DE1601870C3 - Freezer container with cooling air circulation - Google Patents

Description

The invention relates to a freezer for frozen products, the walls of which a has free opening for access to the interior of the freezer container, with a device for circulation of cooling air through this opening between a cooling air outlet on one side and one Re-entry opening on the opposite side of the opening, with one provided on the re-entry opening and this with a grid-like one Arrangement covering heating device for the re-entering cooling air and with a liquefiable Refrigerant working cooling system for the cooling air.

The grid-like arrangement is used not only to cover the re-entry opening for uniform and efficient heat transfer from the heater to the re-entering air. the The purpose of heating the air is to keep ice deposits on the grille and the adjacent area of the Housing and the existing in the housing air duct to reduce. Inside the Air duct channel possibly deposited ice in this way does not take on any extent that the Air flow obstructed to a significant extent, at least not until defrosting due to the reason icing of other components of the cooling system becomes necessary.

A freezer container with a heating device of the type mentioned is known from US Pat. No. 3,128,609. The heating device is formed here by electric heating rods, d. H. by one from the cooling system Separate system that requires a special control device, with insufficient heating power the effect does not occur and if the heating output is too high, unnecessary energy consumption and also too much heating of the cooling air reduces the effectiveness of the freezer container are expected.

The invention is based on the object of designing a freezer container of the type mentioned at the outset in such a way that that the re-entry opening can be heated with a minimum of effort.

To solve this problem, the invention provides that the heating device by a section the supply line of the cooling system leading to the evaporator, in which the refrigerant is warmer al the cooling air is formed.

The refrigerant flowing to the evaporator h; i still has an increased temperature, which is in the cold generating device should cool down first. The temperature is also higher than the temperature de after passing the evaporator and the oil well; cooling air flowing back into the re-entry opening of the freezer container, with the transfer in front Heat on the cooling air remains limited to the value that is required to prevent it of ice build-up is required. It will be ow! this way an unnecessary increase in heat load of the cooling system avoided. The integration of the heating device into the thermodynamic system produces a self-adjusting adjustment of the heating output to the cooling output, without a special one Control device would be required. In addition, the transfer of cooling air leads over the A refrigerant supply line in front of the evaporator or the other cold-generating means Subcooling of the refrigerant, which gives it greater heat absorption capacity and so on the effectiveness of the cooling increases.

The drawing shows an embodiment of the invention.

Fig. 1 is a partial vertical section through a chest freezer;

F i g. Figure 2 is an enlarged top plan view of the re-entry port.

In Fig. 1, a part of a designated as a whole with 10 is Freezer shown, which has an insulated vertical front wall 11, an insulated bottom wall 12, an insulated back wall 13 and suitable side walls 14 (Fig. 2) which together make up the Form the housing of the freezer 10. The housing can be supported by any base 15 will. The plates 17, 18 and 19, which can be made of any suitable plate material, have inwardly spaced from the walls 11, 12 and 13 and extend between the Side walls 14. They form an air duct 16. The front vertical part of the air duct 16 between the plate 17 and the front wall 11 communicates with the atmosphere through a re-entry opening 20 near the upper limit of the front wall in connection. By a fan or Another suitable air circulation device 21 is air into the air duct through the re-entry opening 16 sucked, which then via an evaporator 22 in the rear vertical part of the Air duct 16 between the plate 19 and the rear wall 13 arrives. The rear wall 13 can be known in the art Way have a forward protruding part into which the rear part of the air duct 16 extends. This rear part of the air duct 16 is not with a The outlet opening shown is provided either in the rear wall itself or in the protruding part can be provided. The freezer is between the re-entry opening 20 and the exit opening open and, as indicated by number 23, offers unimpeded access to the content of the Housing, at least to the area bounded in the wall by the plates 17, 18 and 19 will. Air exiting from the rear part of the air duct 16 brings the interior of the housing

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to the desired freezing temperature by flowing over and around the contents and then enters the re-entry opening 20 to be circulated again by the fan 21 and in the evaporator 22 to be cooled again. The fan 21 and the evaporator 22 are located in an extended Part of the air duct 16 between the bottom wall 12 of the housing and the bottom plate 18. It more than one fan and more than one evaporator can be provided.

The evaporator 22 receives refrigerant through a refrigerant supply line 25 via a condenser 26 in which it liquefies after being compressed in the compressor 27 which expanded it Sucks back refrigerant in gaseous form from the evaporator 22 via a return or suction line 28, as shown in Fig. 1 schematically. The freezer can be of the closed type, in which the compressor and condenser are installed, or the externally fed design, in the case of the compressor and capacitor are arranged outside of the housing. That the compressor, condenser and Evaporator with the connecting lines comprehensive cooling system naturally includes the usual Control elements and other components as well as devices for removing the on the evaporator or ice accumulated in the air duct. However, these parts do not belong to the invention and are therefore not shown.

In or on the re-entry opening 20 of the air supply duct 16 is a designated as a whole with 30 Grid attached. Part of the supply line 25 is used to form the grid 30, which is located between the condenser 26 and the evaporator 22. How best to look Fig. 2 can be seen, this part of the line 25 consists of a number of strands of wire 31, which extend along the re-entry opening 20 or along the housing 10. In the illustrated embodiment four such cable strands are used, which at one end through a common Head piece 32 are connected, while two of the strands of wire are on the opposite side are connected by a head piece 33, which is connected to the supply line 25 coming from the condenser communicates. The other two strands of wire are at the corresponding ends via a Head piece 34 connected, which is connected to the part of the supply line 25 leading to the evaporator 22 is. The condensed refrigerant flows out of the condenser via the head piece 33 and the connected cable strands 31 to the common head piece 32, from where it over the other Line strands and the head piece 34 in the part of the supply line 25 leading to the evaporator 22 got. After the refrigerant has evaporated in the evaporator 22 to bring about the cooling, it returns to the compressor 27 via the line 28 and begins to circulate again. The grid 30 is completed by a number of rod-like ribs 35 which are welded to the cable strands 31 or otherwise attached at right angles to and parallel to each other. The grid 30 can be attached in any way; in the present case this happens through the internal and outer ends of the ribs 35 extending from corresponding recesses 36 and 37 in the plate 17 and the Front wall 11 are added.

The temperature of the refrigerant in the supply line 25 and in the grid 30 is higher than that of the Cooling air flowing through the grille 30 into the re-entry opening 20, which in turn is higher than that of the area of the housing 10 adjacent to the opening If a large part of its moisture condenses on it in the form of ice, it becomes on its way from the outlet opening of the air duct 16 to

ίο Re-entry opening 20 mixed with warmer and more humid ambient air. At the contact this air condenses with the housing near the re-entry opening 20 in the absence of frost preventive Facilities part of the moisture and forms an ice deposit near the top edge the front wall 11. This is undesirable because buyers have to hand them into the freezer the ice can come into contact and because ice in the air duct 16 is in such a Can accumulate extent that the air flow is obstructed and the cooling air is not in terms of volume sufficient to bring about the desired cooling effect, even if it is at the desired low Temperature is brought.

As a result of the design and arrangement of the grille 30, it is brought to a temperature by the refrigerant warmed so that no frost is deposited on it, d. H. it is raised to a temperature above freezing temperature heated, the ribs 35 the heat from the strands of conductors 31 over the entire grid 30 and the adjacent housing area distribute. In addition, the grille 30 serves to bring the cooling air flowing through it to such a temperature to heat up so that their relative humidity is more appreciable for condensation and freezing Amounts of moisture on the inner walls of the air duct in the vicinity of the re-entry opening 20 and is still too low at least in a certain area below this. When the air is in that front part of the air duct 16 flows downwards, their temperature drops again and their Moisture tends to condense and freeze out, with a part like snow in the lower part of the air duct 16 falls and the remainder forms an ice shelf in the front part of the air duct. This deposition, however, is reduced to a degree by the grid 30 or prevents it not the circulation of a sufficient volume of cooling air to maintain the desired Freezing temperature bothers. In other words: the freezer will have to be defrosted anyway, before the accumulation of ice in the air duct 16 due to the air entering through the grille 30 becomes large enough to impede the flow of air through the air duct 16. Defrosting will made depending on the amount of ice accumulated on the evaporator 22, the cooling efficiency both by obstructing the flow of air through the air duct 16 and by hindering the transfer of heat between the air and the evaporator 22. There are several effective methods and devices for effecting defrosting are known, of which after Any request can be used in the present case.

It can be seen that the grille 30 could completely prevent ice deposition in the front part of the Air duct 16 can be used by the

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Temperature of the cooling air is brought to a sufficiently high value. However, this would lead to withdrawal make a larger amount of heat from the air through the evaporator 22 necessary and thus the The cooling system demand a higher performance and require a greater expenditure of energy than usual for Lowering the cooling air temperature to the desired value is necessary. The grid 30 is special in view designed to avoid unnecessary heating of the cooling air and thus the loss of effectiveness avoid, which arises from the need to subsequently recycle the heat added to the cooling air to have to remove. This effect of the grid 30 is achieved in that it is designed so that only some of the air passing through comes into contact with the grille surface. It will only be one brought about such a rise in temperature that ice deposition of such an extent is prevented would impede proper cooling by restricting airflow through the air duct. In a special embodiment of the invention, the cable strands 31 are made of, for example Tubing is formed of no more than 9 mm in outside diameter and the ribs 35 are about 1.5 mm Diameter. They have a distance of about 12 mm from center to center, while the cable strands 31 are further apart. In this way the openings in the grid delimited by the ribs and the strands of conductors are relatively large, and the grid is very wide-meshed, although the total surface area of the pipe strings 31 and ribs 35 is larger can be than the total area of the grid openings. The ratio of the grille area and the air exposed grating surface may, of course, vary from this particular example depending, among other things, on the type of grid surface. of the Temperature of the cooling air and that of the refrigerant flowing through the grille 30.

It can be seen that the ribs 35 do not need to be arranged parallel to one another, nor even in right-hand positions Angles to the cable strands 31. Furthermore, can

ίο, if desired, others also delimiting the openings Elements as the ribs 35 can be used. For example, on the cable strands 31 a suitable sheet metal can be attached in a thermally conductive manner, which is used to produce the desired ratio of Lattice passage area is perforated to the surface of the lattice material exposed to the incoming air. Obvious If the number of cable strands 31 can furthermore be changed, the cable strands 31 can be different than in the longitudinal direction of the re-entry opening 20 run and can run the cable strands 31 in the manner shown instead of head pieces or the like Means are connected by elbows or by bending the feed line 25 so that a continuous, unbranched zigzag path is established for the refrigerant.

In addition to the advantageous results mentioned above, the grid 30 also causes subcooling of the refrigerant through the heat that it gives off to the air as it flows through the grille.

This improves the effectiveness of the cooling system by increasing the cooling capacity.

1 sheet of drawings

Claims (1)

16 Ol Claim: Freezer containers for frozen products, its Wall has a free opening for access to the inside of the freezer container, with a Device for circulating cooling air through this opening between a cooling air outlet on one side and a re-entry opening on the opposite side of the opening, ίο with one provided at the re-entry opening and this with a grid-like arrangement covering heating device and with a working with liquefiable refrigerant Cooling system for the cooling air, characterized in that that the heater through a portion of the to the evaporator (22) extending Supply line (25) of the cooling system, in which the refrigerant is warmer than the cooling air, is formed.