SE413805B - DEVICE AT A FREEZER FOR FREEZING GOODS AND STORAGE OF FROZEN GOODS - Google Patents

Description

u 721z1s7-3 2 is adversely affected during freezing of rnfinlag-t goods.

It has i.a. There has been information in the literature that the gas temperature changer of the absorption apparatus in particular would impede the development of an absorption cycle apparatus with optimum performance for both the one and the other purpose mentioned. It has i.a. It has been proposed to solve this problem by arranging a series of parallel flow paths for gas in a gas temperature exchanger specially designed for the purpose. If it were feasible, it would still be unattractive and quite expensive. The said disadvantages are eliminated with a device according to the invention which is substantially characterized by what is stated in claim 1.

According to the invention, the friendly transport from the storage space is effected by co-operation between the secondary system and the evaporator part of the refrigeration apparatus operating at a lower temperature, while the heat transport from the freezing space is effected by means of the cooling unit operating at a higher temperature.

The invention will be described in more detail below with reference to a freezer shown in the drawings. Fig. 1 is a schematic view of the back of the freezer with details of the absorption coil apparatus. Fig. 2 is a horizontal section along the line II - II in Fig. 3, which is a vertical section along the line III - III in Fig. 2. Fig. 1t is a perspective view of the front of the cabinet with the door removed, and Fig. 5 and 6 shows modified embodiments of the upper part of the freezer. Fig. 7 is a section along the line VII - VII in fi g. 2 with fan-cooled condenser. f Of those in fi g. 2 and 3 through a freezer it appears that this consists of a bottom 10, a rear wall 11, a roof 12 and side walls 13, 11% together with a door 15 without storage shelves. The cabinet walls and the door are constructed in a manner known per se: down an outer casing, an inner shell and a relatively strong thermal insulation 16, 1T of, for example, polyurethane foam containing a heavy gas, such as trichloromonofluomuethane. In the rear wall there is a so-called window Sat, through which the evaporator system 19 of the absorption cooling apparatus is inserted into the heat-insulated space 20 of the cabinet. The embodiment of the absorption cooling apparatus is shown in Figs. ) and surrounds the appliance's cooker unit 22. Around the appliance's gas temperature exchanger 23 a heat insulation (not shown) is also arranged, suitably of the same type as in the cabinet walls.

The gas temperature exchanger 23 of the absorption refrigeration apparatus 23 has an increased capacity in relation to other ordinary components when compared with an ordinary refrigeration apparatus. It also works to some extent with evaporation of excess shielding medium from the evaporator system.

The kitchen appliance has a liquid circulation system, comprising an absorber 21+, an absorber cable 25, a liquid tin temperature switch 26 and the cooker assembly 22. From the absorber, absorbent rich refrigerant solution, for example ammonia and water, is fed to the outer conductor of the solvent vessel 25. the liquid temperature exchanger 26 flows to the boiler assembly 22, where the solution reaches a level corresponding to the liquid level 28 in the absorber vessel. The solution is transferred through a transverse analyzer 29 to the lower part 30 of a line 31. The part 30 contains a reaction column of solution for the liquid-circulation pump 32 connected at the bottom, which is heat-conductively connected partly to a sleeve. 33 for an electric heating cartridge S11, which is connected via lines 35 through a thermostat 36 to an electric power source 37, for example a mains voltage or a generator over a battery, partly with a chimney 38 'for a gas burner (not shown).

The thermostat 36 is connected by an impulse line 39 to a sensing body OO, which is arranged inside the freezer oven and depends on the evaporation temperature in its evaporator part.

By supplying heat to the pump pipe 32 from one or the other heat source, refrigerant vapor is expelled in the rich solution in the pump pipe, and at the same time a circulation of the solution is effected, which is transferred in the inner line III to the vertical part inside the boiler unit. This one has at the top on. per se known openings, through which the steam from the punch pipe flows out into the outer pipe 27, where the steam presses down the rich solution so far that the steam can flow through the analyzer 29 into the line 31, which constitutes a steam line to the device's condenser l + 2 with flanges l43. After the boiling of refrigerant in the pump pipe 32, the absorption solution, which is required in the vertical part of the line lll in the boiler unit, reaches such a high level that the solution through the inner line lll and a line lll! can flow into the absorber 2l + upper part ..

The gas circulation system of the apparatus comprises the evaporator system 19, which is designed in the form of a nine horizontal pipe loop, and gas temperature switch x 23, which consists of two parallel, thermally conductively connected pipes formed into a pipe loop, which at the bottom passes into the line for poor solution and thus in the upper part contains on. refrigerant poor gas, for example hydrogen gas, and a line H5, through which rich gas flows down into the steam space of the absorber vessel 25 and then rises upwards through the absorber 2lß in countercurrent to the flowing, poor solution.

From the condenser lr2, refrigerant condensate is passed through a line 166 downwards to a pipe 1W, which is wound in a loop around the gas temperature exchanger 23 and heat conductively connected to its line 148 for rich and cold gas. The gas temperature changer's second gas line læ9, which contains poor gas, is routed at the top in an upward direction. angle 50, which at a point 51 is connected to the evaporator loop 19. The condensate line H7 opens into the gas line 1: 9 at a point 52 between the highest part of the angle 50 and the connection point 51 to the evaporator. Thus comes fautzig gas and kölflmeul.I, akorzdnnuat; to. The apparatus is designed so that extremely low evaporation gas temperatures can be found in the first loop 53 of the evaporator 19. Between the condenser ÄE and the gas circulation system a ventilation line 51+ is arranged on the apparatus. . per se known manner. In the example shown, it is connected to the rich gas-carrying line 1: 5 from the gas temperature exchanger 23. The latter is, as shown in Figs. 2 and 3, almost completely built into the window 18 in the rear wall 11 of the cabinet and enclosed in a the window is otherwise complementary, high-class thermal insulation consisting of, for example, polyurethane foam containing a heavy gas.

As shown in Figs. 2 and h, the pipe loop forming the evaporator system 19 is designed to cover substantially the entire cross-section inside the created chamber 20 and divide it into two compartments. As mentioned, the first part 53 of the evaporator loop, which is located on the left in Fig. 2, operates at very low temperatures, for example between -30 and -22 ° C. In the rest of the evaporator loop, the temperature is slightly higher, but still below that required for storage of frozen goods, for example between -22 and -19C. Fig. H shows how the evaporator system 19 is arranged to co-operate with a secondary system operating with evaporation and condensation of a refrigerant for cooling a cabinet chamber 55 located below the evaporator system I9, for example dichlorodifluoromethane at a suitably adjusted pressure. The secondary condenser system 56 includes a tubular loop which is heat conductively connected to the evaporator member 53. Condensed refrigerant is passed through a conduit 57 down to the bottom 10 of the cabinet, where it merges into a loop 58 which substantially covers the bottom. From the loop 58 a line 59 goes upwards to a loop. 60, which forms a shelf in the chamber 55 or forms part of one. The cooling medium is led from the loop 60 through a conduit 61 upwards to a further horizontal loop 62, which forms a shelf. in the canister 55, and from there through a line 63 - to the condenser part 56.

The second evaporator part 61 of the refrigeration apparatus; is heat-conductively connected to a heat-conducting plate 65, for example of aluminum sheet, which forms a freezing shelf in a chamber 66 above the evaporator system 19.

When the freezer described above contains freezer goods in the chambers 55 and 66, the whole evaporator system 19 maintains temperatures below that required for the storage of goods, for example -30 - -19 ° C and the operation of the apparatus is regulated during electrical operation by the said thermostat 36 and in gas operation of a corresponding thermostat (not shown) which regulates the gas supply to the burner (not shown). I Freezing of goods shall take place on. shelf 65 in chamber 66. The goods should be refrigerated in advance to a temperature of about +5 OC. The evaporator stone temperature in the second part 67+ of the refrigerator's evaporator system changes significantly after the goods are loaded. The evaporation of refrigerant in the evaporator system will initially take place at temperatures between approx. -22 and -5 OC in section 611. 7213187-3 On. Due to the nature of the absorption apparatus, the heat transport in this part of the evaporator system is now several times greater than before. The cooling device will work continuously, as the thermostat will not feel temperatures so low that the device's friend source is disconnected or regulated. The freezing of goods comes on. This is due to the fact that it takes place relatively quickly, despite the fact that the effect of the absorption cell at storage temperature in the cabinet compared with other types of refrigerators must be considered limited. As the freezing of the goods takes place, the evaporation temperature in the evaporator decreases and the heat transport decreases and when the freezing is complete, the power of the cooling device exceeds the current need, whereby the thermostat comes into operation and regulates the cold generation in the normal way. At the same time, at least during electric operation, it can mark when the freezing is completed. A glow lamp is fitted for the purpose. suitable place and connected in the circuit regulated by the thermostat.

While maintaining the main features of the invention set forth above, certain modifications may be made within the scope of the invention. Thus, for example, the freezer shelf 65, which is connected to the evaporator part 61+, can be extended over the evaporator part 53 with a part 67, as shown in Fig. 5. However, a heat insulation 68 should be arranged between the part 65 of the shelf 65 and the evaporator part 53, so that the temperature in the storage chamber 55 is not significantly affected by the freezing of goods in the chamber 66.

It is also possible, as shown in Fig. 6, to provide a removable thermal insulation body 69 below the evaporator part 61% in order to separate it from the chamber 55, especially during freezing occasions. At extremely high ambient temperatures, the condenser's ability to deliver refrigerant condensate to the evaporator system decreases. To achieve an improvement in this respect, a fan can be fitted to increase the condenser cooling. During electric operation of the 'cooling apparatus', it can be driven by a motor connected to the current source of the friend element 311. For cooling the condenser 1L2 during gas operation, a fan 70 with motor' (1 in a holder 72 and 1) can be arranged as shown in Fig. in a circuit 73 through thermocouple Th, which is kept in contact with the chimney 38 by a holder 5. With a bimetallic switch 76 in the circuit it is possible to arrange that the fan 70 only operates at ambient temperatures above a certain limit, for example 35 OC.

As mentioned, the invention is not limited to the shown and described embodiment of a freezer. The principles of the invention set forth in the following claims may also be applied to a freezer box.

Claims (6)

7213187-3 e 6 P a t e n t k r a v _ 1. A device in a freezer unit for freezing goods and storing frozen goods with a primary teaching apparatus, which consists of an absorption cooling apparatus operating with inert gas with an evaporator having a first part (53), operating at a lower temperature and a second part (6h), which operates at a higher temperature, and with a secondary system operating with condensation and evaporation of a cooling medium and by heat exchange with the primary system, characterized in that a) that the condensing part (56) of the secondary system is heat conductive connected to the first, coldest evaporator part (53) of the primary refrigeration apparatus, b) that the evaporation part (58-62) of the secondary system is arranged for cooling a frozen storage compartment (55) true c) that a heat transfer freezing means (65) is arranged in heat conducting connection with the other, higher-temperature evaporator part (uh). Device according to Claim 1, characterized in that the evaporator part (58-62) of the secondary system is thermally conductively connected to shelves in the storage compartment. _ Device according to claim 1, characterized in that the evaporator part (58-62) of the secondary system forms shelves in the storage room (55). H. Device according to any one of claims 1 to 3, characterized in that the evaporator system (19) of the refrigeration apparatus is extended substantially in a horizontal plane, suitably in the form of a pipe loop. Device according to one of the patent claims 1 - h, characterized in that heat-insulating material (68) is arranged between the part (53) of the cooling apparatus operating at a lower temperature and a freezing chamber (66). V Device according to one of Claims 1 to 5, characterized in that a thermal insulation (69) is arranged between the part (uh) of the cooling device which operates at a higher temperature and the storage space (55). T. Device according to claim 6, characterized in that the thermal insulation (69) is removably arranged in place. _ PROMISED PUBLICATIONS: Sweden 158 063 (17 a: 18/02), 183 095 (17 0: 18/02), 362 494 šFzsa 31/02. United Kingdom 1 262 255 (F25b 49/00)