WO2017219518A1

WO2017219518A1 - Refrigerator and separate embedded-type air duct structure thereof

Info

Publication number: WO2017219518A1
Application number: PCT/CN2016/099421
Authority: WO
Inventors: 罗金兆; 李凌云; 闵龙; 陈小峰
Original assignee: 南京创维家用电器有限公司
Priority date: 2016-06-21
Filing date: 2016-09-20
Publication date: 2017-12-28
Also published as: CN106091537A

Abstract

A refrigerator and separate embedded-type air duct structure thereof. The separate embedded-type air duct structure comprises a freezing air duct (10) and a variable-temperature air inlet duct (20) communicated with the freezing air duct (10), and further comprises a first variable-temperature air duct (30), a second variable-temperature air duct (31), a refrigerating air inlet duct (40), and a refrigerating air duct (50). The first variable-temperature air duct (30) and the second variable-temperature air duct (31) are arranged in parallel, and an inlet end of the first variable-temperature air duct (30) and an inlet end of the second variable-temperature air duct (31) are both communicated with the variable-temperature air inlet duct (20). An outlet end of the second variable-temperature air duct (31) is communicated with the refrigerating air duct (50) by means of the refrigerating air inlet duct (40). A temperature-variable air door (301) is provided inside the first variable-temperature air duct (30), and a refrigerating air door (401) is provided inside the refrigerating air inlet duct (40). The structure achieves independent control of cold air of a refrigerating compartment (13) and a variable-temperature compartment (12), so as to achieve independent and accurate control over the temperature of the refrigerating compartment (13) and the variable-temperature compartment (12).

Description

Refrigerator and its discrete in-line duct structure

Technical field

The invention relates to the technical field of refrigerators, in particular to a refrigerator and a discrete in-line air duct structure thereof.

Background technique

The refrigerator compartment of the prior art is generally divided into a refrigerating compartment, a changing greenhouse and a freezing compartment. Since the refrigerating compartment and the greenhouse change a fan, the refrigerating compartment duct is connected to the variable greenhouse duct, and when the refrigerating compartment is cooled, it changes. The greenhouse is also cooled at the same time, and the temperature of the refrigerating compartment and the temperature of the greenhouse change with each other, so that the temperature of the refrigerating compartment and the greenhouse can not be controlled separately, and precise temperature control of the refrigerating compartment and the greenhouse can not be achieved.

Therefore, the prior art has yet to be improved and improved.

Summary of the invention

In view of the above-mentioned deficiencies of the prior art, the object of the present invention is to provide a refrigerator and its discrete in-line air duct structure, which can realize independent and precise temperature control of the refrigerating chamber and the variable greenhouse.

In order to achieve the above object, the present invention adopts the following technical solutions:

A discrete in-line air duct structure of a refrigerator, comprising a freezing air duct and a variable temperature air inlet duct communicating with the freezing air duct, wherein the discrete in-line air duct structure of the refrigerator further comprises a first variable temperature air duct, a second variable temperature air passage, a refrigerating air inlet duct and a refrigerating air duct, wherein the first variable temperature air duct and the second variable temperature air duct are juxtaposed, and the inlet end of the first variable temperature air duct and the second variable temperature air duct The inlet end is connected to the variable temperature inlet air duct, and the outlet end of the second variable temperature air passage is connected to the refrigerating air passage through the refrigerating inlet air duct; the first variable temperature air passage is internally provided with a variable temperature damper, A refrigerated damper is arranged inside the refrigerating inlet duct.

In the separate in-line air duct structure of the refrigerator, the freezing air duct is provided with a plurality of freezing air outlets, and the outlet end of the first variable temperature air duct is provided with a temperature changing air outlet, and the refrigerating air duct is provided with Several refrigerated air outlets.

In the discrete in-line air duct structure of the refrigerator, one side of the variable temperature inlet air duct is provided with a variable temperature return air duct, and one side of the refrigerating air inlet duct is provided with a refrigerating return air duct; The inlet end of the variable temperature return air duct is provided with a variable temperature return air inlet, and the inlet end of the refrigerating return air duct is provided with a refrigerating air return port, and a freezing air return port is disposed below the freezing air outlet.

The discrete in-line air duct structure of the refrigerator further includes an insulation layer, wherein the variable temperature inlet air duct, the variable temperature return air duct, the refrigerating inlet air duct, and the refrigerating return air duct are all embedded in the In the insulation layer.

In the discrete in-line air duct structure of the refrigerator, the first variable temperature air duct is formed in a detachable temperature change air duct assembly, and the variable temperature air duct assembly includes a first air duct foam member and a second air passage. The foam member and the air duct cover are fixed between the first duct foam member and the second duct foam member, and the air duct cover is engaged with the second duct foam member.

In the discrete in-line air duct structure of the refrigerator, the refrigerating damper is embedded in an integrally formed refrigerating air inlet duct, and a damper block for sealing heat insulation is disposed under the refrigerating damper.

In the discrete in-line air duct structure of the refrigerator, a vent hole is formed on the damper block.

In the discrete in-line air duct structure of the refrigerator, the damper pad is an EPS insulation block.

A refrigerator comprising a freezing compartment, a changing greenhouse and a refrigerating compartment, wherein the freezing compartment is provided with an evaporator, the refrigerator further comprising a discrete in-line duct structure of the refrigerator as described above, the freezing outlet and freezing The return air outlet is connected to the freezing chamber; the variable temperature air outlet and the variable temperature air return port are connected to the variable greenhouse; and the refrigerating air outlet and the refrigerating air return port are connected to the refrigerating chamber.

In the refrigerator, the outlet end of the variable temperature return air duct and the outlet end of the refrigerating return air duct are both connected to the evaporator.

Compared with the prior art, in the refrigerator and the discrete in-line air duct structure provided by the present invention, the discrete in-line air duct structure of the refrigerator includes a freezing air duct and a temperature-changing air inlet communicating with the freezing air duct. The air duct, the discrete in-line air duct structure further includes a first variable temperature air duct, a second variable temperature air duct, a refrigerating air inlet air duct and a refrigerating air duct, wherein the first variable temperature air duct and the second variable temperature air duct are juxtaposed Provided that the inlet end of the first variable temperature air duct and the inlet end of the second variable temperature air duct are both connected to the variable temperature inlet air duct, and the outlet end of the second variable temperature air passage passes through the refrigerating air inlet duct Connecting the refrigerating air duct; the first variable temperature air duct is internally provided with a variable temperature damper, and the refrigerating air inlet duct is provided with a refrigerating damper, and the first variable temperature air passage and the second variable temperature air passage are arranged in parallel The refrigerating air passage and the first variable temperature air passage connected by the two variable temperature air passages are separately arranged, and the variable temperature damper and the refrigerating damper are respectively disposed inside the first variable temperature air duct and the refrigerating air duct, respectively, thereby realizing independent control of the cold air of the refrigerating chamber and the variable greenhouse To achieve a cold room Precise temperature control becomes independent greenhouse.

DRAWINGS

Figure 1 is a front view of a refrigerator provided by the present invention;

Figure 2 is a cross-sectional view taken along line A-A of Figure 1;

Figure 3 is a cross-sectional view taken along line B-B of Figure 1;

4 is a schematic diagram of a discrete in-line air duct structure of a refrigerator provided by the present invention;

5 is a schematic structural view of an air passage inside a thermal insulation layer in a discrete in-line air duct structure of a refrigerator provided by the present invention;

6 is a schematic diagram of a cold air flow passage of a freezer compartment and a greenhouse in a refrigerator provided by the present invention;

Figure 7 is a partial cross-sectional view taken along line B-B of Figure 1;

Figure 8 is a partial cross-sectional view taken along line A-A of Figure 1;

Figure 9a is an enlarged schematic view of A in Figure 7;

FIG. 9b is a schematic diagram of a cold air flow when the variable temperature damper is opened in the discrete in-line air duct structure of the refrigerator provided by the present invention; FIG.

10 is an exploded view of a variable temperature air duct assembly and a variable temperature air damper in a discrete in-line air duct structure of a refrigerator provided by the present invention;

Figure 11a is an enlarged schematic view of B in Figure 8;

Figure 11b is a schematic view showing the flow of cold airflow when the refrigerating damper is opened in the discrete in-line air duct structure of the refrigerator provided by the present invention;

Figure 12 is an exploded view of the refrigerating inlet air duct refrigerating damper in the discrete in-line duct structure of the refrigerator provided by the present invention.

detailed description

In view of the disadvantages of the prior art that the refrigerating compartment air duct communicates with the variable greenhouse air duct, the temperature of the refrigerating compartment and the variable greenhouse cannot be separately controlled, and the present invention provides The refrigerator and its separate in-line air duct structure can realize the independent control of the cold air of the refrigerating room and the changing greenhouse, thereby achieving independent and precise temperature control of the refrigerating room and the changing greenhouse.

The present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to FIG. 1 , FIG. 2 , FIG. 3 and FIG. 4 , the refrigerator provided by the present invention includes a freezing compartment 11 , a greenhouse 12 and a refrigerating compartment. 13 , an evaporator 14 is disposed in the freezing chamber 11 , and the evaporator is cooled by the evaporator 14 Produced to achieve refrigeration, the refrigerator further includes a discrete in-line duct structure that enables independent temperature control of the refrigerating compartment 13 and the variable greenhouse 12.

Specifically, the discrete in-line air duct structure of the refrigerator provided by the present invention includes a freezing air duct 10 and a variable temperature air inlet duct communicating with the freezing air duct 10 20, the discrete in-line air duct structure of the refrigerator further includes a first variable temperature air duct 30, a second variable temperature air duct 31, a refrigerating air inlet duct 40, and a refrigerating air duct 50, wherein the first variable temperature air duct 30 And the second variable temperature air duct 31 is arranged in parallel, and the inlet end of the first variable temperature air duct 30 and the inlet end of the second temperature change air duct 31 are both connected to the temperature change air inlet duct 20, and the second variable temperature air duct 31 The refrigerating air duct 40 communicates with the refrigerating air duct 50 through the refrigerating air inlet duct 40; the first temperature changing air duct 30 is internally provided with a temperature changing damper 301, and the refrigerating air inlet duct 40 is internally provided with a refrigerating damper 401.

Please refer to FIG. 5, FIG. 6, FIG. 7 and FIG. 8 together, and the freezing air duct 10 is provided with a plurality of freezing air outlets 101. The outlet end of the first variable temperature air duct 30 is provided with a temperature-changing air outlet 302, and the refrigerating air duct 50 is provided with a plurality of refrigerating air outlets 501. The variable temperature inlet air duct 20 One side of the refrigerating air inlet duct 40 is provided with a refrigerating return air duct 70, and the inlet end of the variable temperature return air duct 60 is provided with a variable temperature return air port 601. The inlet end of the refrigerating return air duct 70 is provided with a refrigerating air return port 701, and a freezing air return port 102 is disposed below the refrigerating air outlet 101.

The freezing air outlet 101 and the freezing air return port 102 are in communication with the freezing chamber 11; the temperature changing air outlet 302 And the variable temperature return air inlet 601 is connected to the variable greenhouse 12; the refrigerating air outlet 501 and the refrigerating air return port 701 are connected to the refrigerating chamber 13; the outlet end of the variable temperature return air duct 60 and the refrigerating return air duct The outlet end of 70 is connected to the evaporator 14 .

Figure 4, Figure 5, Figure 6, Figure 7, and Figure 8 As shown, the solid arrow direction is the cold air inlet direction, the dotted arrow direction is the cold air return direction, and the cold air generated by the evaporator 14 is sent to the freezer compartment through the freezing air outlet 101 on the freezing duct 10 Inside, the freezing compartment 11 is cooled, and the cold air of the freezing compartment 11 passes through the freezing return air outlet 102 and returns to the evaporator 14 to circulate the cold air; after that, the cold air enters the first variable temperature air passage through the variable temperature inlet air duct 20, respectively. 30 and the second variable temperature air passage 31, the cold air is sent to the changing greenhouse 12 through the variable temperature air outlet 302 disposed at the outlet end of the first variable temperature air duct 30, so that the greenhouse 12 is cooled and the greenhouse is changed. The cold air then enters the variable temperature return air passage 60 through the variable temperature return air inlet 601, and then the cold air returns to the evaporator 14 through the variable temperature return air passage 60; and enters the second variable temperature air passage 31. The cold air enters the refrigerating air duct 50 through the refrigerating air inlet duct 40 connected to the second variable temperature duct 31, and is then transported to the refrigerating chamber through a plurality of refrigerating air outlets 501 provided on the refrigerating duct 50. The refrigerating compartment 13 is cooled, and the cold air of the refrigerating compartment 13 enters the refrigerating return air duct 70 through the refrigerating return air duct 701, and returns to the evaporator through the refrigerating return air duct 70. At the point, the air is circulated. The present invention provides the refrigerating air passage 50 communicating with the second variable temperature air passage 31 and the first variable temperature air passage 30 by providing the first variable temperature air duct 30 and the second temperature changing air passage 31 which are juxtaposed. The discrete arrangement avoids the disadvantages of the prior art that the temperature of the refrigerating compartment 13 and the greenhouse 12 cannot be separately controlled due to the air passage of the refrigerating compartment 13 and the greenhouse, and more precise temperature control.

Further, the discrete in-line air duct structure of the refrigerator further includes an insulation layer 80, the variable temperature inlet air duct 20, and a variable temperature return air duct 60. The refrigerating inlet duct 40 and the refrigerating return duct 70 are both pre-buried in the insulating layer 80. In specific implementation, the insulating layer 80 A foaming heat insulating material such as polyester may be used to realize the heat insulating and heat insulating function, that is, the temperature changing air inlet duct 20, the variable temperature return air duct 60, the refrigerating air inlet duct 40, and the refrigerating return air duct 70. The outer surface of the outer surface is surrounded by the foaming and heat insulating material, and the heat transfer is prevented to the utmost to ensure the cooling effect. Of course, the heat insulating layer 80 can also adopt other heat insulating materials, which is not limited by the present invention.

Specifically, as shown in FIG. 9a, FIG. 9b and FIG. 10, the first variable temperature air duct 30 is formed on a detachable variable temperature air duct assembly. 303, the variable temperature air duct assembly 303 includes a first duct foam member 3031, a second duct foam member 3032, and a duct cover 3033, and the variable temperature damper 301 The card is between the first duct foam member 3031 and the second duct foam member 3032, and the duct cover 3033 is engaged with the second duct foam member 3032. First duct foam piece 3031 The second air duct foam member 3032 can be made of a polyester foam filling material, which is insulated and insulated to ensure the cooling effect, and a detachable temperature change air duct assembly 303 is adopted, and the temperature change damper 301 is embedded in the variable temperature air duct assembly. In 303, it is convenient to install and disassemble the temperature change damper 301. As shown in Fig. 9a, when the temperature change damper 301 is closed, the cold air in the temperature change air inlet duct 20 cannot enter the first temperature change air passage 30. And then conveyed to the greenhouse 12, at which time the greenhouse 12 is cooled off; as shown in Fig. 9b, when the temperature change damper 301 is opened, the cold air in the variable temperature inlet duct 20 passes through the variable temperature damper 301. After entering the variable temperature air duct, it is transported to the variable greenhouse through the variable temperature air outlet 302 at the outlet end of the variable temperature air duct. At this time, the greenhouse 12 is cooled, thereby realizing the cooling control of the greenhouse 12.

Referring to Figures 11a, 11b and 12 together, the refrigerated damper 401 is embedded in the integrally formed refrigerated inlet duct 40 A damper block 402 for sealing heat insulation is disposed below the refrigerating damper 401. Refrigerated air inlet duct 40 The one-piece non-detachable part can be injection-molded at one time to improve the processing efficiency, and the refrigerating inlet duct 40 is pre-buried in the insulating layer 80, and one end thereof is connected to the second variable temperature duct in the variable greenhouse 12 The other end is connected to the refrigerating duct 50 in the refrigerating compartment 13, and the refrigerating damper 401 and the damper block 402 are embedded in the refrigerating inlet duct 40, wherein the refrigerating damper 401 and the damper block 402 Removable, the damper block 402 can function as a sealing and heat insulation to prevent freezing under the refrigerating damper 401. Specifically, the damper block 402 can adopt EPS. An insulating block, or other insulating material block, and the refrigerating damper 401 and the damper block 402 are disposed in the refrigerating inlet duct 40 to separate the refrigerating damper 401 from the refrigerating duct 50 In addition, the cooling of the refrigerating damper 401 is prevented due to poor building or assembly problems of the mounting components of the refrigerating duct 50, and the refrigerating damper 401 does not occupy the refrigerating duct 50. The space simplifies the structure of the refrigerating duct 50 and increases the space of the refrigerating compartment 13.

Wherein, the damper block 402 is formed with a vent hole 4021 so that the damper 401 is When opened, cold air can smoothly enter the refrigerating duct 50 through the damper block 402 and the refrigerating damper 401. Similarly, as shown in Fig. 11a, when the refrigerating damper 401 is closed, the refrigerating inlet duct 40 The cold air inside cannot enter the refrigerating air duct 50, and is transported to the refrigerating compartment, at which time the refrigerating compartment 13 is cooled and closed; as shown in Fig. 11b, when the refrigerating damper 401 is opened, the refrigerating air duct 40 is refrigerated. The inside cold air enters the refrigerating duct 50 through the refrigerating damper 401, and is then transported to the refrigerating compartment 13 through the refrigerating air outlet 501 provided in the refrigerating duct 50, at which time the refrigerating compartment 13 The cooling is turned on to achieve the refrigeration control of the refrigerating compartment 13.

Since the first temperature change air passage 30 and the second temperature change air passage 31 are disposed independently of each other, and the first temperature change air passage 30 and the second temperature change air passage 31 A variable temperature damper 301 and a refrigerating damper 401 are respectively embedded in the connected refrigerating inlet duct 40, and the cold air generated from the evaporator 14 can enter the variable greenhouse 12 and the refrigerating compartment through the two paths respectively. In the meantime, the temperature of the greenhouse 12 and the refrigerating compartment 13 are prevented from affecting each other, and the respective greenhouses can be controlled by controlling the opening and closing of the variable temperature damper 301 and the refrigerating damper 401, respectively. The cold air delivery of the refrigerating compartment 13 and the independent and precise temperature control of the refrigerating compartment 13 and the greenhouse 12.

In summary, in the refrigerator and its discrete in-line air duct structure provided by the present invention, the discrete in-line air duct structure of the refrigerator includes a freezing air duct and a variable temperature air inlet duct connected with the freezing air duct. The discrete in-line air duct structure further includes a first variable temperature air duct, a second variable temperature air duct, a refrigerating air inlet duct, and a refrigerating air duct, wherein the first variable temperature air duct and the second variable temperature air duct are juxtaposed, And the inlet end of the first variable temperature air duct and the inlet end of the second variable temperature air duct are both connected to the variable temperature air inlet duct, and the outlet end of the second variable temperature air duct is connected to the cold air through the refrigerating air inlet duct a wind tunnel; a temperature-changing damper is disposed inside the first variable temperature air passage, and a refrigerating damper is disposed inside the refrigerating air inlet duct, and the second variable temperature is set by the first variable temperature air passage and the second variable temperature air passage The refrigerating air passage connected with the air duct is separately arranged from the first variable temperature air passage, and the variable temperature damper and the refrigerating damper are respectively disposed inside the first variable temperature air passage and the refrigerating air duct respectively, thereby realizing independent control of the cold air of the refrigerating chamber and the changing greenhouse, thereby Achieve cold storage and temperature change Independent precise temperature control.

It is to be understood that those skilled in the art can make equivalent substitutions or changes to the inventions and the inventions of the present invention, and all such changes or substitutions fall within the scope of the appended claims.

Claims

A discrete in-line air duct structure of a refrigerator, comprising a freezing air duct and a variable temperature air inlet duct communicating with the freezing air duct, wherein the discrete in-line air duct structure of the refrigerator further comprises a first a variable temperature air duct, a second variable temperature air duct, a refrigerating air inlet duct and a refrigerating air duct, wherein the first variable temperature duct and the second variable temperature duct are juxtaposed, and the inlet end and the second end of the first variable temperature duct The inlet end of the variable temperature air duct is connected to the variable temperature air inlet duct, and the outlet end of the second variable temperature air duct is connected to the refrigerating air duct through the refrigerating air inlet duct; the first variable temperature air duct is internally provided with a temperature change A damper is provided with a refrigerating damper inside the refrigerating inlet air duct.
According to claim 1 The discrete in-line air duct structure of the refrigerator is characterized in that: the freezing air duct is provided with a plurality of freezing air outlets, and the outlet end of the first variable temperature air duct is provided with a temperature changing air outlet, the refrigerating wind There are several refrigerated air outlets on the road.
According to claim 2 The discrete in-line air duct structure of the refrigerator is characterized in that: one side of the variable temperature air inlet duct is provided with a variable temperature return air duct, and one side of the refrigerating air inlet duct is provided with a refrigerating return air The air inlet; the inlet end of the variable temperature return air duct is provided with a variable temperature return air inlet, the inlet end of the refrigerating return air duct is provided with a refrigerating return air outlet, and a freezing return air outlet is disposed below the freezing air outlet.
According to claim 3 The discrete in-line air duct structure of the refrigerator is characterized in that it further comprises an insulation layer, and the temperature-changing air inlet duct, the variable temperature return air duct, the refrigerating air inlet duct and the refrigerating return air duct are all buried. In the insulation layer.
According to claim 1 The discrete in-line air duct structure of the refrigerator, wherein the first variable temperature air duct is formed in a detachable temperature change air duct assembly, and the variable temperature air duct assembly includes a first air duct foam member, The air duct cover and the air duct cover are fixed between the first air duct foam member and the second air duct foam member, and the air duct cover is engaged with the second air duct foam member.
According to claim 1 The discrete in-line air duct structure of the refrigerator is characterized in that the refrigerating damper is embedded in an integrally formed refrigerating air inlet duct, and a damper block for sealing heat insulation is disposed under the refrigerating damper.
The discrete in-line duct structure of the refrigerator according to claim 6, wherein the damper block is formed with a vent hole.
The discrete in-line duct structure of a refrigerator according to claim 6, wherein the damper pad is EPS Insulation pad.
A refrigerator comprising a freezing compartment, a changing greenhouse and a refrigerating compartment, wherein the freezing compartment is provided with an evaporator, wherein the refrigerator further comprises the claim 1 The discrete in-line air duct structure of the refrigerator, the freezing air outlet and the freezing air return port are connected with the freezing chamber; the variable temperature air outlet and the variable temperature air return port are connected with the variable greenhouse; the refrigerating air outlet and the refrigerating air outlet Connected to the cold room;

The discrete in-line air duct structure of the refrigerator includes a freezing air duct and a variable temperature air inlet duct connected with the freezing air duct, and the discrete in-line air duct structure of the refrigerator further includes a first variable temperature air duct, a second variable temperature air passage, a refrigerating air inlet duct and a refrigerating air duct, wherein the first variable temperature air duct and the second variable temperature air duct are juxtaposed, and the inlet end of the first variable temperature air duct and the second variable temperature air duct The inlet end is connected to the variable temperature inlet air duct, and the outlet end of the second variable temperature air passage is connected to the refrigerating air passage through the refrigerating inlet air duct; the first variable temperature air passage is internally provided with a variable temperature damper, A refrigerated damper is arranged inside the refrigerating inlet duct.
According to claim 9 The refrigerator is characterized in that: the freezing air duct is provided with a plurality of freezing air outlets, the outlet end of the first variable temperature air duct is provided with a temperature-changing air outlet, and the refrigerating air duct is provided with a plurality of refrigerating air outlets .
According to claim 10 The refrigerator is characterized in that: one side of the variable temperature inlet air duct is provided with a variable temperature return air duct, and one side of the refrigerating air inlet duct is provided with a refrigerating return air duct; The inlet end of the air duct is provided with a variable temperature return air inlet, and the inlet end of the refrigerating return air duct is provided with a refrigerating air return port, and a freezing air return port is disposed below the freezing air outlet.
According to claim 11 The refrigerator is characterized in that it further comprises an insulation layer, and the temperature-changing inlet air duct, the variable temperature return air duct, the refrigerating inlet air duct and the refrigerating return air duct are all pre-buried in the heat insulation layer.
According to claim 9 The refrigerator is characterized in that the first variable temperature air duct is formed in a detachable temperature change air duct assembly, and the variable temperature air duct assembly includes a first air duct foam member, a second air duct foam member and a duct cover a plate, the variable temperature damper is fixed between the first duct foam member and the second duct foam member, and the duct cover is engaged with the second duct foam member.
According to claim 9 The refrigerator is characterized in that the refrigerating damper is embedded in an integrally formed refrigerating air inlet duct, and a damper block for sealing heat insulation is disposed below the refrigerating damper.
According to claim 9 The refrigerator is characterized in that both the outlet end of the variable temperature return air duct and the outlet end of the refrigerating return air duct communicate with the evaporator.