FR2462673A1 - REFRIGERATION CHAMBER - Google Patents

Abstract

In order to improve the homogeneity of the cooling of a stack (6) with intermediate spacing of objects to be cooled, the enclosure (1-4) comprises, in the vicinity of its corners, four pipes with ejection and pressure-reduction nozzles (8-11) which spray liquid carbon dioxide which turns into snow on exit from the nozzles. The fans (13) cause circulation of this carbon dioxide snow by sucking the latter through the spaces separating the stacked objects. The stack of objects (6) should be placed in the middle of the enclosure, rear nozzle pipes (6, 11) close to the fans (13) eject their carbon dioxide snow onto the side of the stack facing forwards, so that it enters the stack laterally and is then resucked backwards by the fans. Two front nozzle pipes (8, 9) are directed towards each other and eject the carbon dioxide snow towards the front of the stack, whence this snow is sucked backwards by the fans through the stack (6) of objects to be cooled. This refrigeration enclosure finds a particularly advantageous application for cooling food, in particular prepared dishes.

Description

 The invention relates to a refrigeration enclosure intended to cool products, in particular food or cooked dishes, placed on trays stacked with mutual intervals, by free jection, in the space surrounding the stack of trays and separating it from the internal walls of the enclosure, of a liquefied gas such as liquid carbon dioxide under pressure by means of expansion nozzles at the outlet of which this liquefied gas becomes carbon dioxide snow, the internal atmosphere of the enclosure being stirred by fans. Of course, the walls of the enclosure are thermally insulating.

 The known refrigeration chambers of this kind have the drawback of unevenly cooling the different parts of the stack of trays, so that, at the end of the operation, there are significant differences in temperature between the products according to their position in the stack.

 To overcome this drawback, provision is made according to the invention to place the injection nozzles on several vertical ramps distributed around the stack of trays. There is thus obtained a more homogeneous cooling of the different parts of the latter and, thereby, of the products to be refrigerated that it contains. The lowering of temperature can then be carried out very quickly and with equal speed for each of the plates and over the entire surface thereof.

Preferably, the ramps are four in number and are arranged along the four vertical edges of an imaginary parallelepiped surrounding the stack. In a particularly advantageous embodiment, these four ramps comprise a first pair of ramps placed in the posterior region of the stack, on either side of it, at the rear of which are the fans creating padaspiration a gas flow through the stack, while the nozzles of this pair of ramps are directed towards the front of the stack, therefore in the opposite direction to the direction of circulation of the gas flow inside the stack The ramps of the second pair are then preferably placed in the anterior region of the stack, and their respective nozzles are directed towards each other, the jets emitted by them meeting halfway between the distance separating these two ramps.

The enclosure can offer, as well as the stack, the shape of a parallelepiped; the ramps of the first pair are then close to the rear vertical edges of the stack, their nozzles being oriented parallel to the lateral faces of the stack, while the ramps of the second pair are close to the anterior vertical edges of the stack, their nozzles being oriented parallel to the front face of the stack. The enclosure can even offer, as well as the stack, the shape of an elongated parallelepiped whose lateral faces are longer than the anterior and posterior faces.

In this case, a uniform cooling temperature of the products is also obtained, whether they are placed at the rear or at the front of the stack.

 Preferably, the nozzles emit jets whose mean direction is horizontal. On the other hand, the nozzles of each boom are advantageously distributed regularly over its length, their spacing being the same for the various booms. As for the fans, they can form a battery covering the entire surface of the rear internal wall of the enclosure.

By replacing the door with which an enclosure is provided according to the invention by a transparent plate, one can observe a very uniform distribution at all levels of the solid particles of dry ice emanating from the nozzles in the volume of the enclosure, which is the origin of the uniformity of the lowering of the temperature of the products at all levels. This is a result which is the direct consequence of the arrangement and orientation of the nozzles and which leads to very low temperature inequalities, less than 5 ° C., whereas in known analogous enclosures it is observed temperature differences of up to 10 to 1500.

A refrigeration enclosure according to the invention has a second advantage, namely the recovery of all the frigories contained in the dry ice particles, which leads to a minimum consumption of C02 per kg of products to be cooled, that is to say to say an optimal economic return.

 The description which follows, with reference to the accompanying drawings by way of nonlimiting example, will make it possible to understand clearly how the present invention can be put into practice.

 Figure 1 shows, in section through a horizontal plane, a refrigeration chamber according to the invention.

Figure 2 shows schematically, in perspective, the arrangement of the ramps and their injection nozzles.

 The refrigeration chamber according to the invention is parallelepipedic and has four vertical walls 1,2,3,4, a lower wall and an upper wall. The front wall 1 has an access opening closable by a door 5. The walls and the door of the enclosure are constituted by thermally insulating panels. Inside the enclosure can be placed food to be refrigerated, in trays carried by superimposed trays with mutual spacings so as to form a pillar 6 of general shape also parallelepiped, separated from the walls of the enclosure on its out around by a free space 7. It is convenient to place this stack on a trolley.

 At the four corners of the enclosure are arranged vertical ramps 8, 9, 10, 11 supplied with liquid carbon dioxide under pressure and provided with nozzles 12 (in the present example, three nozzles per ramp, equidistant and situated at identical levels for the four ramps) which emit horizontal jets of liquefied gas in the free space 7. The nozzles of the ramps 10,11 located in the corners of the rear wall 3 are directed towards the front wall 1 and the corresponding jets are parallel to the walls 2.4. The nozzles of the ramps 8, 9 located in the corners of the front wall 1, on either side of the door 5, are directed towards each other, parallel to this latter wall.

 Between the rear ramps 10,11 and the rear wall 3 is disposed a battery of six fans 13 arranged in a plane parallel to said wall and distributed over the entire surface thereof. These fans create by suction a large flow of gas circulation 15 flowing horizontally through the superimposed plates of the stack 6,.

 When the enclosure is in operation, the nozzles 12 of the rear ramps 10 and 11 emit in the lateral corridors formed by the space 7 of the jets of liquid carbon dioxide which is immediately transformed into snow carbonic. These jets, directed towards the front, fold down along the assembly 6 to be refrigerated in a multitude of currents, indicated diagrammatically in FIG. 1, moving towards the rear under the effect of the flow 15 generated by the fans 13 and licking the plates of the stack 6. As for the jets emitted by the nozzles 12 of the front ramps 8 and 9 in the front part of the space 7, they meet halfway between said ramps and are deflected towards the rear, under the effect of the aforementioned flow 15 through the plates of the stack 6. This results in a very homogeneous distribution of the dry ice particles throughout the interior volume of the enclosure, which provides excellent uniformity of the lowering the temperature of the food to be refrigerated in all parts of the stack 6, as well as optimal use of the frigories provided by the carbon dioxide snow, hence a reduced consumption of refrigerant.

 The gas circulation circuits in the enclosure close along the side walls 2,4 thereof. The residual gases escape into the atmosphere through a chimney 14 passing through the upper wall of the enclosure.

 During an experimental test, such an enclosure made it possible to lower the temperature by 320 liters of water, distributed in 51 tanks arranged in layers of 3 out of 17 stacked trays, from 7,400 to SOC with lower deviations at 50C between the different tanks, in a time of 50 minutes and with a consumption of 211 kg of carbon dioxide.

In general, the lowering of temperature depends on the time of injection of liquid carbon dioxide. Thus the food placed on the trays can be simply refrigerated, for example at 50C, or frozen at -200C by prolonging for a sufficient time the admission of liquefied gas.

 As a practical example, an enclosure according to the invention can have internal dimensions equal to 945 mm in width, 1600 mm in length and 1880 mm in height. These dimensions make it possible to place three "gastronorm" tanks per level in the stack 6. Such an enclosure can be provided with six fans each delivering 4100 m3 / h, which ensures intense mixing of the interior atmosphere of the enclosure.

Claims (9)

1.- Refrigeration chamber intended to cool products, in particular food or cooked dishes, placed on stacked trays with mutual intervals, by injection, in the free space surrounding the stack of trays and separating it internal walls of the enclosure, a liquefied gas such as liquid carbon dioxide under pressure by means of expansion nozzles at the outlet of which this liquefied gas turns into carbon dioxide snow, the internal atmosphere of the enclosure being stirred by fans, characterized in that the injection nozzles are arranged on several vertical ramps distributed around the stack of trays. 2.- enclosure according to claim 1, characterized in that the ramps are four in number and are arranged along the four vertical edges of an imaginary parallelepiped surrounding the stack. 3.- enclosure according to claim 2, characterized in that the ramps comprise a first pair of ramps placed in the rear region of the stack, on either side of it, at the rear of which are the fans creating by suction a gas flow through the stack, and that the nozzles of this pair of booms are directed towards the front of the stack, therefore in the opposite direction to the direction of circulation of the gas flow at the - inside of the stack.  4.- enclosure according to claim 3, characterized in that the ramps of the second pair are placed in the anterior region of the stack, and that their respective nozzles are directed towards each other, the jets emitted by them- Ci meeting halfway between the distance separating these two ramps.  5.- enclosure according to claims 3 and X, characterized in that it offers, as well as the stack, the shape of a parallelepiped, that the ramps of the first pair are close to the rear vertical edges of the stack, their nozzles being oriented parallel to the lateral faces of the stack, and the ramps of the second pair are close to the anterior vertical edges of the stack, their nozzles being oriented parallel to the front face of the stack.  6.- enclosure according to claim 5, characterized in that it offers, as well as the stack, the shape of an elongated parallelepiped whose lateral faces are longer than the front and rear faces.  7. - Enclosure according to any one of claims 1 to 6, characterized in that the nozzles emit jets whose average direction is horizontal.  8.- Enclosure according to any one of claims 1 to 7, characterized in that the nozzles of each ramp are distributed regularly over its length, their spacing being the same for the different ramps. 9.- enclosure according to any one of claims 1 to 8, characterized in that the fans form a battery covering the entire surface of the rear internal wall of the enclosure.