NL1016535C2 - Coolant device not generating carbon dioxide has a coolant container, a cooler and a transfer device - Google Patents

Abstract

The device comprises an upper coolant container, a separate cooler and a transfer device whose top side (4) is formed by the coolant container.

Description

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Cooling device

The present invention relates to a cooling device, comprising: a cooling space for holding objects to be cooled therein, and a cooling medium space for holding a fixed coolant therein.

Such devices are known in the art. These cooling devices are generally used for the transport and the short-term storage of objects to be cooled.

Such cooling devices are also known in aviation, wherein the solid coolant is placed in containers in the cooling space. In addition, the solid refrigerant generally consists of frozen CO2, which is released over time, whereby an increased CO2 content in the cooling space is obtained.

This property of the known cooling devices also forms a large share. The CO2 content in the cooling space is considerably increased, which is often undesirable.

The invention now has for its object to provide an improved device of the type mentioned in the preamble. In particular, the invention has for its object to provide a cooling device with which no CO2 is delivered to the cooling space. A further object of the invention is to provide a cooling device with which a circulation of cooled air through the cooling space is possible.

To this end, the invention provides a cooling device of the type mentioned in the preamble, which is characterized in that the cooling space is completely closed off from the cooling medium space, the cooling medium space is located at the top of the device, and wherein the device also comprises a transfer space the top of which is formed by the bottom of the coolant space and the bottom of which is formed by a surface inclined relative to the top, and which transfer space is connected to the cooling space near a highest position and a lowest position of the flat. The aforementioned objects are achieved with the device of the invention.

According to a preferred embodiment, a fan is provided in or near the transfer space, for passing the atmosphere present in the device through the transfer space.

The invention will be described below with reference to a preferred embodiment, as shown in the drawing.

The drawing shows a number of figures.

FIG. 1 shows a perspective view, partly in cooling, of a cooling device according to a preferred embodiment of the invention.

FIG. 2 shows a part of the device according to a preferred embodiment of the invention.

FIG. 3 shows a cross-section along the line III-III of FIG. 1.

FIG. 1 shows an embodiment of the cooling device according to the invention. The cooling device comprises a coolant space 1 at the top, into which a solid coolant, such as dry ice or solid CO2, can be introduced. Below the coolant space 1 there is a cooling space 3. These two spaces 1, 3 are completely separate from each other. This can be achieved, for example, by arranging an intermediate partition in the cooling device at the position of position 4 in the manner indicated. Thereby it is obtained that no exchange is possible between the spaces 1 and 3 mutually. In the space 3, at the top, against the surface 4, which forms the bottom of the coolant space 1, an inclined surface is placed at a distance from the bottom 4, whereby a space 2 is formed. The inclined surface 7 has a highest position 5 and a lowest position 6. The transfer space 2 is connected to the cooling space 3 by means of openings which are provided near the position 5, 6.

In the embodiment as shown in Fig. 2, the side on the lowest edge 6 of the surface 7 is completely open. A complete connection between rooms 2 and 3 is thereby obtained. At the highest position 5 of the surface 7, as shown in this embodiment, one opening 9 is provided, which forms the connection on the side 5 of the surface 7 between the spaces 2 and 3. If desired, it is possible to provide a plurality of such openings 9 on the relevant side.

According to a preferred embodiment, a fan (not shown) can be arranged in or near the opening 9. This allows a forced air flow to be generated between rooms 2 and 3. Even if a fan or the like is not provided, when the device is used and when a coolant, for example dry ice, is provided in the space 1, an air flow will arise. Air, which is present in spaces 2 and 3, will cool down considerably by heat transfer to the bottom 4 of space 1. This cooled air will simply move through the lowest position 6 via the lowest position 6 due to the sloping surface 7. the space 3. Objects present in the space 3 will thereby be cooled. Heated air will then rise upward in the space 3 and, because of the inclined surface 7, enter the space 2 via the opening 9, where it will cool off at the bottom 4 of the coolant space 1 due to heat release. Therefore, a continuous air flow through the spaces 2 and 3 will be obtained.

Fig. 3 shows a cross-section in the direction of the arrows III-III of Fig. 1. This clearly shows the positions of the individual elements of the cooling device according to the invention. It is also clear to see that the surface 7 near the positions 5 and 6 is at a distance from the walls 8 of the device. This makes a good air flow possible.

If desired, heat transfer promoting means such as cooling fins (not shown) can be provided on the underside of the bottom 4 of the coolant space 1, which forms the top of the transfer space 2. A greater heat transfer per unit of time will hereby be obtained. In particular, an increased heat transfer will be obtained when fans are provided in the device. When a fan is provided in or near the opening 9, as shown in Fig. 1016 635 4 in Fig. 2, wherein optionally a plurality of openings 9 can be provided, each of which is provided with a fan, it is preferred that guide elements are also provided whereby distribution of the forced displaced air along the entire bottom 4 is obtained. As a result, a greatly improved heat transfer is achieved.

The device can be provided with ribs on the walls of the cooling space 3, in particular on the walls 8 as shown in Fig. 3. As a result, objects which are present in the space 3 cannot abut against the walls 8. whereby a blockage of the air flow could be obtained. According to a further preferred embodiment, all walls, as well as the bottom of the cooling space 3, are provided with such ribs.

It is preferable that the bottom 4 of the coolant space is made of a material that has a very good heat conductivity coefficient λ. Preferably, the heat conductivity coefficient is> 1 W / mK, preferably> 10 W / mK, even more preferably> 100 W / mK. A material of aluminum or an alloy thereof is particularly preferred. Thereby also the advantage is obtained that the weight remains very limited. The inclined surface 7 can also be made of aluminum. However, this is not necessary. For example, the inclined surface 7 can be made of a material that has a low temperature conductivity coefficient λ. As a result, the air ascending into the space 3 will essentially not be cooled at the surface 7, but will enter the transfer space 2 via the opening 9, where this air is only cooled, after which it will move more to the space 3. As a result, a improved air flow.

The outer walls of the device must have a very low thermal conductivity. As a result, heat from the outside will not be able to get into rooms 1, 2 and 3. It is also preferred that the material of the cooling device is very sturdy. According to a preferred embodiment, the outer walls of the device are made for this purpose from a polyester material, which may optionally be reinforced with fibers, for example glass fibers, and which even more preferably comprises a core part of a very good insulating material. material, for example polystyrene.

The walls of the device are preferably made of a material with a total heat transfer coefficient of <1 W / mK, preferably ^ 0.1 W / mK, even more preferably <0.01 W / mK.

The invention is not limited to the embodiment 10 as shown in the drawing and as described above. Instead of one opening 9, for example, several such openings can be provided, but it is also possible to design the side where the opening 9 is situated, as shown in the drawing, completely open, analogue on the side 6. For filling the cooling device with objects to be cooled, the device can be provided on one of the side walls with a door that can be opened, for example hinged. This door can extend over the entire height of the device, but it is also possible that this door extends over the height of the space 3, possibly over the height of the spaces 2 and 3 together. The coolant space 1 can be filled, for example, through an opening located at the top of the space 1. It is also possible that it is filled via a side, by inserting a module in which the coolant is located. According to yet another embodiment, it is possible to fill the coolant space 1 with coolant when the aforementioned door, which can be located in a side wall of the device, is opened. In addition, it must be provided that when the door is closed there is no connection between spaces 1 and 3.

According to yet a further embodiment, it is possible to have all edges on the inside of the spaces 2 and 3 rounded off. As a result, an improved air circulation in the entire spaces 2 and 3 is obtained.

The fan can be powered by a power supply that can be received in the device, for example a battery. This battery is arranged, for example, at a position above the spaces 2 i 1 1 3 3 5 6 and 3. To this end, however, good insulation must be provided between the coolant and the battery. However, it is also possible to use an external power source to supply the fan. For this purpose, connecting means accessible on the outside must be provided in the cooling device.

According to a further preferred embodiment, the walls 8 of the cooling device have a K value of 0.28 to 0.4.

Finally, the cooling device in the space 3 can be provided with a temperature sensor which is connected to a control device. If the temperature rises too high, the control device can, for example, switch on the fan or switch to a higher position, whereby a greater cooling of the air and a greater release of heat to the wall 4 can be obtained.

Examples of dimensions of the cooling device are as follows. The outside of the device can have a width, depth and height of, for example, 40-100 cm. The internal size of the device according to the invention can vary as required. In any case, the wall thickness must be such that a low heat conductivity is obtained. For example, the internal shape and size of the space 3 can be adapted to a specific product. It is also possible to make provisions by means of which several products can easily be cooled. For example, it is possible to arrange bearing partitions in the space 3, so that several products can be stored one above the other. It is herein preferred that these bearing partitions are provided with openings to allow circulation of air through the entire space 3.

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Claims (8)

A cooling device, comprising: a cooling space (3) for holding objects to be cooled therein, a cooling medium space (1) for holding a cooling medium therein, characterized in that: the cooling space (3) completely from the cooling medium space ( 1) is closed; the coolant space (1) is at the top of the device 10; the device also comprises a transfer space (2), the top side (4) of which is formed by the bottom of the coolant space (1) and the bottom side is formed by a surface (7) inclined relative to the top side (4), and which transfer space (2) is in communication with the cooling space (3) near a highest position (5) and a lowest position (6) of the surface (7). 2. Device as claimed in claim 1, characterized in that it is provided with a fan or the like for passing the atmosphere present in the device through the transfer space (2). Device as claimed in claim 1 or 2, characterized in that the coolant consists of solid CO2, with a temperature of -20 ° C to -100 ° C, preferably about -79 ° C. Device according to one of claims 1 to 3, characterized in that heat transfer promoting means are provided on the upper side (4) of the transfer space (2), and which are in heat-conducting contact with the bottom of the coolant space (1) . Device according to one of the preceding claims, characterized in that the bottom of the coolant space (1) consists of a material with a thermal conductivity X of> 1 W / mK, preferably> 10 w / mK, even more preferably > 100 / mK. Device according to one of the preceding claims, 1016535, characterized in that the bottom of the coolant space (1) consists of aluminum or an alloy thereof. 7. Device as claimed in any of the foregoing claims / characterized in that the walls (8) of the device are made of a material with a heat conduction coefficient λ of <1 W / mK, preferably <0.1 W / mK even more preferably with a heat conductivity coefficient of <0.01 W / mK. 8. Device as claimed in claim 7, characterized in that the walls comprise a shell part of in particular plastic, for example polyester, and a polystyrene core. IOI6535