FR3123112A1 - Portable cooling device - Google Patents

Abstract

The invention relates to a portable cooling device (100) comprising a body (101) delimited by a thermally insulated wall (102), with a removable lid (103) which is also thermally insulated and allowing access to the interior of a cavity (104) included in the body (101) of the cooling device (100), said portable cooling device (100) further comprising a refrigeration unit allowing the production of cold comprising a compressor, a condenser, an evaporator (116) and a supply system, characterized in that said refrigerating device (100) comprises a tank (106) for storing elements to be refrigerated housed in said cavity (104) of the body (101), said evaporator (116) being positioned in a space (117) of the said cavity (104) of the body (101) between the tank (106) and the thermally insulated wall (102), the said evaporator (116) being in particular embedded in a eutectic material also placed in the said cavity (104 ) of the body (101). Figure for abstract: Fig. 1

Description

Portable cooling device

Technical field of the invention

The invention relates to a portable cooling device. It falls within the field of refrigerating devices for storing items to be cooled, in particular foodstuffs, and relates more particularly to an autonomous refrigerating device in energy production comprising a removable storage tank, for domestic or professional use.

The cooling devices known from the prior art, also called coolers, generally comprise a body delimited by a thermally insulated wall, forming a cavity for receiving elements to be maintained at a relatively low temperature compared to the outside temperature, and a movable or even removable element, for example a cover, also thermally insulated, allowing access to the interior of the cooler and therefore of said cavity. The refrigeration devices further comprise a refrigeration unit allowing the production of cold for the refrigeration of the elements placed in the cavity of the refrigeration device. This refrigeration unit can produce cold, for example, by a sorption process well known to those skilled in the art, for example using a zeolite/water couple (the zeolite being the sorbent), an evaporator and an exchanger. An example of a refrigerating device as cited above is presented in European Patent Application No. EP 1 361 402. The refrigeration unit may also include a compressor and a condenser for extended cooling times. The refrigeration unit is then generally powered by electric batteries whose autonomy is limited, these batteries having to be recharged by an external 12-24 volt or 220 volt power supply, which requires a nearby power outlet with various accessories to be able to connect according to the power supply source (for example for a vehicle cigarette lighter socket).

Carrying means are often associated with cooling devices, for example a handle or a strap.

Depending on the type of items transported in the cavity of a refrigerating device, it may be important to clean and disinfect said cavity, especially when foodstuffs have been stored there. Indeed, in such a case, it is necessary to clean the cavity daily with hot water and detergent products. For example, when milk has remained or circulated in contact with equipment, it always leaves a residue in the form of a film or more or less significant deposits. These residues accumulate particularly in the angular, hollow or protruding parts of the cavities of conventional cooling devices. Left in the air, said residues dry out quickly, adhering strongly to their support. With each addition of milk or other foodstuff, new residues form and attach to the previous ones. In a short time, these successive layers constitute a tenacious coating which is all the more difficult to eliminate as it is older. The residues formed are always difficult to eliminate due to their composition (fat, proteins, sugar, mineral salts, etc.) and the strength with which they adhere to the walls. These residues serve as a protective support for the bacteria which, moreover, find there the nutritive substances necessary for their development. It is therefore essential to proceed with the complete cleaning of the cavity immediately after the evacuation of the foodstuff placed in the cavity. Water alone, even hot, is not enough. It must be accompanied by products called detergents, with special properties. The detergent solutions must in particular make it possible to detach the residues, to dissolve them, to put them in solution or in suspension and to prevent them from redepositing on the surfaces. In addition, these solutions must be able to be completely removed from the cleaned surfaces by rinsing with water. Under no circumstances should they corrode the materials or be toxic in the event that, following insufficient rinsing, a small quantity comes into contact with the foodstuff stored in the cavity following washing. Finally, they must prevent so-called hard water, that is to say water loaded with calcareous salts, from forming scale deposits on the equipment. To meet these properties, detergents must be composed of various substances carefully selected and mixed in suitable proportions. This is why it is always advisable not to use a simple product (trisodium phosphate, soda ash, etc.) but special mixtures well suited to the nature of the residues, the type of equipment and material and the cleaning method. .

It therefore appears necessary to provide an autonomous transportable cooling device whose manufacture is facilitated, cold production improved over time and cleaning facilitated.

Presentation of the invention

To this end, the invention relates to a portable cooling device comprising a body delimited by a thermally insulated wall, with a removable cover that is also thermally insulated and allowing access to the interior of a cavity included in the body of the cooling device, said portable refrigerating device further comprising a refrigeration unit allowing the production of cold comprising a compressor, a condenser, an evaporator, and a supply system, said refrigerating device comprising a tank for storing elements to be refrigerated housed in said cavity of the body, said evaporator being positioned in a space of said cavity of the body between the tank and the thermally insulated wall, said evaporator being in particular embedded in a eutectic material also disposed in said cavity of the body.

By supply system is meant a system configured to supply the refrigerating device with energy, for example electrical energy, so that the refrigerating device can operate, that is to say in particular so that the refrigerating unit can produce cold.

The refrigeration unit generates cold which is transmitted to the tank via the evaporator. The eutectic material advantageously makes it possible to store the cold produced by the refrigeration unit and to restore it to the tank over time without thus needing to operate the refrigeration unit continuously, thus advantageously making it possible to refrigerate any element positioned in the tank, for example foodstuffs, over an extended period of time and reducing the energy consumption of the refrigeration unit.

The fact that the evaporator and the eutectic material are located directly in a space of the cavity between the tank and the thermally insulated wall, rather than in a separate compartment of the cavity of the body of the refrigeration device improves the thermal conductivity between evaporator and tank due to the absence of an additional thermal barrier that such a separate compartment would have created. In addition, the manufacture of the refrigeration device is thereby facilitated and less expensive. Indeed, the creation of a special compartment would have posed an additional problem in the manufacturing process since it would have been necessary to place the evaporator and the eutectic material before closing this compartment hermetically. In addition, the refrigerating device that is the subject of the present invention advantageously does not have a heat transfer fluid circulation system for cooling that refrigeration units have in a conventional manner. This therefore further advantageously reduces the manufacturing cost of said cooling device.

Preferably, the compressor used in the refrigerating device that is the subject of the present invention is a brushless motor compressor ( "brushless" in English terminology) with low-speed start-up (2000 rpm) and gradual acceleration (up to 3500 rpm ), with no inrush current peak.

In particular embodiments, the invention also responds to the following characteristics, implemented separately or in each of their technically effective combinations.

In particular embodiments of the invention, the evaporator is a plate evaporator of the roll-bond type. Roll-bond type plate evaporators are well known to those skilled in the art. These are evaporators comprising an evaporation plate with integrated tubes ( “roll-bonded” in Anglo-Saxon terminology). Preferably, the evaporator used for the cooling device which is the subject of the present invention has integrated direct expansion.

In particular embodiments of the invention, the space of the cavity between the tank and the thermally insulated wall is hermetically sealed by a removable closing element. Preferably this removable closure element is made of metal. Preferably, this removable closure element comprises at least one seal, for example made of rubber. The closure element provides the advantage of protecting the space of the cavity between the tank and the thermally insulated wall, from any intrusion by an element which would be transported in the tank. This is particularly advantageous when the tank contains a liquid, the latter being able to overflow from the tank if the device is moved. The closing element then prevents the liquid from penetrating into the cavity space between the tank and the thermally insulated wall.

In particular embodiments of the invention, the eutectic material is a gel, preferably a gel comprising water and monopropylene glycol or a gel comprising water and monoethylene glycol. This gel improves the thermal conductivity between the evaporator and the tank. Preferably, the eutectic material used for the present invention has the property of liquefying at a constant temperature of 0°C. The fact that the conductivity of the ice is low, with a value of 2.1 Wm ^-1 .K ^-1 at 0°C, allows a slow transfer to the tank of the cold stored. Preferably, the eutectic material is chosen so that its freezing point has a difference of 6 to 8° C. with the final temperature to be reached in the tank. This allows better controlled heat exchanges (without regulation). Preferably, the eutectic material has a freezing point of between -2°C and -4°C. In addition to a better controlled heat exchange, this also makes it possible to limit the risk of freezing of a foodstuff present in the tank, for example milk whose freezing temperature is -0.5°C.

In particular embodiments of the invention, the MCP gel comprises expanded natural graphite positioned in the gel, preferably in the form of compressed strips or compressed clusters. This improves the thermal conductivity of the MCP.

In particular embodiments of the invention, the tank comprises an interior devoid of angular, hollow or projecting parts. This advantageously makes it possible to reduce the presence of residues of elements transported in the tank, in particular when it comes to foodstuffs and particularly liquid foodstuffs. According to a particular embodiment, the tank comprises an ovoid-shaped bottom. This shape also makes it possible to reduce the presence of residues of elements transported in the tank.

In particular embodiments of the invention, the tank is cylindrical in shape. In these embodiments where the tank is cylindrical, the removable closing element closing the space of the cavity between the tank and the thermally insulated wall is a crown, preferably metallic. Said crown can be fixed on the body of the cooling device. The crown preferably comprises a seal, for example made of rubber. This seal is preferably positioned between the tank and the crown.

In particular embodiments of the invention, the cavity of the body of the cooling device comprises an evacuation bung, the tank and the evacuation bung being configured to cooperate together so that when the tank contains a liquid, the liquid can be evacuated from the tank through the drain plug. This drain plug is advantageous because it allows the evacuation of a liquid present in the tank.

In particular embodiments of the invention, the cooling device comprises an evacuation circuit, one end of said evacuation circuit being connected to the evacuation bung and another end of the evacuation circuit being arranged at the exterior of the cooling device.

In particular embodiments of the invention, the cooling device comprises means for activating and deactivating evacuation via the evacuation bung and/or the evacuation circuit. Such means comprise for example a tap with an open position activating the evacuation and a closed position deactivating the evacuation.

In particular embodiments of the present invention, the tank is removable. The fact that the tank is removable is advantageous for the operations of cleaning or replacing the latter. In such an embodiment, the tank is for example removably fixed to the body of the cooling device, to the evacuation bung or even to the evacuation circuit, by removable fixing means. These removable fastening means may for example comprise a screw cooperating with a threaded hole in the body of the cooling device.

In particular embodiments of the present invention the tank is made of aluminum. The advantage of an aluminum tank is that this material improves the thermal conductivity of the tank and the forming of the tank by spinning is facilitated with very low investment in tooling. According to a preferred embodiment, the tank is made of aluminum having undergone a surface treatment by anodization. Such treatment reinforces the solidity of the tank. In other particular embodiments of the present invention, the tank is made of aluminum having undergone a surface treatment by covering with a food-grade thermosetting paint. Food-grade paint means paint subject to regulations relating to contact with foodstuffs. This paint notably guarantees chemical safety and allows easy disinfection and cleaning of the tank. In other particular embodiments of the present invention the tank is made of stainless steel.

In particular embodiments of the present invention, the cooling device comprises a system for disinfection of the inside of the tank and at least part of its contents. Preferably, the disinfection system includes a UV lamp powered by the power system. This system advantageously makes it possible to sterilize the interior of the tank and at least on the surface the elements placed in the tank, by eliminating approximately 99% of the bacteria (such as Escherichia Coli , Salmonella , etc.) and viruses. In preferred embodiments, the disinfection system comprises means for agitating the elements present in the tank. These agitation means are particularly advantageous when a liquid transparent to UV radiation is stored in the tank in order to sterilize a greater part of it (not only the surface). According to an exemplary embodiment of the invention, the stirring means comprise a circulation pump. The circulation pump is configured to suck in a liquid present in the tank and to discharge it into the tank, preferably close to the bottom of the tank, with a speed allowing dynamic mixing of the liquid. According to another exemplary embodiment of the invention, the stirring means comprise a rotating blade configured to rotate in the tank either under the manual action of a user or driven by a motor, said rotating blade thus creating a movement of convection within a liquid present in the tank and thus mixing the latter. According to another exemplary embodiment of the invention, the stirring means comprise a circulation pump and at least one rotating blade.

In particular embodiments of the invention, the cooling device comprises at least one photovoltaic panel and the supply system is configured to supply the cooling device with electrical energy from solar energy captured by said photovoltaic panels. Preferably, the power supply system directly supplies the refrigerating device, in particular the compressor, with direct current, for example from 22V to 42V, from solar energy captured by the photovoltaic panel or from another current source. continued. The power supply is advantageously done without energy conversion, that is to say, the direct current from the photovoltaic panels is directly transmitted to the compressor without transforming it into alternating current 110V, 220V or 400V, without rectifying it or regulate at a fixed voltage.

In particular embodiments of the invention, the refrigerating device comprises a management unit comprising means for measuring the energy available for the supply system and means for controlling the compressor, in particular its speed, as a function measured available energy. In particular embodiments, the management unit further comprises means for controlling the disinfection system according to the measured available energy.

Brief description of figures

The invention will be better understood on reading the following description, given by way of non-limiting example, and made with reference to the figures which represent:

the illustrates an overview of the portable cooling device according to one embodiment of the present invention;

the illustrates a longitudinal sectional view of the portable cooling device according to one embodiment of the present invention;

the illustrates a zoom of the longitudinal section view of the .

In these figures, identical reference numerals from one figure to another designate identical or similar elements. Also, for reasons of clarity, the drawings are not to scale, unless otherwise stated.

In the present mode of implementation, given here by way of illustration and not limitation, a portable cooling device according to the invention is used in particular in the context of the refrigeration and transport of foodstuffs and is particularly suitable for refrigeration and transport. of liquids.

As shown in , the portable cooling device 100 comprises a body 101 delimited by a thermally insulated wall 102, with a removable cover 103 also thermally insulated and allowing access to the interior of a cavity 104 included in the body 101 of the cooling device 100. The wall 102 delimiting the body 101 is preferably rotomolded polyethylene. The body 101 comprises an insulating material, preferably an insulating polyurethane foam. The body 101 is preferably cylindrical as illustrated in and comprises at least one foot 105, preferably four feet 105 so as to promote the stability of the cooling device 100 when it is placed on a surface.

The refrigerating device 100 comprises a tank 106 for storing elements to be refrigerated housed in the cavity 104 of the body 101. As illustrated in , this tank 106 is cylindrical in shape with a bottom 107 devoid of angular, hollow or projecting parts, for example a bottom 107 of ovoid shape. The tank 106 is made of aluminum, preferably of aluminum having undergone a surface treatment by anodization. Preferably, the tank 106 is made of thermo-lacquered aluminum.

The cavity 104 of the body 101 of the cooling device 100 comprises an evacuation bung 108, the tank 106 and the evacuation bung 108 being configured to cooperate together so that when the tank 106 contains a liquid, the liquid can be evacuated from the tank 106 through the drain plug 108 if necessary. For this purpose, the tank 106 comprises a bottom 107 with holes at the level of a zone of the bottom 107 cooperating with the evacuation bung 108 ( ). Thus a liquid present in the tank 106 can pass through the hole or holes 109 arranged in the said bottom zone 107 cooperating with the evacuation bung 108 and reach the said evacuation bung 108. An evacuation circuit 110 is also included. in the cooling device 100 and one end of said evacuation circuit 110 is connected to the evacuation bung 108 and another end of the evacuation circuit 110 is placed outside the cooling device 100. This evacuation bung 108 is particularly advantageous when the tank 106 is used to transport a liquid to be refrigerated. The liquid can thus be evacuated from the tank 106 and from the cooling device 100 by the evacuation plug 108 then by the evacuation circuit 110 without opening the cover 103 of the cooling device 100 and thus avoiding a significant change in temperature in the tank 106 (prevents the loss of cold). The drain plug 108 is preferably made of polypropylene.

A part 111 of the body 101 of the cooling device 100 is gripped between the tank 106 and the drain plug 108 so that the cooperation between the tank 106 and the drain plug 108 is liquid tight. Preferably, the cooling device 100 comprises a first seal 112 between said part 111 of the body 101 taken in embrace and the tank 106 as well as a second seal 113 between said part 111 of the body 101 taken in embrace and the drain plug 108.

The tank 106 is preferably removable and can therefore be removed from the cavity 104 of the body 101 of the cooling device 100 if necessary, for example for a cleaning operation of the tank 106. The tank 106 is arranged in a removable manner in the cavity 104 of the body 101 of the cooling device 100 using removable fixing means. These removable fastening means may for example comprise a screw 114 cooperating with a threaded hole in the body 101 of the cooling device 100 or as illustrated in with a threaded hole 115 in the drain plug 108.

The refrigeration device 100 further comprises a refrigeration unit allowing the production of cold. This refrigeration unit comprises a compressor (not visible in the figures), a condenser (not visible in the figures), an evaporator 116 ( ), and a feed system (not visible in the figures).

The evaporator 116 is of the roll-bond type plate and is positioned in a space 117 of said cavity 104 of the body 101 between the tank 106 and the thermally insulated wall 102. The evaporator 116 thus surrounds the tank 106. The evaporator 116 thus positioned in the space 117 of said cavity 104 of the body 101 between the tank 106 and the wall 102 is kept at a distance from the tank 106 and the wall 102 by at least one, preferably several first wedges 118 positioned between the tank 106 and the evaporator 116 and at least one, preferably several second wedges 119 positioned between the wall 102 and the evaporator 116.

The evaporator 116 is in particular embedded in a eutectic material. Around the evaporator 116, the eutectic material (not visible in the figures) fills the rest of the space 117 of said cavity 104 of the body 101, between the tank 106 and the thermally insulated wall 102. The eutectic material is in the present embodiment a gel also called eutectic gel. This gel surrounds the evaporator 116 and improves the thermal conductivity between the evaporator 116 and the tank 106. This gel notably comprises expanded natural graphite, preferably in the form of compressed strips or compressed clusters. This further improves the thermal conductivity of the eutectic material.

The space 117 of the cavity 104 between the tank 106 and the thermally insulated wall 102 is hermetically sealed by a removable closing element 120. The closing element 120 is made of metal. The closure element 120 comprises at least a third seal 121, for example rubber, disposed between the tank 106 and said closure element 120. As illustrated in Figures 1 and 2, in the present embodiment the removable closing element 120 closing the space 117 of the cavity 104 between the tank 106 and the wall 102 is a metal crown. Said crown can be fixed in a removable manner on the body 101 of the cooling device 100 and/or on the tank 106.

The cooling device 100 comprises a disinfection system (not shown in the figures) of the interior of the tank 106 and its contents. Preferably, the disinfection system includes a UV lamp powered by the power system. The disinfection system further comprises means for agitating the elements present in the tank 106. According to one embodiment of the invention, the agitation means comprise a circulation pump and/or at least one rotating blade.

The cooling device 100 comprises at least one, preferably several photovoltaic panels (not shown in the figures) and the power supply system is configured to supply the cooling device 100 with electrical energy from solar energy captured by said photovoltaic panels. The power supply system directly supplies the cooling device 100, in particular the compressor, with direct current from 22V to 42V, from solar energy captured by the photovoltaic panels or from another source of direct current.

The refrigerating device 100 also comprises a management unit (not visible in the figures) comprising means for measuring the energy available for the supply system and means for controlling the compressor, in particular its speed, as a function of the measured available energy. This management unit further comprises means for controlling the disinfection system according to the measured available energy.

Preferably, the management unit comprises means for measuring the voltage delivered by the photovoltaic panels and means for controlling the compressor configured so that the compressor cannot start when the voltage delivered by the measured photovoltaic panels is below a certain voltage threshold determined beforehand. The voltage threshold preferably corresponds to the minimum power necessary to start the compressor. The threshold is chosen according to the maximum voltage value accepted by the compressor and according to the open circuit voltage delivered by the photovoltaic panel or panels.

According to a preferred embodiment of the invention, the device comprises at least one photovoltaic panel of sixty polycrystalline photovoltaic cells, the compressor accepts a maximum voltage of 42V and the previously determined voltage threshold is 30V.

More generally, it should be noted that the modes of implementation and embodiment of the invention considered above have been described by way of non-limiting examples and that other variants are therefore possible.

Claims (15)

Portable cooling device (100) comprising a body (101) delimited by a thermally insulated wall (102), with a removable lid (103) also thermally insulated and allowing access to the interior of a cavity (104) included in the body (101) of the refrigerating device (100), said portable refrigerating device (100) further comprising a refrigeration unit allowing the production of cold comprising a compressor, a condenser, an evaporator (116) and a supply system, characterized in that said refrigerating device (100) comprises a tank (106) for storing elements to be refrigerated housed in said cavity (104) of the body (101), said evaporator (116) being positioned in a space (117) of the said cavity (104) of the body (101) between the tank (106) and the thermally insulated wall (102), the said evaporator (116) being in particular embedded in a eutectic material also placed in the said cavity (104) of the body (101 ). A portable cooling device (100) according to claim 1, wherein the tank (106) is removable. A portable refrigeration device (100) according to any one of claims 1 to 2, wherein the evaporator (116) is a roll-bond type plate evaporator. A portable cooling device (100) according to any one of claims 1 to 3, wherein the eutectic material is a gel. A portable cooling device (100) according to claim 4, wherein the gel comprises expanded natural graphite positioned in the gel preferably in the form of compressed rods or compressed clusters. Portable cooling device (100) according to any one of claims 1 to 5, in which the space (117) of the cavity (104) between the tank (106) and the thermally insulated wall (102) is hermetically sealed by a removable closure element (120). A portable cooling device (100) according to any one of claims 1 to 6, wherein the vessel (106) comprises an interior free of angled, hollow or projecting parts. Portable cooling device (100) according to any one of claims 1 to 7, in which the tank (106) is made of aluminum or of aluminum having undergone a surface treatment by anodization. Portable cooling device (100) according to any one of claims 1 to 8, the cavity (104) of the body of the cooling device (100) comprising an evacuation plug (108), the tank (106) and the drain (108) being configured to cooperate together so that when the tank (106) contains liquid, the liquid can be drained from the tank (106) through the drain plug (108). Portable refrigerating device (100) according to claim 9, comprising an evacuation circuit (110), one end of said evacuation circuit (110) being connected to the evacuation bung (108) and another end of the circuit drain (110) being disposed outside the cooling device (100). Portable cooling device (100) according to any one of Claims 1 to 10, comprising a system for disinfection of the inside of the tank (106) and at least part of its contents. A portable refrigeration device (100) according to claim 11, wherein the disinfection system comprises a UV lamp powered by the power system. Portable refrigerating device (100) according to any one of claims 11 to 12, the disinfection system comprises means for agitating the elements present in the tank (106). Portable cooling device (100) according to any one of claims 1 to 13, comprising at least one photovoltaic panel, the supply system being configured to supply the cooling device (100) with electrical energy from solar energy captured by said photovoltaic panels. Portable refrigerating device (100) according to any one of Claims 1 to 14, comprising a management unit comprising means for measuring the energy available for the supply system and means for controlling the compressor, in particular its speed, depending on the measured available energy.