NL1030399C2 - Method and device are for feeding heat to a surface or for feeding heat away from a surface - Google Patents

Abstract

The method and device are for feeding heat to a surface or for feeding heat away from a surface. On or under the surface a sandwich is placed, comprising a first membrane, a layer prepared from a material with an open structure and a second membrane. A medium for heat transport is then allowed to flow through the space between the first and second membranes. The sandwich comprises a heat exchanger. The medium for heat transport is fed to one or more upper points of the heat exchanger and fed away from one or more lower points of the heat exchanger. The inward feed or outward feed of the medium for heat transport is so regulated that between the first and second membranes a pressure appertains which in at least the usage state is lower than the ambient air pressure. The heat exchanger (2) can be incorporated in an ice skating rink (1), a solar collector, a ski slope or an ice store. The second membrane involved rests on a flat base surface (3). The medium for heat transport, preferably a water/glycol mixture, is moved by a pump (4) through the heat exchanger via a central connection (5) and a number of peripheral connections (6a,6b...). The medium flows to a storage vessel (7) and via a cooling unit (8) back to the pump. The storage vessel is provided with an air pump (9), which maintains a pressure less than that atmospheric in the whole circuit.

Description

Method and device for supplying heat to a surface or dissipating heat from a surface. The invention relates to a method for supplying heat to at least one cohesive surface or for dissipating heat from at least one cohesive surface. For this method, which is known per se, the at least one coherent surface is generally covered with a tube system through which a medium for heat transport is passed. The method is used, for example, with solar collectors, but also with the realization of an artificial ice rink. The installation of a tubular system is expensive and cumbersome, especially if the surface is not flat. The method according to the invention obviates this drawback and is characterized in that a heat exchanger is provided on or below the at least one cohesive surface, consisting of a sandwich of at least a first membrane, a layer made of a material with an open structure and a second membrane, after which a medium for heat transport is passed through the heat exchanger. The term open structure must be understood to mean that the heat transfer medium can flow through this layer. Instead of installing a tube system, it is therefore sufficient to lay down the heat exchanger, after which it is ready for use. An important additional advantage is that the entire surface is cooled, because there is no tubular structure.

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With the heat exchanger an artificial ice rink or a ski slope can easily be realized by passing a cooled medium for heat transport through the heat exchanger and subsequently spreading water over the heat exchanger.

With the heat exchanger it is also possible to realize a solar collector 1030399 2, also at a difficult location such as an inclined and / or curved surface, by passing a heat transport medium through the heat exchanger and subsequently the heat thus collected with an additional heat exchanger from the heat transfer medium. An additional advantage is the low weight of the heat exchanger.

A favorable realization is characterized in that the heat transfer medium 10 is supplied to one or more high-lying points of the heat exchanger and is discharged from one or more low-lying points of the heat exchanger, so that gravity contributes to the transport and distribution of the heat exchanger. medium for heat transport in the heat exchanger.

According to a further aspect of the invention, a very favorable realization is characterized in that a supply and / or a discharge of the medium for heat transport is regulated such that a pressure prevails between the first membrane and the second membrane at least in a user lower than a prevailing air pressure. The advantage is that the underpressure holds the sandwich together, so that an attachment of the layer with an open structure to the first and second membrane is superfluous. An important additional advantage is that in the event of a possible leak in the first membrane or the second membrane, no medium for heat transport will leak out of the sandwich, but air will be sucked into the sandwich. The leakage of medium is very undesirable, because this, for example, affects the quality of the ice and moreover has a cost-increasing effect, while it is generally also undesirable that medium ends up in the environment. On the other hand, it is very easy to remove air from the cooling medium.

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The invention also relates to a device for cooling or heating an object consisting of at least one cohesive surface. The inventive device is characterized in that it comprises at least one sandwich-shaped heat exchanger, consisting of at least a first membrane, a layer of material with an open structure and a second membrane, as well as cooling means and / or heating means for cooling and / or heating a heat transfer medium and pumping means for pumping the heat transfer medium through the heat exchanger.

A favorable embodiment in which the risk of leakage of the sandwich-shaped heat exchanger leaking is limited to a minimum is characterized in that the first membrane and the second membrane are each made from a plastic with a high tensile strength.

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A further favorable embodiment is characterized in that the layer is made from a flexible material with an open structure, such as, for example, non-woven mats with an open structure, made from, for example, plastic or rock wool or glass wool. A heat exchanger can then simply be rolled out for use, while it will also connect better to a possibly non-flat surface.

A further favorable embodiment in which gravity contributes to the transport through and the distribution of the cooling medium in and through the sandwich-shaped heat exchanger is characterized in that near one or more high-lying positions the heat exchanger is provided with a first group of connections via which medium for heat transport is supplied and that near one or more low-lying positions the heat exchanger is provided with a second group of connections via which medium for heat transport is discharged.

A further favorable embodiment is characterized in that the pumping means comprise at least one discharge pump for supplying a medium for heat transport to the first group of connections. The pumping means also preferably comprise a suction pump for discharging heat-transporting medium from the second group of connections, as well as a control member for controlling the press pump and the suction pump in combination, such that a pressure prevails in the heat exchanger at least in a position of use which is lower than a prevailing air pressure. The advantage is that the underpressure holds the sandwich together, so that an attachment of the layer with an open structure to the first and second membrane is superfluous. An important additional advantage is that in the event of a possible leak in the first membrane or the second membrane, no medium for heat transport will leak out of the sandwich, but air will be sucked into the sandwich. The leakage of medium for heat transport is very undesirable, because this affects the quality of, for example, the ice cream and moreover has a cost-increasing effect, while it is moreover undesirable for medium for heat transport to end up in the environment. For removing air from the medium for heat transport, the device is then preferably also provided with a separator known per se.

The invention also relates to objects, such as a sculpture, ice cave, slope and the like, manufactured with the method or device as described in the preceding paragraphs.

The invention will now be further elucidated with reference to the following figures, in which:

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FIG. 1A schematically shows a possible embodiment of an ice rink according to the invention in side view;

FIG. 1B schematically represents a heat exchanger 5 according to the invention in cross section;

FIG. 2 schematically represents a solar collector according to the invention;

FIG. 3 schematically represents a possible embodiment of a ski slope according to the invention in side view;

FIG. 4 schematically represents a possible embodiment of an ice cave according to the invention in side view.

FIG. 1A schematically shows a possible embodiment of an ice rink 1 according to the invention in side view. Ice rink 1 comprises a heat exchanger 2 consisting of a sandwich of a first membrane, a layer made of a material with an open structure and a second membrane that rests on a flat surface 3. Via a pump 4 a medium for heat transport, for example a water / glycol mixture, is pumped around through heat exchanger 2 via a central connection 5 and a number of peripheral connections 6a, 6b, .. Subsequently, the medium for heat transport flows to a storage tank 7 and via a cooling unit 8 back to pump 4. Supply vessel 7 is provided with an air pump 9, which maintains a negative pressure in the entire circuit, including heat exchanger 2, so that the sandwich is held together. An additional advantage is that if a leak occurs in the first membrane or the second membrane of heat exchanger 2, air is sucked in which is subsequently pumped away by air pump 9. In that sense, storage tank 7 and air pump 9 form a separator. It is also easy to deduce from the amount of air pumped out by air pump 35 9 whether there is a leak. Pump 4 is provided with a control circuit 10 which controls the pressing force of pump 4 in a manner known per se such that a negative pressure is always maintained in heat exchanger 2. Once the heat transfer medium flows through heat exchanger 2, water can be flowed onto the top of heat exchanger 2, as a result of which an ice-skating ice rink will soon be formed. If the ice rink is to be cleaned up, it is sufficient to switch off the cooling unit 8 and pump 4 and once the ice 10 has melted, pump the medium for heat transport into reservoir 7 with the aid of pump 4.

Heat exchanger 2 can then be disconnected and taken along.

FIG. 1B schematically represents a heat exchanger 2 according to the invention in cross section. Heat exchanger 2 consists of a first membrane 11, a layer 12 made of a material with an open structure and a second membrane 13.

Membranes 11, 13 are made from a plastic with a high tensile strength, such as, for example, polyvinyl chloride with a polyester reinforcement. Layer 12 consists of, for example, non-woven sheets or mats made of, for example, plastic or rock wool or glass wool. If it is ensured that a constant underpressure prevails in heat exchanger 2, then layer 12 can in fact lie loosely in the envelope formed by membranes 11,13, which can considerably simplify the manufacture of heat exchanger 2 and keep the costs low.

Furthermore, layer 12 can be made flexible, making it possible for the heat exchanger, for example, to be used during the process. 30 transport.

FIG. 2 schematically represents a solar collector 14 according to the invention. Solar collector 14 comprises a heat exchanger 2 consisting of a sandwich of a first membrane, a layer made of a material with an open structure and a second membrane resting on a flat surface 3. Via a suction pump 15 a medium for heat transport, for example a water / glycol mixture, is pumped around a storage vessel 7, a heat storage 16, heat exchanger 2 via a central connection 5 and a number of peripheral connections 6a, 6b ,. . back to pressure pump 15. Heat storage 16 is, for example, of the type in which the state of aggregation of a substance changes. Supply vessel 7 is provided with an air pump 9, which maintains a negative pressure in the entire circuit, including heat exchanger 2, so that the sandwich is held together. An additional advantage is that if a leak occurs in the first membrane or the second membrane of heat exchanger 2, air is sucked in which is subsequently pumped away by air pump 9. Heat exchanger 2 can be laid on a flat surface, but can also be placed on a roof or on a slope, whereby the amount of collected solar heat can be increased.

FIG. 3 schematically shows a possible embodiment of a ski slope 17 according to the invention in side view. Ski slope 17 comprises a heat exchanger 2 consisting of a sandwich of a first membrane, a layer made of a flexible material with an open structure and a second membrane that rests on a sloping surface 18. Via a pump 4 a medium for heat transport, for example a water / glycol mixture, is supplied to one or more high-positioned connections 5 on heat exchanger 2, whereafter the medium for heat transport flows down through heat exchanger 30 to one or more low-placed connections 6 and via a suction pump 15 to a storage vessel 7 and via a cooling unit 8 back to pump 4. Storage vessel 7 is provided with an air pump 9, which maintains a negative pressure in the entire circuit, including heat exchanger 2, whereby the sandwich is held together. An additional advantage is that if a leak occurs in the first membrane or the second membrane of heat exchanger 2, air is sucked in which is subsequently pumped away by air pump 9. Pump 4 is provided with a control circuit 10 which controls the pressing force of pump 4 in a manner known per se such that a negative pressure is always maintained in heat exchanger 2. Once heat transfer medium flows through heat exchanger 2, water can be flowed onto the top of heat exchanger 2, whereby an ice layer will soon be formed which can then be covered with artificial snow in a manner known per se. It is of course also possible to apply the artificial snow directly to heat exchanger 2. If ski slope 16 is to be cleaned up, then it is sufficient to switch off cooling unit 8 and pump 4 and once the ice and / or snow has melted, pump the medium for heat transport into storage tank 7 using suction pump 15. Heat exchanger 2 can then be disconnected, rolled up and taken.

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FIG. 4 schematically shows a possible embodiment of an ice cave 19 according to the invention in side view. Ice cave 19 comprises a heat exchanger 2 consisting of a sandwich of two hemispherical membranes, between which a layer made of a material with an open structure is placed. Heat exchanger 2 is attached to a bottom 20 such that the space bounded by heat exchanger 2 and bottom 20 can be inflated until heat exchanger 2 has the shape 30 shown in the figure. Via a pump 4 a medium for heat transport, for example a water / glycol mixture, is supplied to a number of high-lying connections 5a, 5b, .. on heat exchanger 2 and discharged via a number of peripheral connections 6a, 6b, .. The medium then flows for 35 heat transport via a suction pump 15 to a storage tank 7 and via a cooling unit 8 back to pump 4. Storage tank 7 is provided with an air pump 9, which maintains a negative pressure in the entire circuit, including heat exchanger 2, so that the sandwich of the hemispherical membranes and the layer placed between them made of material with an open structure is held together. An additional advantage is that if a leak occurs in the first membrane or the second membrane of heat exchanger 2, air is drawn in which is subsequently pumped away by air pump 9. Pump 4 is provided with a control circuit 10 which controls the pressing force of pump 4 in a manner known per se such that a negative pressure is always maintained in heat exchanger 2. Once heat transfer medium flows through heat exchanger 2, water can be flowed onto the top of heat exchanger 2, on which an ice layer will soon be formed. If the ice layer is sufficiently thick, the air pressure in the space bounded by heat exchanger 2 and bottom 20 can be reduced to atmospheric pressure and the ice cave thus obtained can be put into use. If the ice cave is to be cleaned up, it is sufficient to switch off the cooling unit 8 and pump 4 and once the ice has melted, pump the medium for heat transport into reservoir 9 using suction pump 15. Heat exchanger 2 can then be disconnected, whereby at preferably an underpressure in heat exchanger 2 must be maintained. Then it can be folded and taken along.

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Claims (10)

Method for supplying heat to at least one coherent surface or for dissipating heat from at least one cohesive surface, characterized in that a heat exchanger is provided on or below the at least one cohesive surface, consisting of a sandwich of at least one a first membrane, a layer made of a material with an open structure and a second membrane, after which a medium for heat transport is passed through the heat exchanger. 2. Method as claimed in claim 1, characterized in that the medium for heat transport is supplied to one or more high-lying points of the heat exchanger and from a | one or more low points of the heat exchanger are discharged. 3. Method as claimed in claim 1 or 2, characterized in that a supply and / or a discharge of the medium for heat transport is regulated such that a pressure prevails between the first membrane and the second membrane which is at least lower in a position of use than a prevailing air pressure. 25 4. Device for cooling or heating an object consisting of at least one cohesive surface, characterized in that the device comprises at least one sandwich-shaped heat exchanger consisting of at least a first membrane, a layer made of a material with an open structure and a second membrane, as well as cooling means and / or heating means for cooling and / or heating a medium for heat transport and pumping means for pumping the medium for heat transport through the heat exchanger. 1 0303 9 9 Device according to claim 4, characterized in that the first membrane and the second membrane are each made from a plastic with a high tensile strength. 11 i Method according to claim 4 or 5, characterized in that the layer is made of a flexible material with an open structure. 7. Device as claimed in any of the claims 4-6, characterized in that near one or more high-lying positions the heat exchanger is provided with a first group of connections via which medium for heat transport is supplied and that near one or more low-lying positions heat exchanger is provided with a second group of connections via which medium is transported for heat transport. 8. Device as claimed in claim 7, characterized in that the pumping means comprise at least one pressure pump for supplying medium for heat transport to the first group of connections. 9. Device as claimed in claim 8, characterized in that the pumping means also comprise a suction pump for discharging medium for heat transport from the second group of connections, and a control member for controlling the press pump and the suction pump in combination such that at least in a state of use in the heat exchanger a pressure prevails that is lower than a prevailing air pressure. 30 10. Objects, such as a sculpture, ice cave or slope, manufactured with the method according to any one of claims 1 to 3. 1 030399