KR0130911Y1 - Return suction structure of cold storage cold air return duct - Google Patents

Abstract

The present design forms a stepped step of the return cooling air inlet to avoid the phenomenon that pressure is concentrated inside the freezer through the return air inlet during the refrigerating door closing operation, so that the freezer door does not open. As related to the suction port, in the related art, when the opened refrigerating compartment door is quickly closed, there is a problem in that the return cooling air of the refrigerating compartment is introduced into the freezing compartment through the feedback cooling suction inlet, and the pressure of the freezing compartment is momentarily increased to push the freezing compartment door.

In order to solve this problem, the present invention, in the return air inlet of the refrigerating compartment cold air return duct connected to the cold air return duct through the inside of the upper side of the refrigerating compartment, the lower end of the side into which the return air is introduced into the upper inner phase of the refrigerating compartment is wide. It is formed, the upper end connected to the cold return duct is formed narrow, a plurality of stepped step is formed between the upper end and the lower end.

Description

Return cold air intake of cold room return duct

1 is a side cross-sectional view showing a schematic structure of a conventional cold return duct.

Figure 2 is a plan view of the main portion 1A direction showing the structure of the return cooling air suction inlet end of the conventional cold return duct.

Figure 3 is a side cross-sectional view showing the structure of the return air intake of the refrigerating compartment according to the present invention.

4 is a plan view of the main portion B in Fig. 3 showing the structure of the feedback cooling air suction inlet end of the present invention.

* Explanation of symbols for main parts of the drawings

40: cold air duct 80: return cold air

90: return cooling air inlet 92: bottom portion of the return cooling air intake

94: upper end of the return cooling air inlet 96: stepped portion of the return cooling air intake

100: refrigerating room interior wall

The present invention relates to the return air intake of the cold return duct formed in the upper side of the refrigerating compartment. In particular, the return air intake is formed in the freezer compartment through the return air intake during the refrigerating chamber door closing operation. It relates to a return cold air suction inlet of the refrigerating compartment cold air return duct to avoid the phenomenon of freezing.

Looking at the return air intake port, which is the lower end of the conventional cold air return duct formed on the front side of the conventional refrigerator compartment, as shown in FIGS. 1 and 2, an implantation plate located between the refrigerator compartment inner shell 12 and the freezer compartment inner shell 22 ( 30 to form a cold air return duct 40 by forming a flow path, and the return air suction inlet 50, which is the lower end of the refrigerating chamber side of the cold air return duct 40 is inclined downward by a predetermined angle. It is coming true.

This is a cold air suction structure for more effectively performing the role of the inflow passage that the cold air in the refrigerating chamber 10 is sent to the cooler 60 through the cold air return duct 40, that is, the temperature rising cold room (10) The return cooler (indicated by arrow 80) in the inner side of the refrigerating chamber 10 is passed through the cold air return duct 40 through the lower end of the return air inlet 50 connected to the cold air return duct 40 to the cooler 60 through the cold air return duct 40. The series ensures efficient delivery of a series of suction operations.

However, in the structure of the conventional feedback cooling air intake 50, the cold air return operation in which the temperature-reduced feedback coolant in the refrigerating chamber 10 is transferred to the cooler 60 through the cold air return duct 40 is properly performed. In the opening and closing operation of the refrigerating compartment door 14, when the opened refrigerating compartment door 14 is quickly closed, the recess is formed to be concave and curved inwardly of the idea plate 30 provided on the refrigerating compartment door 14 side. The internal pressure of the refrigerating compartment 10 is introduced into the freezing compartment 20 through the return cooling air suction port 50 formed by convexly curved upper one side of the refrigerating compartment inner wall 100 at regular intervals, thereby temporarily pushing the freezing compartment door 24. There is a problem.

The present invention was devised to solve the structural problems of the conventional return air inlet, and when the closed air inlet is formed in a stepped form of the upper and lower light, the pressure of the return air in the refrigerating compartment is concentrated in the freezer compartment when the open door is closed. It is an object of the present invention to provide a return air intake port of the refrigerating compartment cold air return duct that prevents the freezing chamber door from being opened.

As a technical means for realizing the above object, the present invention provides a return air inlet of the refrigerating compartment cold air return duct connected to the cold air return duct through the inner side of the refrigerating compartment, wherein the return air is introduced into the upper inner phase of the refrigerating compartment. The lower end portion is formed wide, the upper end portion is connected to the cold return duct is formed narrow, characterized in that consisting of a plurality of stepped step between the upper end and the lower end.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings as follows, the same configuration as the prior art will be described by specifying the same reference numerals.

Figure 3 is a side cross-sectional view showing the structure of the return air intake of the refrigerating compartment according to the present invention, Figure 4 is a plan view of the main portion B direction of Figure 3 showing the structure of the return air intake, the end of the cold return duct of the present invention.

As shown in the drawing, the feedback cooling air inlet 90 according to the present invention is formed between the lower end portion of the implantation plate 30 and the refrigeration chamber wall 100 as upper and lower light beams.

When describing the return cooling air inlet 90 in detail, the lower end portion 92 of the side in which the return cooling air of the refrigerating chamber 10, which is elevated in temperature, is wide, and the upper end 94 connected to the cold return duct 40 is narrow. The stepped step portion 96 is made of.

The stepped step 96 may be formed in two or more steps.

With the structure as described above, the return air suction inlet 90, which is the lower end portion of the refrigeration type 10 side of the cold air return duct 40, formed between the inner box 12 of the refrigerating compartment and the implantation plate 30, has a refrigerating cycle ( 10) As the cold air is introduced through the cold air discharge port (not shown) of the cold air duct to maintain the cold air temperature of the refrigerating compartment 10 for a predetermined time, and the temperature is increased, the return air inlet formed at the upper side of the refrigerating compartment 10 ( 90 is collected and sent to the cooler 60 through the cold air return duct 40, which is a connection flow path of the return air intake port 90.

At this time, the return cooler 80 that is transmitted to the cooler 60 through the cold return duct 40 has a lower side and a narrower upper return structure. The cold air circulation is sent to the cooler 60 through the cold air return duct 40 through the 90 and the temperature is lowered by the freezing cycle, and the cold air is discharged and distributed to the cold room 10 through the cold air outlet of the cold room 10. The operation will repeat continuously.

In addition, when the refrigerating chamber door 14 is closed, the refrigerating chamber door 14 is quickly closed and the pressure inside the refrigerating compartment 10 is momentarily increased, so that the return cooling air whose pressure rises through the refrigerating air inlet 90 is returned to the cold air. The upward air pressure may be transmitted by being pumped into the freezing chamber 20 through the duct 40, but by the return cooling air suction port 90 of the present invention, which is formed by the phase narrowing step 96 of the upper and lower beams. The phenomenon of concentration of the elevated pressure return air in the refrigerating compartment 10 is structurally weakened, and thus an instantaneous pressure rise when the refrigerating compartment door 14 is closed immediately flows into the return air inlet 90 to freeze the compartment 20. It is delivered to the) to avoid the phenomenon that the freezing chamber door 24 is opened.

As described above, the present invention provides a damper function by forming a step at the lower end of the return cooling air inlet 90 with upper and lower beams, thereby providing a damper function, so that the return cooling air inside the freezer compartment through the return cooling air inlet of the cold return duct during the closing operation of the refrigerating chamber door. Since the phenomenon of concentration can be avoided, the effect of preventing the freezing door from being opened can be obtained.

Claims (1)

In the return air inlet of the refrigerating chamber cold return duct connected to the cold air return duct 40 penetrating through the inner image 12 above the refrigerating compartment 10, the return coolant flows into the upper inner image 12 of the refrigerating compartment 10. The lower end 92 of the side is formed wide, and the upper end 94 connected to the cold air return duct 40 is narrowly formed, and a plurality of stepped portions 96 are formed between the upper end 94 and the lower end 92. Return cold air suction inlet of the cold room cold return duct, characterized in that made.