NL1021279C2 - Liquid heat storage medium for body warming devices, contains particles with poor thermal conductivity - Google Patents

Abstract

Particles with a poor thermal conductivity are present in the liquid. A liquid heat storage medium contains particles with a relatively poor thermal conductivity in order to prevent the formation of thermal currents in the medium. Independent claims are also included for the following:Container (2) filled with the heat storage medium; and Cover (6) for the container, having one side wall comprising a thick insulation layer (14) with a reflective lining (18) on the inner side and another side wall comprising a thin insulation layer (16).

Description

Brief description: A fluid-containing, heat-accumulating, composition; method for manufacturing thereof; container filled with such a composition and enclosure for such a container.

The invention relates to a flowing, heat-accumulating composition; to a method of manufacturing 5; on a container filled with such a composition and also on an enclosure for such a container.

The use of a flowing substance as a heat accumulator has long been known per se as, for example, in the hot water bottle filled with hot water: it has been used since time immemorial for the local treatment of body disorders or for keeping people and animals warm. There is always the drawback that the heat emission is not uniform: there is a first stage in which relatively much of the accumulated heat is undesirably released, followed by a second stage in which the heat emission is noticeably lower. This is stressful for the user and disadvantageous for the treatment.

The invention has for its object to obviate this drawback and to this end it is proposed according to the invention that particles with poorer heat conduction are dispersed in the composition for delaying the heat flow occurring in the composition.

By thus increasing, as it were in practice, the internal resistance to heat flow in the composition, it is effectively achieved that the heat emission by an amount of this composition is considerably more uniform, which is more pleasant for the treated person but also by the controlled heat emission makes the treatment as such considerably more effective and while the available heat capacity of a given amount of composition is used optimally.

According to the invention, said particles are preferably formed by very small, per se known, gas-filled plastic spheres - so-called microspheres. Such microspheres are known per se and are marketed under the registered 1021279-2 brand name "Expancel®"; the product is a development by Akzo Nobel. Such microspheres consist of a gas enclosing polymer shell. In the unexpanded state, the diameter thereof is between 10 and 17 μπ; the density 5 is 1000 to 1300 kg / m3. Heating the microspheres with the enclosed gas leads to a softening of the envelope and a far-reaching increase in the volume of the microspheres: more than 40 times the originally enclosed volume is possible. For further explanation, reference is made to the brochure "Expancel® Microspheres, an introduction" from the company Expancel (www.expancel.com).

According to the invention, it is preferable if the microspheres are present in the expanded state, their content is between 2 and 10% by weight, and is preferably substantially equal to 4% by weight. According to the invention it is advantageous if the composition also contains a thickener so that the flowing substance is then in fact a gel. Laponite and Xanthan gon are suitable as thickeners, preferably with a content of 3% by weight.

Further advantages are obtained when a boiling point-increasing substance is added to the composition, for example calcium chloride in a dosage of 3 g mol / liter. With this measure it is achieved that the total amount of heat that can possibly be accumulated can be increased in accordance with the increase in boiling point achieved, while at the same time a higher end temperature favorable for the expansion of the microspheres can be achieved.

The invention further relates to a method for manufacturing a heat-accumulating composition as described in claim 13.

The requested exclusive rights furthermore comprise a holder 30 as subject of claims 14 and 15 and an enclosure for such a holder as described in claims 16-18.

The invention will be explained in more detail below, partly with reference to a drawing of a preferred embodiment of the enclosure. In the drawing: FIG. 1 is a perspective view of a container filled with the heat-accumulating composition according to the invention; Fig. 2 is a perspective view of an enclosure for such a container; 1

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3 is a cross-sectional view of this enclosure; and Fig. 4 shows a partial cross-section of this enclosure at the place where an indicator indicating the temperature of the container is arranged.

The preparation of the heat-accumulating composition according to the invention is simple: a desired amount of the fluid used, for example water or ammonia, is mixed with the desired amount of Expancel Microspheres. Use can be made of already expanded microspheres. It is also possible to introduce non-expanded microspheres into the flowing substance and then heat the whole to a final temperature of 100-120 ° C. If water is used, possibly mixed with 3% by weight of thickener, the achievable final temperature is determined by the boiling point of this mixture, approximately 100 ° C. As can be seen from the data that can be derived from the brochure mentioned in the preamble, a noticeable expansion of microspheres is then already obtained. However, if at least 3 g of mol per liter of calcium chloride is added to the liquid, the boiling point of the liquid will be increased to approximately 120 ° C and an even greater expansion will be possible, namely if Expancel 642 microspheres are used up to 35-40 times the original volume thereof. Moreover, as already stated, the amount of heat to be accumulated then increases proportionally.

EXAMPLE

10 1 of water is mixed with 400 g of already expanded Expancel® Microspheres, type 551 WE and 30 g of calcium chloride molecule is added to this mixture. Then another 300 g of thickener, for example Laponite or Xanthan gon, are added. The heat-accumulating gel thus obtained has the desired properties described above.

A holder for such a gel is shown in perspective as an example in Fig. 1. The holder, indicated in its entirety by reference numeral 2, is an elongated parallelepid-shaped, flat body 4, with dimensions of, for example, length (1) = 60 cm, width (b) = 25 cm and height (h) = 1.5 cm. The container can be made of relatively sturdy material and thus be dimensionally stable, but can also consist of a flexible bag. In both cases, the container can easily be filled with the heat-accumulating composition according to the invention using the techniques known per se and sealed in a sealing manner. Such a container can be heated in a microwave oven or in boiling water.

FIG. 2 shows this holder 2 arranged in an enclosure 6 which is in fact an elongated cover with a closing flap 8 which can be folded inwards in the manner of an envelope closure. This cover can consist of material that is sterilizable and thus can be reused, but it can also be a one-time cover made of, for example, a suitable paper or textile. A temperature indicating strip 10 is provided on the holder, which strip will be further elucidated with reference to Fig. 4.

FIG. 3 is a cross-section of this enclosure 6 which, as the figure shows, here consists of a first outer wall 8, a second outer wall 10, a first inner wall 12 and a second inner wall 14. Between the first outer wall 8 and the first inner wall 12 is a relatively thick, insulating layer of insulating material 14 is provided and a second, thinner layer of insulating material 16 is provided between the second outer wall 10 and the second inner wall 14.

Furthermore, the first inner wall 12 is covered with a reflective foil 18.

The result of these measures will be that there is a considerably better heat transfer from the holder 2 to the first outer wall 10, which is then also the wall that will be transferred to the object to be heated, for instance a part of the body of a patient. turned. Due to the combination of reflective layer 18 and thicker insulating layer 14, the heat losses through the first outer wall 8 will only be small and due to the measures described above, the heat transfer to the desired location, for example a patient to be treated, will be well controlled.

FIG. 4 shows a longitudinal section through the container described above at the location of the heat-indicating strip 10.

Such strips are known per se; they exhibit a color that varies as a function of its temperature. In the embodiment shown, the strip 10 is connected to a connecting strip 20 passing through the first outer wall 8, the insulation 14 and the first inner wall 12, in heat-conducting connection with a scanning strip. 22 which rests against the top of the holder 2. Thus, the strip will have a temperature that is closely related to the temperature of the holder 2, so that a reliable indication of the temperature of the latter is obtained in a simple manner.

It will be clear that the subjects of the present invention are suitable not only for metered-off heat transfer to an object, but also for metered and uniform heat absorption from an object, and thus can also be used as a coolant or cooling element.

Claims (18)

A fluid-containing heat-accumulating composition, characterized by particles dispersed therein with poorer heat conduction for retarding a heat flow occurring in this composition. Composition according to claim 1, characterized in that these particles consist of very small gas-filled plastic spheres (microspheres). 10 Composition according to claim 2, characterized in that the microspheres are present in the expanded state. 4. Composition according to claim 2-3, characterized in that the content of microspheres is between 2 and 10% by weight. Composition according to claim 4, characterized in that the content of microspheres is approximately 4% by weight. Composition according to claims 1-5, characterized in that it also contains a thickener. Composition according to claim 6, characterized in that the thickener consists of Laponite or Xanthan gon. 25 A composition according to claims 6-7, characterized in that the thickener content is approximately 3% by weight. 9. Composition as claimed in claims 1-8, characterized in that it further comprises a substance which increases the boiling point of the flowing substance. Composition according to claim 9, characterized in that this substance is formed by calcium chloride and the content thereof is 35 g / mol per liter. Composition according to claims 1-10, characterized in that the flowing material consists of water. A composition according to claims 1 to 10, characterized in that the flowing substance consists of ammonia. 5 A method for manufacturing a composition according to claims 2-12, characterized in that the microspheres are mixed in the expanded state by the flowing substance. 10 A heat-accumulating container according to one or more of claims 1-12. 15. Holder as claimed in claim 14, characterized by an upper and lower surface whose mutual distance is considerably smaller than the dimensions of these surfaces. 16. Enclosure intended for receiving a holder according to any of the claims 14-15, characterized in that the one, the two, wall facing towards a holder side surface is provided with a thick insulating layer with the interior of the holder. container-facing reflective coating, and the other is formed by a thinner, heat-permeable layer. 17. Enclosure as claimed in claim 16, characterized in that the two outer surfaces thereof are designed with mutually different colors. 18. Casing according to claim 18-19. characterized in that it is provided with an indicator indicating the temperature of a container included therein by discoloration. O