DE1476962C3 - Refrigerator with two thermally insulated chambers and a compressor-operated refrigerator - Google Patents

Description

The invention relates to a refrigerator with two thermally insulated chambers and with a compressor Refrigerator, the evaporator of which is made up of two metal sheets, one on top of the other, connected to one another with flow paths for the refrigerant formed in between and by slitting and bending of the metal sheets is divided into firstly a ceiling, floor and rear wall of a freezing chamber forming part, secondly an in. a cooling chamber protruding below the freezing chamber, extending in a plane parallel to the rear wall plate-shaped part and thirdly, narrow connecting

. links in the form of refrigerant piping bridges or ribbons between the two first named parts.

Such a refrigerator is already known, but in which the disadvantage arises that the Do not thermally isolate the freezing and cooling chambers from one another in the manner necessary in practice because the evaporator parts of the two chambers are connected to each other on the shortest possible route through connecting bridges are connected. However, if the freezing and cooling chambers cannot be thermally mutually sufficient isolate, this has the consequence that not very different temperatures in the two chambers can be sustained and, what can be worse under certain circumstances, that too The low temperature part of the evaporator affects wire? When defrosting the high temperature part.

The object of the invention aimed at improving the insulation between the freezing and cooling chambers is achieved in that the rear wall is arranged at a distance from the rear wall of the cabinet housing, the connecting bridges near the ceiling are bent down from the rear wall to the rear and between the rear wall and the connecting bridges along the rear wall of the cabinet housing a body made of heat-insulating material is appropriate.

In an advantageous embodiment of the invention, both the evaporator and the refrigerator are in dividing wall into two thermally separated chambers through the open front of the cabinet housing insertable.

The invention is shown schematically in the following with reference to one chosen as an example illustrated embodiment described.

It shows

1 shows a vertical section through a refrigerator equipped according to the invention,

F i g. 2 shows a partial section of the cabinet along line 2-2 in FIG. 1 looking from the front,

3 shows an interrupted horizontal section according to Line 3-3 in FIG. 2,

F i g. 4 in plan view of the evaporator system made of roll-welded sheet metal and provided with lines in FIG spread out on a plane,

5, 6 and 7 show some manufacturing steps in perspective and on a reduced scale of the evaporator according to FIGS. 1 to 3 from the in F i g. 4 roll-welded sheet metal shown,

Fig. 8 in perspective schematically the whole cooling system,

9, 10 and 11 partial sections along the lines 9-9, 10-10 or 11-11 in Fig. 4,

FIG. 12 is an enlarged partial view of FIG illustrated parts,

13 and 14 are sections along the lines 13-13 and 14-14, respectively, in FIG.

FIG. 15 is a vertical section along line 15-15 in FIG. 14.

■. In Fig. 1, a household refrigerator 10 is shown, which consists of a cabinet housing 11 with an inner lining 12, an outer lining 14 and a thermal insulation 15 in between. The inner lining 12 delimits the heat-insulated inner space 16, which is divided into an upper chamber 16 a ′ and a lower chamber 166 by a horizontal partition 22 . The former contains a thermally insulated freezer compartment 16 and the latter serves as a cooling chamber for storing food at a higher than the maintained in the freezer compartment 16a temperature, advantageously at a temperature of about 0 ⁰ C. The two chambers 16a 'and 166 are through frontal openings 22a and 226 accessible, which can be closed by separate, heat-insulating doors 23a and 236 which are hinged on the front of the refrigerator.

The refrigeration apparatus comprises an evaporator 24 which is accommodated in space 16. It consists of a low-temperature evaporator part 24a arranged in the upper chamber 16a and a high-temperature part 246 in the cooling chamber 166. As in FIG. 8, the evaporator 24 part of a compressor-operated refrigeration system with a group consisting of a motor and a compressor in a common housing summarized Kdmpressöreinheit 25. This is expediently mounted in a space 26 at the rear side of the cabinet housing 11 outside the thermally insulated enclosure sixteenth

From Fig. 8 shows the functional sequence of the cooling system. Compressed refrigerant vapor, which is emitted by the compressor 25, flows through a connecting line 27 to a condenser 28, which has the shape of a pipe coil with a plurality of heat-emitting ribs 29 attached to the pipe coil. to cool the refrigerant with the aid of circulating air at the rear of the cabinet 11 and outside it.

The refrigerant condenses in the condenser 28 and then, after reducing the pressure in a capillary tube 31, reaches a line 30 in the evaporator 24. From there it flows through a line 32 to lines 33 and 34 and to an accumulator part 34a in the evaporator part 24a for low temperatures ( see Fig. 4). Evaporating refrigerant flows on through lines 35 and 36 to accumulator 37, from where the refrigerant vapor is sucked back to the condenser through a line 38 and a suction line 39 (see FIG. 8). The suction line 39 allows a heat exchange with the capillary tube 31 essentially over its entire length. Both form a heat exchanger 40 in which the capillary tube 31 is arranged within the suction line 39. ■ '■ -.

The evaporator 24 is made of roll-welded sheet metal and is formed by the sheets 41 and 42 , which are held in a thermally conductive connection with one another and are formed with flow paths for the refrigerant. Such flow paths are the lines 30, 32, 33, 34, the accumulator 34a, the lines 35, 36, the accumulator 37 and the line 38. The low-temperature part 24a and the high-temperature part 246 are only connected to one another by relatively narrow connecting bridges 43, 44 connected to lines 32 and 35 (see FIG. 8).

The high temperature part 246 has, as in FIG. 4 and 8, a recess 45 at a lower corner. The line 30 extends upwards from this recess 45 and consists at its beginning of a narrow throttle part 30a. The lower. Part of the line 38 is bent and merges into a vertical line part 38a, which extends upwards from an edge 46 of the recess 45 and ^{: surrounds} the narrow throttle part 30a of the line 30. In order to connect the heat exchanger 40 to the evaporator 246 , the end of the capillary tube 31, which forms the inner tube of the former, is attached to the lower end of the throttle part 30a of the line 30 and the end of the suction line 39, which forms the outer line of the heat exchanger, to the edge 46 is connected to the lower end of the line part 38a of the bent line 38. The connection of the heat exchanger 40 to the metal sheets 41 and 42 can be done, for example, by welding. : ■ '· ■ · ■. · ■ ·,. ;,

The refrigerant which has passed the capillary tube 31 flows through the narrow throttle part 30a and further upwards through the line 30 and through the other lines and accumulators of the evaporator 24. Refrigerant vapor is sucked out of the accumulator 37 via the suction line 39 through the line 38 .

In the electrical lines "47, through which the motor of the compressor 25 is connected to a power source 48, a thermostat-controlled switch 49 is arranged (FIG. 8): The thermostat control consists of a sensor body 50 (FIG. 2), which is connected to the rear of the high-temperature evaporator 246 is connected in a thermally conductive manner, as well as a capillary tube 51, which in turn is connected to the sensing element 50 and contains an appropriate, evaporable liquid, "which is used to operate the switch 49 when the temperature of the high-temperature evaporator 246 changes . - - -

The initially straight metal sheets 41 and 42 are bent in such a way; that one part forms three side surfaces of a box, namely the sides 24a 'A4a "and an intermediate part 24a'", which represent the bottom, the ceiling and the rear wall of the cryogenic evaporator 24a. Another part of the metal sheets remains flat and emits the high-temperature evaporator 246, which is located below the rear wall 24 '"of the low-temperature evaporator 24a in one of the rear walls

24a '"extends parallel, vertical plane.

The bridges 43,44 extend from the ceiling 24a 'of the Cryogenic evaporator 24a downwards. They run behind the rear wall 24a "'at a distance to this wall through a space 52 between the rear wall 18 of the inner lining 12 and the Rear wall 24a "'(see FIG. 1). The lower sections 43a and 44a of the bridges 43, 44 are oblique to the opening angled towards the cabinet. The high-temperature part 246 then closes again vertically Direction to the lower ends 43a and 44a of the bridges 43,44.

During operation, the refrigerant flows from the capillary tube 31 into the line 30, up through the beginning of line 32 over bridge 43 and then through the remainder of the line 32 in the rear wall 24a "'of the evaporator part 24a downwards and into the line 33. The line 33 in the Bottom 24a is a continuous flow path in a zigzag shape from the front edge to the rear Edge of the bottom part 24a 'guided.

The refrigerant passes from line 33 into line 34. This consists of straight line parts 346, which end at the bottom of the rear wall 24a '"and near the' front edge of the ceiling 24a. In each case several of the straight line parts 346 are connected by cross lines 34c in such a way that they form a continuous Flow path for the refrigerant in the ceiling 24a "and the rear wall 24a '" in the transverse direction from the Form bridge 43 to bridge 44. The straight line parts 346 can be multiple, z. B. in pairs, run parallel between the transverse lines 34c (see. Fig. 4). .

The liquid refrigerant flows from the line 34 together with refrigerant vapor into the accumulator 34a, then passes line 35 in bridge 44 and line 36 and arrives at the lower part of the Accumulator 37 in the evaporator part 246. The refrigerant vapor flowing from the accumulator 34a into the Accumulator 37 flows in, together with the refrigerant evaporated there through line 38 in the suction line 39 of the heat exchanger 40 is sucked.

The F i g. 5, 6 and 7 schematically show various steps in the manufacture of the evaporator 24 according to FIG Fig.8 from those shown in Fig.4, .with each other connected sheets 41 and 42. From the outset, these sheets are 41,42 with a U-shaped slot 53 and Recesses 54, 55 are provided. To manufacture the evaporator parts 24a and 246, the part 24a ″, which is of the U-shaped slot 53 is surrounded, bent along a line 56 (see FIG. F i g. 4) and then forms a Wall at right angles from the on the longitudinal edges of the sheets 41,42 outside of the two parallel legs of the U-shaped slot 53 located bridges 43, 44 goes out. The in F i g. 5 and 6 overhead evaporator part 24a 'is along a line in FIG. 4 drawn line 57 bent so that it is parallel to the part 24a " Wall forms (see. Fig. 6). The lower, curved ones or angled sections 43a and 44a of bridges 43, 44 can be used simultaneously or after Bending of the sheet metal parts 24a ″ and 24a ′ are deformed.

At the end the sheet metal parts 24a ', 24a "and 24a'" from the position ■ according to FIG. 6 in relation to Evaporator part 246 bent at an angle of 180 "at the location of the upper bridge arches 43, 44, so that the evaporator is given the shape according to FIG. 7. Between the top and bottom part 24a "and 24a are then still in appropriately insert side walls 58 made of sheet metal, so that one only on the front side 22a opened freezing chamber 16a arises.

According to the invention, both the evaporator 24 and the horizontal partition 21 insert through the open front into the interior 16 of the cabinet housing 11. How best from the F i g. 13 and 15, there is a partition wall 21 from a relatively deep shell 60 and a cover 61 that fits this. The shell 60 is

ίο preferably made of plastic and takes a body 62 made of heat insulating material. 4, The long sides of the shell 60 are facing outwards directed paragraphs 63 provided, which on edges 64 of the side walls 17 of the inner lining 12 put on. To a particularly extensive isolation of the freezing chamber 16a from the outside atmosphere to achieve is between the wall sections 17a of the side walls 17 of the inner lining 12 over the edges 64 provided a greater distance from the outer clothing 14 than between the Wall sections 176 of the inner side walls and the outer lining in the area below the edges 64. This is also from FIG. 3 can be seen where the left side, a horizontal section above the partition wall 21 and the right side shows one below the partition wall 21.

The outer clothing 14 is formed with front surfaces 14a on which the front edges of the inner clothing 12 are attached in an appropriate manner. The cabinet housing 11 is on the front with a Cover strip 65 is provided, which is arranged between the heat-insulated doors 23a, 236 (FIG. 1). In Fig. 13 it is shown that the cover strip 65, which may be made of sheet metal, e.g. B. aluminum sheet, with flanges 66, 67 is provided, by means of which the removable cover strip 65 on the edges 68 and 69 of the shell 60 or the cover 61 of the partition wall 21 can be attached. The cover strip 65 and the front 60a of the shell 60 form a cavity in front of the partition wall 21, in which a heat-insulating Material 70a is inserted. In Figs. 12 and 14 is shown that the cover strip 65 is provided with end portions 65a which are in a plane with and on the edge of the Front part 14a of the outer housing 14 are and detachably attached to it, for example with screws 70 are.

At the same height as the edges 64 on the side walls 17, the rear wall 18 has supporting lugs 71 * separated by a gap 72 (see FIG. 2). A passage (not shown) on the back of the partition 21 in the region of the space 72 allows water to flow from the cover 61 of the partition 21 over the inner surface of the rear wall 18 to a channel 73 from which the collected water can be directed away in an expedient manner. The rear side wall of the shell 60 is provided with short paragraphs 63a analogous to the paragraphs on the other sides resting on the lugs ₀ 71st ^: ■ «* '^ ¹ *' _:.

There are openings 74 between the short rear shoulders 63a and the edges 64 on the side walls 17 formed, through which the bridges 43 and 44 are guided (see FIG. F i g. 2). Panels 75 semicircular shape can attach to the bottom of the shell 60 of the partition wall 21 to the lower inclined parts 43a, 44a of the To cover bridges 43,44.

When the septum 21 and the evaporator 24 through the front opening of the cabinet housing 11

14 / b yfc> 2

are to be introduced, a body 76 of insulating material, e.g. B. polyurethane foam, between the Rear wall 24a '"and the bridges 43 and 44 attached, as shown with dashed lines on the right in Fig. 1 is indicated. When the evaporator later assumes its final position in the cabinet housing 11, sits the insulating body 76 at the rear end 52 of the upper space 16a 'at the rear of the Cryogenic evaporator 24a. The septum 21 is pushed in on the edges 64 until the short Paragraphs 63a on the rear side of the septum on the shoulders 71 of the inner lining for support come. In Fig. 15 it is shown that the side walls 16a are provided with diaphragms 61a to the To cover the slot between the cover 61 and the side walls 17,18.

In the rear wall of the cabinet housing 11 there is an opening 77 through which the heat exchanger 40 is performed. This opening 77 represents the only breakthrough in the thermal insulation. It is necessary to to connect the evaporator 24 to the other parts of the refrigeration system. The leadership of the heat exchanger 40 through the rear wall happens behind the high-temperature evaporator 246 and is thus hidden. Only its lower end, with which it is connected to the evaporator 246 in the recess 45, is used by the Front of the cabinet housing 11 from visible. In the The openings 77 in the rear wall of the cabinet housing 11 are expediently rubber sleeves 78 Od. The like. Used to obtain an airtight seal and the insulation 15 against moisture protection.

The heat exchanger is expediently only used when the evaporator 24 is installed in the cabinet connected to the lower evaporator part 246. First, the free end of the heat exchanger 40 is through the Opening 77 is introduced into the rear wall, after which the rubber bushings 78 are inserted into the opening 77. Then the capillary tube 31 at the connection point 3 Γ with the outlet of the capacitor 28 and the Line part 39a of the suction line 39 at the connection point 39 'with the outer tube of the heat exchanger 40 connected (see Fig. 8).

After the vaporizer part 246 has been inserted into the chamber 166, it can by means of a holder 79 be releasably attached to the inner lining at both edges of the rear wall 18. In this In this way, it is securely held in a position that water drips into the collecting channel 73 during defrosting can.

When it is necessary to remove the evaporator 24 from the chamber 16, the holder 79 of the lower evaporator part 24b is first released can be removed. Then the partition wall 21, the evaporator 24 and the insulating body 76 can be pulled out of the cabinet towards the front. In this way it is possible to clean the inside of the cabinet if this should be necessary. The method of introducing the evaporator 24 into the chamber 16 of the cabinet from the front also has the further advantage that the otherwise necessary large opening in the rear wall of the cabinet, through which the evaporator is usually introduced, can be avoided.

The structure according to the invention of the evaporator 24 allows it to be produced from the metal sheets 41 and 42 without any substantial loss of material. A single U-shaped slot 53 and the small recesses 45, 54, 55 are required, the recess 45 having the purpose of simplifying the connection of the heat exchanger 40 to the evaporator part 24b , and the recesses 54,55 the lower sections 43a, 44a of the connecting bridges 43, 44 help to form, which are guided through the openings 74 on the rear side of the partition wall 21. _;

With the bridges 43, 44 on opposite longitudinal sides of the metal sheets, 41, 42 the unit very stiff, which is evident in the handling of the vaporizer during the various manufacturing steps is of great importance.

By the method of using the cryogenic evaporator 24a during the manufacture of the apparatus shown in FIG. 6 shown in the in F i g. 7 and 8, one obtains connecting bridges 43, 44 between the low-temperature evaporator and the high-temperature evaporator 24b, which are connected to the main parts of the evaporator from the outset and which are also extremely long and therefore represent a relatively poorly heat-conducting connection between these parts. With such an evaporator device it is possible to defrost the high-temperature evaporator 246 without influencing the temperature at the low-temperature evaporator 24a during the defrosting time. As best seen in FIGS. 1 and 8, the bridges 43 and 44 run perpendicularly to the side of the low-temperature evaporator 24a over at least the main part of the height of the same. This is achieved by the above-described bending process during manufacture, so that the bridges 43 and 44 run in a vertical direction parallel to the rear wall 24a "'of the evaporator 24a over essentially its length and then continue vertically down into the high-temperature chamber 166 over a distance which corresponds to the thickness of the horizontal partition wall 21. In this embodiment, the bridges 43, 44 together with the rear wall 24a '"are given the shape of an inverted U, the bottom of which is located essentially at the same level as the ceiling 24a" of the evaporator 24a is.

In operation, the low temperature evaporator 24a and the high temperature evaporator 24b will extract heat from the freezing chamber 16a and the cooling chamber 166. The parts of the evaporator 24 which have refrigerant lines in open communication with one another will operate at essentially the same temperature. Nonetheless, it is possible to maintain a substantial temperature difference between the freezing chamber 16a and the high temperature chamber 166 by properly sizing the length of the refrigerant flow path in each evaporator part and the size of the metal parts that make up those evaporator parts. If the refrigeration system operates while maintaining a temperature of -18 to -25 ° C in the freezing chamber 16a, the high temperature evaporator 246 will establish a storage temperature in chamber 166 that is above freezing. Under such operating conditions, there can also be a tendency for frost to form on the high-temperature evaporator 246.

After the desired temperature is reached in chamber 166, thermostat control enters Function and switches off the engine via switch 49,

709 617/442

which drives the compressor 25. The sensing element 50 is connected to the high-temperature evaporator 246 in a thermally conductive manner in such a way that, once the power has been switched off, the thermostat does not switch on again until the high-temperature evaporator 24b has completely defrosted. For this purpose, the thermostat can be set so that it always switches on at the same temperature. This temperature is for example about +1 or +2 ⁰ C, so therefore the high temperature evaporator 24b is always defrosted before restarting. The switch-off temperature of the thermostat, on the other hand, can be used for various purposes

10

can be set differently.

Since the freezing chamber 16a is very well insulated by the insulation 15, the partition 21 and the body 76 and the relatively narrow bridges 43 and 44 between the low-temperature evaporator 24a and the high-temperature evaporator 24b represent a relatively poorly heat-conducting connection, the temperature of the freezing chamber 16a in the essential the intended low

ίο Maintain value, even during periods when the Switch 49 is switched off and the motor compressor 25 is at a standstill.

In addition 5 sheets of drawings

Claims (9)

Patent claims: 1. Refrigerator with two thermally insulated chambers and one with a compressor Refrigerator, the evaporator of which is made up of two metal sheets, one on top of the other, connected to one another with flow paths for the refrigerant formed in between and by slitting and bending of the metal sheets is divided into firstly a ceiling, floor and back wall one Part forming the freezing chamber, secondly a part which projects down into a cooling chamber below the freezing chamber and is parallel to the rear wall Plate-shaped part extending in a plane and, thirdly, narrow connecting links in the form of Bridges or ribbons leading refrigerant lines between the first two parts mentioned, characterized in that the rear wall (24a '") at a distance from the rear wall (18) of the Cabinet housing (11) is arranged, the connecting bridges (43,44) near the ceiling (24a ") of the Rear wall (24a '") are bent back and down and between the rear wall (24a'") and on the The connecting bridges (43,44) guided along the rear wall of the cabinet housing form a body (76) heat insulating material is attached. 2. A refrigerator according to claim 1, characterized in that between the partition (22) between the freezing and cooling chamber (16a, b) and the rear wall (18) of the cabinet housing (11) in the vertical direction there are openings (74) through which the Connecting bridges (43,44) are performed. 3. Refrigerator according to claim 1 or 2, characterized in that the transition from the Connecting bridges (43, 44) in the second evaporator part (24Z>) in the cabinet housing (11) in the Located near the bottom of the partition (22) and the rear wall (18) of the cabinet housing (11) has a drip channel (73) for collecting water that settles on the plate-shaped second evaporator part (246) precipitates and drips down from there. ■ "■■ 4. Refrigerator according to one or more of the preceding. Claims, characterized in that the evaporator (24) and the partition (22) can be introduced through the open front of the cabinet housing (11) ^{.: <} 5. Refrigerator according to ".: 'Claim 4, characterized characterized in that the inner lining (17) of the side walls of the cabinet housing (11) with a support surface (64) are provided for supporting the partition (22) and a horizontal cover strip (65) in front of this between the front parts (14a) of the side walls of the cabinet housing (11) over it front opening extends, wherein the cover strip (65) both on the front parts (14a) and on the Partition wall (22) is removably attached. 6. Refrigerator according to one or more of the preceding claims, characterized in that that the freezing chamber (16a) with a better insulating material or greater wall thickness the side walls of the cabinet housing (11) achieved stronger insulation than the one below Cooling chamber (16Z?) Is provided. 7. Refrigerator according to one or more of the preceding claims, characterized in that that the heat-insulating septum (22) from a relatively deep shell with a Insulating body (62) and a cover (61) over it and that the side walls (17) of the cabinet housing (11) wear diaphragms (61a) which secure the position of the cover (61) on the shell (60) for as long the partition (22) rests removably on the bearing surfaces (64) of the side walls (17). 8. Refrigerator according to one or more of the preceding claims, characterized in that the ceiling (24a ') is located between the connecting bridges (43, 44) and is narrower than the bottom (24a) and the rear wall (24a '") . 9. Refrigerator according to one or more of the preceding claims, characterized in that the three parts (24a ' ₍ a ", a'") of the evaporator part (24a) are connected to one another by side parts (58) made of sheet metal, so that a after box open at the front is created.