DE102006015994A1 - Refrigerating appliance with defrost heating - Google Patents

Abstract

A refrigerator has a storage chamber (6) and an evaporator chamber (5), which communicates with the storage chamber (6) via a cold air passage (14) and a warm air passage (9) and which contains an evaporator (8) and a defrost heater (15). The defrost heater (15) has a higher heating power density in an area adjacent to the warm air passage (9) than in an area adjacent to the cold air passage (10).

Description

The The present invention relates to a refrigerator with a storage chamber and an evaporator chamber, which communicates with the storage chamber via a cold air passage and a warm air passage communicates and the one evaporator contains cooled at which from the storage chamber incoming air and subsequently is returned to the storage chamber. Such refrigerators are also as no-frost devices designated.

Warmth Air that flows from the storage chamber into the evaporator chamber, carries moisture with himself, which tends to settle on the evaporator, so that on this in the course of operation of the refrigerator, a layer of ice grows. Around To avoid a deterioration of the efficiency of the device, this must be Ice layer can be eliminated from time to time. For this purpose is conventionally in the evaporator chamber, a defrost heater attached to the ice thaw on the evaporator and drain. The resulting condensation water collects at the lowest point of the evaporator chamber and from there through a passage to the outside, where it can evaporate.

Of the Defrosting burdened the energy balance of such a refrigerator, since the heating energy is not complete can be used to defrost the ice. So that defrosting at all that is, must begin first the evaporator from an operating temperature below 0 ° C, at 0 ° C heated be, and after the end of the defrosting process, the evaporator be cooled down to its operating temperature again before the Storage chamber cooled can be. Furthermore flows out of the evaporator chamber during defrost inevitably dissipates heat into the storage chamber, the latter subsequently must be withdrawn again. Such a drain of heat is around so stronger, The higher the temperature in the evaporator chamber during defrosting is.

Around To minimize the energy consumption during defrosting, it is therefore desirable in the evaporator chamber one possible homogeneous temperature distribution to realize the freezing point just above.

Surprisingly this goal is according to the invention to simple Way achievable by a defrost heater, which in a the warm air passage adjacent area a higher Has Heizleistungsdichte than in a cold air passage adjacent area.

Of the reason for this is that the air flowing through the evaporator chamber predominantly their entrained moisture discharges in an area adjacent to the hot air passage of the evaporator, so that There, the ice layer increases faster in thickness than in a den Cold air passage adjacent area. By according to the Hot air passage adjacent area of the evaporator with a higher Heizleistungsdichte is acted as the cold air passage adjacent area, thaws the ice in the hot air passage adjacent Area faster, allowing the ice layer substantially over the area throughout the evaporator at the same time. A Heating already defrosted areas, which there to a strong temperature increase leads, can be avoided.

The Heating is preferably plate-shaped, so they along a main side of the evaporator is placeable.

Preferably the heater extends below the evaporator, so that on her heated air can ascend through the evaporator.

Preferably the heater has a carrier plate and one on the carrier plate arranged heating coil on.

The Heating coil can on the support plate material fit, for Example by soldering, be attached to a good heat transfer from the heating coil to ensure the plate. An attachment The heating coil on the plate by latching also comes in Consideration.

Around to promote a heating of the evaporator by radiation, the heating coil is preferably at a side facing the evaporator Side of the plate arranged.

she should also be spaced from the plate for at least a portion of its length on the one hand, the drainage of condensation water from the evaporator the plate drips, not affecting, on the other hand to one Outflow of heat from the heating coil to the plate, the effectiveness of heat dissipation would reduce to limit.

Is appropriate it in such a case, too, if the plate is made of a material such as a metal, the incident heat radiation efficiently reflected, so as heat radiation, that of the heating coil in a direction away from the evaporator direction is radiated, yet to direct to the evaporator.

According to a first embodiment, the heating coil is arranged in the area adjacent to the hot air passage denser than in the region of the support plate adjacent to the cold air passage. This allows the use of a Heating coil with constant heating power per unit length over its entire length.

A Obstruction of the running through the evaporator chamber air flow through the heating coil can be kept low, if the latter in itself arranged in the passage direction of the air extending serpentines is. To realize the different distribution of heating power, then is preferably at least one of the serpentines completely on the area of the carrier plate adjacent to the hot air passage arranged.

one According to a second embodiment, the heating coil can be in the hot air passage adjacent Range a higher Heating power per unit length as in the area adjacent to the cold air passage. Then there is a different distribution of the heating power density as well feasible if the heating coil in both areas after the same pattern is arranged.

Around To keep the construction of the heating coil simple, it is in this the latter case prefers that the heating coil two connected in series Includes sections, one of which adjacent to the hot air passage Area and the other fills the area adjacent to the cold air passage.

In the two sections, the heating coil can be separated from each other be arranged in serpentine, extending in the direction of passage of the Air through the evaporator chamber extend.

If at the bottom of the evaporator chamber, a condensation channel is provided, in the condensation water from the evaporator converges, it may be appropriate to pass a section of the heating coil along the defrost channel to ensure that ice residues in the drainage channel do not drain away Prevent condensation water from the evaporator and dammed up dew water freezes again after the end of the defrosting process.

Further Features and advantages of the invention will become apparent from the following Description of exemplary embodiments with reference to the attached Characters. Show it:

1 a schematic section through an inventive refrigerator;

2 a perspective view of the evaporator housing of the refrigerator 1 with defrost heater disposed therein;

3 a plan view of the evaporator housing and the evaporator mounted therein according to a second embodiment of the invention; and

4 a schematic partial section through an evaporator housing according to a third embodiment of the invention.

1 shows a schematic section through the upper portion of a refrigeration device according to the invention. The refrigerator has a body 1 and a door 2 , each in a conventional manner than with a heat-insulating foam layer 3 filled hollow body are realized. The interior of the corpus 1 is by a likewise heat-insulating partition 4 divided into an evaporator chamber 5 and a storage room 6 , The evaporator chamber 5 is largely filled by a housing 7 an evaporator assembly in the interior of an evaporator 8th is mounted by known per se with running parallel to the cutting plane slats and a transverse to the slats in serpentine refrigerant line. Below the evaporator 8th is at the bottom of the case 7 a defrost heater 15 appropriate. The housing 7 has a warm air passage 9 at his door 2 facing side, through the warm air from the storage chamber 6 in the evaporator chamber 5 passes, and a passage 10 at its the back wall of the corpus 1 facing side 19 behind which is a fan 11 with paddle wheel 12 and engine 13 is housed, the air from the housing 7 pulls off and into a cold air passage 14 to the storage chamber 6 suppressed.

2 shows a perspective view of the housing 7 and the defrost heater mounted therein 15 , The housing 7 has a flat, back slightly sloping bottom plate 18 equipped with an electrically operated heating coil mounted on the defrost heater 15 forms. The bottom plate 18 consists of metal or plastic, which is metallically coated on its upper side to heat radiation radiated downwards from the heating coil to the top of the evaporator 8th to steer.

Between the bottom plate 18 and the back wall 19 of the housing 7 is located at the bottom of a gutter 20 extending over the entire width of the case 7 extends and to a drain opening 21 is inclined.

The heating coil includes a plurality of in the depth direction of the body 1 running serpentines 16 . 17 , The serpentines 16 . 17 are at the bottom plate 18 with the help of from the bottom plate 18 protruding elastic braces 22 held. The brackets 22 keep the heating coil from the bottom plate 18 spaced so that condensation water from the evaporator 8th on the bottom plate 18 drips, unhindered by the heating coil in the gutter 20 can drain away.

It change in the width direction of the bottom plate 18 short and long hairpin bends 16 respectively. 17 starting, each just below one of the hot air passage 9 adjacent area of the evaporator 8th or under the entire evaporator 8th extend and thus form two sections with different Heizleistungsdichten. Alternatively, serpentines could be provided in more than two different length stages, of which, however, all of the hot air passage 9 facing side of the evaporator 8th go out to this area of the evaporator most icing in operation 8th to heat the most intensively. A straight-lined section 23 the heating coil extends along the gutter 20 to ensure that there are no pieces of ice left in the water which hinder the drainage of the dew water.

3 shows a plan view of an evaporator housing 7 with an evaporator 8th and a defrost heater 25 according to a second embodiment of the invention. The shape of the case 7 with bottom plate 18 and gutter 20 is the same as with respect to 2 described, and also the evaporator 8th with one in lamellae 28 held refrigerant pipe 29 is with respect to 1 identical. The heating coil 25 has two sections 26 . 27 , which differ in their heating power per unit length. The more powerful section 26 runs below the warm air passage 9 adjacent area of the evaporator 8th , and the less powerful section 27 below the back wall 19 and thus the cold air passage adjacent portion of the evaporator. Both sections 26 . 27 are the same pattern, in the form of elongated serpentines in the depth direction of the body 30 , relocated. One in the transverse direction of the carcass 1 running serpentine 31 leading to the underperforming section 27 heard, heated the gutter 20 ,

4 shows in section a third embodiment of the invention. Here is the heating coil 15 with alternating long and short serpentines 16 . 17 from in 2 Type not shown from the bottom plate 18 kept spaced, but with this by Lot 32 good heat conducting connected. To prevent condensation on the gutter 20 facing curves 33 the serpentine dams, these are in the case of the short serpentines 16 bent slightly upwards, leaving water between them and the bottom plate 18 can flow through it; in the case of long hairpin bends 17 The curves extend over the gutter 20 , so that also here a free drain is guaranteed.

Claims (12)

Refrigerating appliance with a storage chamber ( 6 ) and an evaporator chamber ( 5 ), with the storage chamber ( 6 ) via a cold air passage ( 14 ) and a warm air passage ( 9 ) communicates and the one evaporator ( 8th ) and a defrost heater ( 15 ), characterized in that the defrost heating ( 15 ) in a warm air passage ( 9 ) adjacent area has a higher heating power density than in the cold air passage ( 14 ) adjacent area. Refrigerating appliance according to claim 1, characterized in that the defrost heater ( 15 ) is plate-shaped. Refrigerating appliance according to claim 2, characterized in that the defrost heater ( 15 ) below the evaporator ( 8th ). Refrigerating appliance according to one of the preceding claims, characterized in that the defrost heater ( 15 ) a carrier plate ( 18 ) and one on the carrier plate ( 18 ) arranged heating coil ( 16 . 17 ; 26 . 27 ) having. Refrigerating appliance according to claim 4, characterized in that the heating coil ( 16 . 17 ) on the carrier plate ( 18 ) is locked. Refrigerating appliance according to one of claims 4 to 5, characterized in that the heating coil ( 16 . 17 ; 26 . 27 ) on a the evaporator ( 8th ) facing side of the carrier plate ( 18 ) and arranged at least on a part of their length from the carrier plate ( 18 ) is spaced. Refrigerating appliance according to one of claims 4 to 6, characterized in that the heating coil ( 16 . 17 ) in the hot air passage ( 9 ) adjacent area is arranged denser than in the cold air passage ( 14 ) adjacent area of the carrier plate ( 18 ). Refrigerating appliance according to claim 6, characterized in that the heating coil ( 16 . 17 ; 26 . 27 ) in the passage direction of the air through the evaporator chamber ( 5 ) extending serpentines ( 16 ; 17 ; 30 ), wherein at least one of the serpentines ( 16 . 30 ) completely on the hot air passage adjacent area of the support plate ( 18 ) runs. Refrigerating appliance according to one of claims 4 to 6, characterized in that the heating coil ( 26 . 27 ) in the hot air passage ( 9 ) adjacent area has a higher heating power per unit length than in the cold air passage ( 14 ) adjacent area. Refrigerating appliance according to claim 9, characterized in that the heating coil comprises two sections ( 26 ; 27 ), one of which ( 26 ) the warm air passage ( 9 ) adjacent area and the other ( 27 ) the cold air passage ( 14 ) fills adjacent area. Refrigerating appliance according to claim 10, characterized in that the two sections ( 26 ; 27 ) each in the passage direction of the air through the evaporator chamber ( 5 ) extending serpentines ( 30 ) exhibit. Refrigerating appliance according to one of the preceding claims, characterized in that at the bottom of the evaporator chamber, a condensation gutter ( 20 ) and a section ( 31 ) of the heating coil along the drainage channel ( 20 ) runs.