DE102018205523A1 - Cooling device with an evaporator - Google Patents

Abstract

The present invention relates to a refrigerating apparatus (1) comprising an evaporator (20) provided in a refrigerating compartment (10) and at least one pipe (24) formed in a predetermined shape; a primary end (26) and a secondary end (27) of the tube (24); and a plurality of ribs (23) connected to the tube (24) in such a manner that a ribbed portion (22) and at least one non-ribbed portion remaining outside the ribbed portion (22) Area (221) are formed, comprising. As an improvement, the cooling device (1) comprises at least one isolation element (30) which at least partially covers the non-ribbed area (221) and the primary end (26) and / or the secondary end (27) of the tube (24) ,

Description

TECHNICAL AREA

The present invention relates to a refrigerating apparatus, particularly a refrigerator, more particularly to a no-frost refrigerator comprising an evaporator provided in a refrigerating compartment and having at least one pipe formed in a predetermined shape and a plurality of ribs which are connected to the pipe in such a manner as to form a ribbed area and at least two lateral areas remaining outside the ribbed area and where at least one rotary part of the pipe is provided at a time.

KNOWN PRIOR ART

In refrigeration systems, the evaporator is the part where the cooling fluid enters as liquid and is vaporized and exits as gas. When the cooling fluid enters the evaporator tubes, it absorbs the heat in the medium and evaporates.

In the application with the publication number EP2899481 There is provided a refrigerator comprising a freezer compartment separated by a heat insulating wall, a cold storage compartment disposed above the freezer compartment, and a radiator compartment disposed behind the freezer compartment. The refrigerator further includes a cooling device disposed in the radiator compartment and having vertically stacked refrigerant tubes equipped with fins, and a cold storage compartment return passage returning cold air returning from the cold storage compartment to the cooler compartment, the cold storage compartment return passage being on one side of the cold storage compartment Cooling device is arranged. The lateral length of a lower part of the refrigerant tubes of the cooling device is made shorter than the lateral length of an upper part of the refrigerant tubes to improve the cooling effect by reducing pressure losses of the flow path and to distribute ice making parts of the cooling device.

BRIEF DESCRIPTION OF THE INVENTION

The object of the present invention is to provide a no-frost cooling apparatus in which the ice accumulation formed on the evaporator is reduced.

The present invention relates to a cooling apparatus comprising an evaporator provided in a refrigerating compartment and at least one pipe formed in a predetermined shape; a primary end of the tube and a secondary end of the tube; and a plurality of fins connected to the tube in such a manner as to form a finned portion and at least one non-finned portion remaining outside the finned portion. Accordingly, the cooling device comprises at least one insulating element which at least partially covers the non-ribbed area and the primary end and / or the secondary end of the tube. Therefore, the portions remaining outside of the ribbed portion are positioned inside the insulating material. Thus, the parts remaining outside the ribbed area are prevented from setting ice. In this way, the ice accumulation on the evaporator is reduced, and the process of defrosting (defrosting) is facilitated.

The predetermined shape may be a stacked or coiled tube structure. The structure can be obtained by successively bending the tube and having parallel rectilinear regions, for example like a coil.

In one possible embodiment of the invention, the isolation element extends along the at least one non-ribbed area. Thus, all sections that are not ribbed remain within the insulation. In this way, the frosting of the non-ribbed portion is prevented, and the process of defrosting the same is eliminated.

In one possible embodiment of the invention, the at least one non-ribbed area may be at least one lateral side of the evaporator. Thus, the portion where less air flows and / or less heat exchange takes place is covered by the insulating member.

In one possible embodiment of the invention, the isolation element is provided on the two lateral sides of the evaporator. Thus, all non-finned portions of the evaporator remain within the isolation member.

In one possible embodiment of the invention, the at least one non-ribbed portion comprises bent portions of the tube. Thus remain on the evaporator, the bent portions of the tube within the insulating element.

In one possible embodiment of the invention, one of the primary end and the secondary end exits the cooling compartment upon exiting the isolation member. Thus, the exposure of the end in question becomes moister Cold air is prevented as much as possible and ice accumulation is reduced.

In one possible embodiment of the invention, at least one capillary tube is connected to one of the primary end and the secondary end by means of a narrowing tube section which remains covered by the isolation element. Thus, the narrowing pipe section remains within the insulation element. Therefore, icing of this part is prevented, and the noise which may occur due to the narrowing of the cross section is reduced.

In one possible embodiment of the invention, the capillary leaves the cooling compartment after emerging from the insulation element. Thus, exposure of the capillary tube to humid cold air is prevented as much as possible, and ice accumulation is reduced.

In one possible embodiment of the invention, a fan is provided in the vicinity of the refrigerating compartment, and the ribs and the direction of the air flow of the fan extend in the same direction. Thus, an air flow within the evaporator is facilitated, and the heat transfer performance is improved.

In one possible embodiment of the invention, an empty space is provided between the finned area and the fan to provide a free air flow path. Thus, a blockage of the air flow between the evaporator and the fan is prevented.

In one possible embodiment of the invention, the insulation element is made of expanded polystyrene foam (EPS) material. Thus, the insulation is ensured at low cost.

list of figures

• In 1 a side sectional view of a possible cooling device is shown.
• In 2 Fig. 12 is a representative plan view of the refrigerating compartment and the evaporator of the no-frost cooling apparatus under consideration.
• In 3 an isometric view of the evaporator is given without the first further insulation element.
• In 4 is a sectional front view of the evaporator with the first and the second further insulation element shown.

DETAILED DESCRIPTION OF THE INVENTION

In this detailed description, the disclosed cooling device ( 1 ) with reference to examples, without any restrictive effect, in order to make the subject easier to understand.

As in 1 shown, the cooling device ( 1 ) a refrigerator with a freezer section ( 2 ) and a refrigerator section ( 3 ), that of a body ( 5 ) and a door ( 6 ) is enclosed. Between these sections is a horizontal post ( 4 ) available. An evaporator ( 20 ) is inside the post ( 4 ) or above or below this.

As in 2 can be seen, the disclosed cooling device ( 1 ) a refrigerated compartment ( 10 ) on. The evaporator ( 20 ) is inside the refrigerator compartment ( 10 ), and at least one fan ( 11 ) is near the evaporator ( 20 ) intended. The evaporator ( 20 ) has at least one tube ( 24 ), which is serpentine wound, and a plurality of ribs ( 23 ) connected to the pipe ( 24 ) are connected. More precisely, the pipe ( 24 ) has a primary end ( 26 ) and a secondary end ( 27 ) on. The pipe ( 24 ) has straight portions extending substantially parallel to each other and bent portions (FIG. 25 ) provided between the straight sections. Ribs ( 23 ) are essentially with the straight sections of the tube ( 24 ) connected. Thus, the ribs define ( 23 ) a ribbed area ( 22 ), which the straight sections of the tube ( 24 ). Accordingly, the bent portions remain ( 25 ) outside of the ribbed area ( 22 ). In one possible embodiment of the present invention, the ribs extend ( 23 ) substantially in an orthogonal direction to the extending direction of the straight portions of the pipe ( 24 ). The fan ( 11 ) is the direction of extension of the ribs ( 23 ). Accordingly, a flow of air between the ribs ( 23 ) on. Thus, by the ribs ( 23 ) ensures effective heat transfer.

As in 3 can be seen, the bent sections ( 25 ) of the pipe ( 24 ) outside of the ribbed area ( 22 ), in a so-called non-ribbed area ( 221 ), and on the two lateral sides ( 21 ) of the evaporator ( 20 ). The primary end ( 26 ) and the secondary end ( 27 ) are on the lateral side ( 21 ) intended. The primary end ( 26 ) extends from the vicinity of a corner of the evaporator ( 20 ) in the body ( 5 ) of the cooling device ( 1 ), in particular within the insulating material (eg polyurethane foam) within the walls of the Body ( 5 ). The secondary end ( 27 ) extends at least partially along the lateral side ( 21 ). The secondary end ( 27 ) has a narrowing pipe section ( 29 ) at a predetermined location, and it is with a capillary tube ( 28 ) coupled. The capillary tube ( 28 ) bends from the surroundings of a corner of the evaporator ( 20 ) and extends in the direction of the primary end ( 26 ), and it essentially leads into the cooler body ( 5 ), together with the primary end ( 26 ). Thus leaving both the primary end ( 26 ) as well as the capillary tube ( 28 ) the cooling compartment ( 10 ).

According to the present invention, the primary end ( 26 ) and the secondary end ( 27 ) on the same lateral side ( 21 ) of the evaporator ( 20 ) intended. In another embodiment of the present invention, the primary end ( 26 ) and the secondary end ( 27 ) on different lateral sides ( 21 ) of the evaporator ( 20 ) be provided.

There are two isolation elements ( 30 ) are provided in a shape which partially covers the lateral sides ( 21 ) of the evaporator ( 20 ). The evaporator ( 20 ) and the isolation elements ( 30 ) are between a first further insulation element ( 31 ) and a second further insulation element ( 32 ) inside the refrigerated compartment ( 10 ) locked in. The isolation element ( 30 ) extends substantially along the lateral side ( 21 ). The isolation element ( 30 ) is preferably provided in such a way that it supports the bent portions ( 25 ) on a lateral side ( 21 ) and a certain part of the primary end ( 26 ) and the secondary end ( 27 ). As in 5 shown, are the secondary end ( 27 ) and the capillary tube ( 28 ) between the insulation element ( 30 ) and the first further insulation element ( 31 ) isolated. The first further insulation element ( 31 ) also covers the upper section of the evaporator ( 20 ). The second further insulation element ( 32 ) covers the lower section of the evaporator ( 20 ). For all insulation elements ( 30 . 31 . 32 ) EPS (expanded polystyrene foam) is used.

The non-ribbed area ( 221 ) of the evaporator ( 20 ) remains within the insulation material ( 30 ). Thus, ice accumulation on the parts outside the finned region ( 22 ) remain prevented. Therefore, more efficient defrosting is ensured. In other words, the defrost is ensured at a lower temperature and with a shorter duration. In addition, the accumulation of ice or frost on the fan ( 11 ) reduced.

In addition, the narrowing tube section remains ( 29 ) within the isolation element ( 30 ). This will isolate the noise that can occur in this part due to the change in cross section.

As in 3 can be seen, an empty space ( 12 ), which forms a free air flow path, between the ribbed area (FIG. 22 ) and the fan ( 11 ), because the primary end ( 26 ) and the secondary end ( 27 ) in the vicinity of the bent sections ( 25 ), in other words, since the primary end ( 26 ) and the secondary end ( 27 ) on the lateral sides ( 21 ) are provided. Thus, the air flow between the fan ( 11 ) and the ribs ( 23 ) facilitated. In other words, entry of the primary end ( 26 ) or the secondary end ( 27 ) between the ribs ( 23 ) and the fan ( 11 ) is prevented, and an adverse effect on the air flow is prevented, such as a prevention of the free air flow due to the tube ( 24 ) or, even more, as a result of ice, possibly at the primary and secondary ends ( 26 . 27 ) has formed.

LIST OF REFERENCE NUMBERS

1

cooler

2

Freezer section

3

refrigerator section

4

post

5

body

6

door

10

refrigerated compartment

11

Fan

12

Empty space

20

Evaporator

21

Lateral side

22

Ribbed area

221

Non-ribbed area

23

rib

24

pipe

25

Curved section

26

Primary end

27

Secondary end

28

capillary

29

Narrowing pipe section

30

insulation element

31

First additional insulation element

32

Second additional insulation element

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2899481 [0003]

Claims (11)

Cooling apparatus (1) comprising an evaporator (20) provided in a refrigerating compartment (10) and at least one pipe (24) formed in a predetermined shape; a primary end (26) and a secondary end (27) of the tube (24); and a plurality of ribs (23) connected to the tube (24) in such a manner that a ribbed portion (22) and at least one non-ribbed portion remaining outside the ribbed portion (22) Area (221) are formed, characterized in that the cooling device (1) comprises at least one insulating element (30) which the non-ribbed area (221) and the primary end (26) and / or the secondary end ( 27) of the tube (24) at least partially covered. Cooling device (1) after Claim 1 wherein the isolation member (30) extends along the at least one non-ribbed portion (221). Cooling device (1) after Claim 1 or 2 wherein the at least one non-ribbed portion (221) is at least one lateral side (21) of the evaporator (20). Cooling device (1) after Claim 3 , wherein the insulation element (30) is provided on the two lateral sides (21) of the evaporator (20). Cooling device (1) according to one of the preceding claims, wherein the at least one non-ribbed portion (221) comprises bent portions (25) of the tube (24). Cooling device (1) according to one of the preceding claims, wherein one of the primary end (26) and the secondary end (27) leaves the cooling compartment (10) after exiting the insulation element (30). Cooling device (1) according to one of the preceding claims, wherein at least one capillary tube (28) is connected to one of the primary end (26) and the secondary end (27) by means of a narrowing tubular section (29) which is separated from the insulating element (30 ) remains covered. Cooling device (1) after Claim 6 wherein the capillary tube (28) leaves the cooling compartment (10) after exiting the isolation element (30). Cooling device (1) according to one of the preceding claims, wherein a fan (11) in the vicinity of the cooling compartment (10) is provided and the ribs (23) and the direction of the air flow of the fan (11) extend in the same direction. Cooling device (1) after Claim 9 wherein an empty space (12) is provided between the finned area (22) and the fan (11) to provide a free air flow path. Cooling device (1) according to one of the preceding claims, wherein the insulation element (30) is made of expanded polystyrene foam (EPS) material.

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