NL1003915C2 - Cooling device. - Google Patents

Abstract

Autonomously operating cooling unit for cooling a storage space (9) during a certain time. The cooling unit (1) contains a container (2) for a coolant and a number of pipes (14) and is provided with means (13) for making the air in the storage space circulate by using the increase in pressure caused by the evaporation of the coolant; the storage space (9) is equipped for the transport of foods in a frozen or cooled condition. The evaporation of a coolant causes: the cooling of the storage space (9); the circulation of the ambient air in the storage space (9); the drying of the ambient air; and thermally controlled cooling. <IMAGE>

Description

Cooling device

The invention relates to an autonomously operating cooling device for cooling a storage space for a specific period of time, which cooling device comprises a container for a cooling medium and a number of pipes.

Such cooling devices are known and are used in particular for cooling frozen foodstuffs during transport and distribution. This known cooling device comprises a container 10 for a cooling medium, for example liquid nitrogen or carbon dioxide in the solid state. Evaporation of the cooling medium means that heat is exchanged and the storage space is cooled.

These known devices have numerous drawbacks. The most important of these relate to the irregular cooling pattern caused by such a known device. Because the evaporation decreases over time and due to the lack of an adapted circulation of the ambient air present in the storage space, considerable temperature differences are observed in this storage space. The temperature in the storage space increases over time and from the bottom to the ceiling.

New EEC directives regarding the storage and transport of frozen foodstuffs prescribe a temperature of -18 ° C during the entire process of transport and storage. These known cooling devices cannot ensure such a stable cooling temperature.

The object of the invention is to eliminate the above drawbacks and to this end provide an autonomously operating cooling device characterized in that such a cooling device is provided with means for circulating the pressure of air present in the storage space caused by the evaporation of the cooling medium. Because a circulation is created, a good mixing of ambient air and evaporated cooling medium is obtained and thus a homogeneous temperature in the storage space.

Preferably, the means for circulating the ambient air comprises a conduit coupled to a venturi for causing an aspiration of the ambient air. Due to the acceleration of the evaporated cooling medium through a constriction - the venturi - is drawn in ambient air via a pipe, for example via a T-connection.

10 To protect the venturi against freezing, an element is provided between the ambient air pipe and the venturi. This element has a custom content measure. The moisture present in the ambient air is frozen solid by cooling the evaporated cooling medium.

The cooling medium thus fulfills three functions: - cooling of the storage space by heat transfer through the evaporated and / or liquid cooling medium; - freezing the moisture from the air drawn in 20 into an element with an adjusted volume, called the moisture trap; and - circulating the ambient air through the suction caused by acceleration of the evaporated cooling medium via the venturi.

In known cooling devices, the evaporated cooling medium only performs the first function.

Temperature measurement also makes it possible to cause an additional direct inflow of evaporated cooling medium via pressure-regulating elements and pipes. A thermally controlled cooling is thus obtained. The cooling device hereby obtains a thermostatic cooling capacity and the temperature in the storage space will remain constant irrespective of the prevailing outside temperature. Moreover, the introduction of this additional flow of evaporated cooling medium results in a better mixing with the sucked-in, cooled ambient air that returns to the storage space.

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Preferred devices according to the invention are further described in the subclaims.

The invention also relates to a storage space provided in a fixed or mobile manner with a cooling device according to the invention, which storage space is adapted for transporting foodstuffs in a frozen state.

Finally, the invention also relates to an autonomous cooling process. The preferred embodiment of this cooling process assigns four functions to the evaporated cooling medium. These four functions are: - cooling the storage space; - causing a circulation of the ambient air present in the storage space; - causing a freezing of the moisture present in the circulated ambient air; and - causing thermally controlled cooling by temperature and pressure sensors.

The invention will be further elucidated with reference to the figure description below of a number of preferred embodiments of the cooling device according to the invention. Herein: figure 1 shows a cross-sectional front view of a preferred embodiment of a cooling device according to the present invention; figure 2 shows the same preferred embodiment as figure 1 in a side view; figure 3 shows a schematic flow diagram of the ambient air and the evaporated cooling medium in a cooling device according to the invention.

figure 4 shows a schematic flow diagram similar to figure 3 in which an extra flow of evaporated cooling medium causes a thermostatic effect.

figure 5 is a schematic cross-sectional view 35 showing the operation of the moisture trap and the venturi in a T-connection piece.

Figure 1 shows the cooling device 1 which comprises a container 2 for a cooling medium 3 connected to a number of pipes. The container 2 is filled with a cooling medium via a filling tube 4. Since the wall 5 of the container 2 is largely insulated by a vacuum jacket 6, the bottom 7 of the container 2 acts as a heat exchanger. This bottom 7 of the container 2 is not insulated, as a result of which an evaporation of the cooling medium is caused via this temperature difference, as a result of which a pressure is built up. This overpressure is created by evaporation of the liquid nitrogen 8. Since the container 2 10 is not closed off from the liquid nitrogen 8, nitrogen in the gas phase flows through the overpressure from the container 2 into an element with an adapted volume measure, further referred to as a moisture absorber 10 after which this gas flows through a heat exchanger and through a venturi connection.

This results in an acceleration, which creates an underpressure in the T-connector, which causes suction of the ambient air pipe 12, which is drawn into the bottom 7 of the container 2.

20 The moisture absorber 10 protects the venturi 13 against freezing. The aspirated ambient air collects in this moisture trap and the moisture present in the ambient air is frozen by the evaporated cooling medium. The moisture absorber can be considered as a heat exchanger whereby moisture in the ambient air is temporarily frozen in it, so that the operation of the venturi is not impeded.

The most important function of the evaporated cooling medium 3 (here nitrogen gas 8) is to cool the storage space 9 by pushing the sucked-in air flow into the storage space 9 together with the nitrogen gas accelerated via the venturi 13.

The nitrogen gas 8 is forced after the heat exchange in the moisture trap 10 via a heat exchanger 14 extending in the storage space as a heat exchange: cooling of the storage space on the one hand and heating of the nitrogen gas on the other hand.

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Another heat exchanger 15 is connected to the container at the bottom and provides additional cooling if this becomes necessary, for example, in warmer periods.

Irrespective of the level of the cooling medium in the container 2, the device according to the invention has the same cooling capacity through an adjustment of pressure-regulating elements.

Because the venturi 13 causes an intake of the ambient air, a circulation is caused as long as evaporation takes place, whereby a homogeneous temperature prevails in the storage space.

Figure 2 shows a side cross-sectional view of the preferred embodiment of the cooling device shown in Figure 1. Herein the top 14 and the bottom heat exchangers 15, the latter of which is an additional heat exchanger, are clearly shown. The top one extends to the ceiling of the storage space 9. A cooling is obtained in the heat exchangers by the transfer of heat via the evaporated nitrogen. The level in the holder 2 can be determined by a probe 26.

Figure 3 shows a schematic flow diagram of the preferred embodiment in Figures 1 and 2. There are two kinds of flows, namely those of the evaporated cooling medium 16 (completely black triangle) and of the ambient air 17 (triangle provided with O). The liquid nitrogen 3 present in the container 2 evaporates and provides cooling of the storage space via the first heat exchanger 18 and also suction of ambient air. Ambient air is drawn in through a venturi 13, so that a circulation is created in the storage space, which ambient air mixes with the evaporated cooling medium through the first heat exchanger, which mixture is released back into the environment, which forms a second heat exchanger 19. A third heat exchanger 20 is provided at the bottom of the holder 2.

Figure 4 shows a similar flow chart as Figure 1003915. 3. In this embodiment, another pressure regulating system is provided in which pressure regulating elements 21 and a valve 22 are connected in series or in parallel. Via other pressure regulating elements 24 and temperature measurement 23, an additional flow of liquid nitrogen is brought to the storage space via line 25. Thereby a thermally controlled cooling of the storage space is caused. The extra flow can cause additional mixing with the output flow - ambient air - evaporated cooling medium.

Figure 5 shows a schematic view of the principle of the moisture trap and venturi according to the invention. The moisture trap 27 consists of a conduit 30 for the ambient air, whereby a low temperature Tv prevails in the moisture trap 27, due to the presence - in equal amounts - and / or counterflow of evaporated cooling medium, so that the moisture present in the ambient air is frozen to the wall of the pipe 30. Thus, ice builds up 29 on this wall 30. The flow of evaporated cooling medium is then led via heat exchangers to the inlet of the venturi 28. The temperature Tw is the temperature of the cooling medium after heat exchange with the storage space and is preferably lower than the temperature Tt of the ambient air from the moisture trap to exclude all freezing phenomena in the venturi. The constriction draws in ambient air and mixes the evaporated cooling medium and aspirated ambient air which are released into the storage area in point 31.

Such a cooling device according to the invention is preferably used in a storage space, for instance in a container or in the loading box of a truck for the transport and distribution of foodstuffs. The level of the cooling medium in the container can be adjusted by a calculation with the logistics data such as transport time and ambient temperature and the volume of the storage space. This level is read, for example, by means of a level-determining probe. This provides regular cooling 1003915 7 over time and in storage that meets all European standards for the transport of chilled and frozen foods.

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Claims (21)

1. Autonomous cooling device for cooling a storage space for a certain period of time, the cooling device comprising a container for a cooling medium and a number of pipes, characterized in that the cooling device is provided with means for evaporation of the cooling medium increase the pressure of the air present in the storage space. 2. A cooling device according to claim 1, characterized in that the means for circulating the ambient air comprise a conduit coupled to a venturi for causing an aspiration of the ambient air. 3. A cooling device according to claim 2, characterized in that the cooling device between the pipe and the venturi comprises an element with an adapted volume for protecting the venturi against freezing by freezing the moisture present in the ambient air in this element. Cooling device according to any one of claims 1 to 3, characterized in that the device is provided for a metered supply to the storage space of cooling medium, the device being arranged for carrying out a dosing, depending on the 25 room prevailing temperature. Cooling device according to claim 1, 2, 3 or 4, characterized in that the container is connected at its lower end to another heat exchanger. Cooling device according to one of the preceding claims, characterized in that the container is partially insulated. Cooling device according to claim 6, characterized in that the container is adapted to contain a cooling medium in its liquid state. 1003915 Cooling device according to claim 7, characterized in that the container is designed for containing liquid nitrogen or liquid carbon dioxide. Cooling device according to one of the preceding 5 claims 1-8, characterized in that the device is provided with pressure regulating means. Cooling device according to any one of claims 1-9, characterized in that the device is provided with temperature sensors. Cooling device according to any one of the preceding claims, characterized in that the device comprises a level-determining element for indicating the level of the cooling medium in the container. 12. A cooling device according to any one of claims 1-11, characterized in that the device is arranged as an independent unit. 13. Cooling device according to any one of claims 1-12, characterized in that the cooling device is provided with means, for instance wheels at the bottom of the cooling device, for easily moving the cooling device from one storage space to another. 14. Cooling direction as claimed in any of the claims 1-13, provided with an external drive source for driving parts of the cooling device, for instance for driving a security element. Storage space provided with a cooling device according to claims 1-14. Storage space according to claim 15, characterized in that the storage space is arranged for transport. Storage space according to claim 15 or 16, characterized in that the storage space is adapted for transporting foodstuffs in a frozen state for at least the duration of the transport. 18. Autonomous cooling process for cooling a storage space, whereby by evaporation of a cooling medium: - the storage space is cooled; and 1003915 - causing a circulation of the ambient air present in the storage space. 19. Cooling process according to claim 18, wherein the freezing of the moisture present in the circulating ambient air is caused by the evaporated cooling medium. 20. Cooling process according to claim 18 or 19, wherein thermally controlled cooling is caused by evaporation of the cooling medium and via pressure and temperature sensors. Cooling process according to claims 18-20 carried out in a device according to from 1-14. f 1003915