 produced by compressing cork. Said inner sheet 1 separates the heat source 8 from the content located in the volume 5. In addition, said inner sheet 1 has a higher density of the outer surfaces 2 than the density of the inner part 3 thereof in order to diffuse the temperature as desired. The geometry of the inner sheet 1 will use the transmission speed of the temperature of the heat sources 8 towards the volume 5 able to receive the content which must be kept at a certain temperature. Indeed, according to the thickness of the sublayers 2 and 3 in the inner sheet 1 and the densities of these sublayers 2 and 3, the diffusion of the temperature is done more or less quickly. This enables to manage the diffusion time, according, for example, to the transportation time of the content having to be kept under a controlled temperature.

[0028] In addition, the outer sheet 6 has a lower density than the inner sheet 1 in order to make the heat flow be directed towards the volume 5, and not towards the outside of the container 4.

[0029] As a heat source, ice packs, containers of a hot liquid, etc. can be considered.

[0030] In certain cases, the isothermic container 4, of which the walls form a primary isothermic space 5, can be put into an outer packaging with a secondary space 11 for separation and protection from the primary isothermic space 5. Indeed, the container is, in certain cases, placed in a packaging, which enables it to have a cover 10 and a bottom 9. This packaging, which can be made of cardboard, for example, is practical for transportation.

[0031] Packaging is a means for separation and protection. But in most cases, the container itself already comprises a bottom and a cover. Packaging thereby only adds an additional cover 10 and an additional bottom 9 to the container 4.

[0032] The space 7 can contain a heat source, but, in certain cases, this can be done without. Indeed, the container of the invention can be used simply by using the fact that the outer walls, during transportation or storage, let the outside temperature pass through little by little, the outer walls regulate the passage of this temperature.

[0033] According to a preferred embodiment of the invention, the isothermic container 4 has the shape of a parallelepiped rectangle.