KR100578347B1 - damper device for refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator damper device that can sufficiently prevent freezing due to the dewing phenomenon caused by the temperature difference around the refrigerator damper.

A damper device for a refrigerator according to the present invention includes: a damper body (12) installed on a supply path of cold air and having a cold air passage hole (12a); It is composed of a baffle (30) for opening and closing the cold air passing hole (12a); The baffle 30 is provided with a rotational center spaced apart so that the cold air discharged through the cold air passing hole 12a passes through the rear surface 31r of the baffle 30 when the cold air passing hole 12a is opened. It is done. According to the above configuration, there is an advantage in that water droplets on the rear surface of the refrigerator baffle can be evaporated and diffused into a high speed cold discharged when the cold air passing hole is opened by the baffle.

Refrigerator, Damper Device

Description

Damper device for refrigerator             

1 is an exploded perspective view showing a conventional damper device for a refrigerator.

Figure 2 is a schematic side cross-sectional view showing a conventional damper device for a refrigerator.

3 is an explanatory view showing cold air flow when a cold air passage is opened by a baffle of a conventional refrigerator damper device;

Figure 4 is an exploded perspective view showing the configuration of a preferred embodiment of a damper device for a refrigerator according to the present invention.

Figure 5a is a schematic side cross-sectional view of a damper device for a refrigerator according to the present invention.

FIG. 5B is a detail view of the “a” portion of FIG. 5A; FIG.

6 is an explanatory view showing the cold air flow when the cold air passage is opened by the baffle of the damper device for a refrigerator according to the present invention.

Brief description of the main parts of the drawing

10 damper device 12 damper body

12a: Cold air passage 12b: Hinge groove

20: stepping motor 24: fan gear

26: drive gear 30: baffle

31r: rear 32a: hinge pin

34: link 34a: link connection

The present invention relates to a damper device for a refrigerator, and more particularly, to a damper device for a refrigerator capable of sufficiently preventing freezing due to the dewing phenomenon caused by the temperature difference around the refrigerator damper.

The refrigerator maintains a predetermined freezing and refrigerating state by supplying cold air generated near the evaporator to the refrigerating chamber and the freezing chamber. When the internal temperature of the freezer compartment and the refrigerating compartment rises above the set temperature, cold air is supplied, and when it falls below the set temperature, the supply of cold air is stopped. The interruption of the cold air is performed by the damper device, for example, whether cold air is supplied to the refrigerating chamber.

Hereinafter, a conventional refrigerator damper device will be described in detail with reference to FIGS. 1 and 2.

As shown, the damper device 10, the damper body 12 having a cold air passage hole 12a through which cold air can pass, and opens and closes the cold air passage hole 12a of the damper body 12. The baffle 30 is included. In addition, a stepping motor 20 is provided at one side of the damper body 12 as a driving source for opening and closing the cold air passage 12a by rotating the baffle 30. The drive gear 26 coupled to the drive shaft 20a of the stepping motor 20 transmits the rotational power of the stepping motor 20 to the fan gear 24. The rotary shaft 24a of the fan gear 24 is fitted to the rotary shaft P of the baffle 30 so that the baffle 30 is rotated by the rotation of the fan gear 24. When the baffle 30 rotates, the cold air passage 12a is opened by the baffle 30 as shown by the dashed-dotted line in FIG. 2. In FIG. 2, a driving device such as a stepping motor 20 that rotates the baffle 30 to show the rotation of the baffle 30 of the conventional damper device 10 is not shown.

However, the conventional refrigerator damper device 10 configured as described above has the following problems. In the state in which the cold air passage 12a is closed by the baffle 30, the temperature of the left part A and the right part B of the baffle 30 is different. That is, since the left portion A is a path through which the generated cold air is supplied, it is maintained at a relatively low temperature state compared to the right portion B. In addition, the right portion B of the baffle 30, which is a passage connected to the refrigerating chamber, is relatively hot due to the temperature of the refrigerating chamber and is humid due to the food stored in the refrigerating chamber.

Therefore, due to the temperature difference, due to temperature difference, one side of the baffle 30 (that is, the surface corresponding to the refrigerating chamber passage) is caused. As such, when water droplets form on the rear surface 31r of the baffle 30 due to the temperature difference, such water accumulates around the baffle 30, and such water may freeze into frost due to the influence of the supplied cold air. do.

3 is an explanatory view showing cold air flow in a state where the cold air passage 12a is opened by the baffle 30 of the conventional refrigerator damper device. As shown in FIG. 3, the inlet side of the damper, that is, the cold air passing hole 12a (see FIG. 2), the front side B of the damper flows high-speed cold air of about 2 m / s, but the rear surface 31r of the baffle 30. The upper side C is stagnant without the flow of air. Accordingly, water droplets or frost formed on the rear surface 31r of the baffle 30 when the cold air passage 12a is closed are evaporated and sublimed by the wind even when the cold air passage 12a is opened by the baffle 30. There will be no, so it will continue to increase.

In this way, if freezing occurs around the baffle 30, the periphery including the rotating shaft P for rotating the baffle 30 freezes, making it difficult to open the baffle 30, thereby reducing the problem of cold air supply. Will result. Such a problem has an important effect on whether or not the cold air is supplied to the refrigerating chamber, which also causes a problem of reliability of the refrigerator.

The present invention has been made to solve the above problems, an object of the present invention is to provide a refrigerator damper device that can sufficiently prevent freezing due to the dewing phenomenon caused by the temperature difference around the refrigerator damper.

According to a feature of the present invention for achieving the above object, the present invention is a damper body is provided on the supply path of the cold air and having a cold air passage; A baffle for opening and closing the cold air passing hole; And a link connected to the baffle at a predetermined angle and rotatably supported on both sides of a damper body; When opening the cold air passing hole, the center of rotation of the baffle is provided at one end of the link so that the cold air discharged through the cold air passing hole by the link rubs the rear surface of the baffle. .

According to the above configuration, when opening the cold air passage by the baffle, there is an advantage that can prevent the freezing of the baffle by evaporating the water droplets on the back of the baffle by using the cold air discharged through the cold air passage.

According to a specific embodiment of the present invention, the damper device for a refrigerator according to the present invention is characterized in that the link is used so that the center of rotation of the baffle is at a position spaced apart from the baffle itself.

According to the above configuration, the high speed cold air discharged at the time of opening the cold air passing hole by passing the center of rotation of the baffle and the baffle by a simple structure has the advantage that can touch the rear surface of the baffle.

The link is considered in consideration of the connection angle between the link and the baffle such that the cold air discharged through the cold air passing hole directly touches the rear surface of the baffle and does not reduce the amount of cold air discharged into the refrigerating compartment. The angle of rotation should be adjusted.

According to the above configuration, while maximizing the anti-icing effect of the baffle by adjusting the rotation angle of the link, there is an advantage that can reduce the amount of cold air discharged to the refrigerating chamber.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment according to the present invention will be described in detail. The same parts as the conventional components will be described using the same reference numerals.

4 is an exploded perspective view showing the configuration of a preferred embodiment of a damper device for a refrigerator according to the present invention. As shown, the refrigerator damper device 10 of the embodiment of the present invention, the baffle 30 for opening and closing the cold air passage 12a of the damper body 12 is provided with a center of rotation spaced apart from itself by a certain distance When the baffle 30 opens the cold air passage 12a, it is a technical subject matter that the cold air discharged through the cold air passage 12a passes through the rear surface 31r of the baffle 30.

To this end, the baffle 30 according to the present invention includes a link 34 at left and right sides of an upper end portion of the rear surface 31r of the baffle 30. The link 34 protrudes forward from the left and right sides of the rear surface 31r of the baffle 30. And, one side of the link 34 is provided with a hinge pin (32a) is inserted into the hinge groove (12b) formed on the left and right sides of the damper body (12).

As shown in FIG. 4, the hinge pin 32a is rotated when the baffle 30 is rotated by the driving force of the stepping motor 20 transmitted through the driving gear 26 and the fan gear 24. It becomes the center. Since the hinge pin 32a is connected by the baffle 30 and the link 34 as described above, when the baffle 30 is rotated, the center of rotation of the baffle 30 is the baffle 30. It is not located on the phase.

Hereinafter, with reference to the accompanying drawings, the operational relationship of the damper device for a refrigerator according to the present invention will be described.

Referring to FIG. 4, when the stepping motor 20 (see FIG. 4) is driven, the driving force of the stepping motor 20 is sequentially driven to the drive gear 26 and the fan-shaped gear 24 through the drive shaft 20a. Delivered as soon as possible. As a result, the hinge pin 32a coupled to the fan gear 24 rotates counterclockwise. The baffle 30 connected by the hinge pin 32a and the link 34 by the rotation of the hinge pin 32a is also rotated counterclockwise as shown by a dashed line in FIG. 12a) is opened.

5A is a schematic side view of a damper device 10 for a refrigerator according to the present invention. In the drawings, a driving device such as a stepping motor 20 for rotating the baffle 30 to show the rotation of the baffle 30 of the damper device 10 according to the present invention is not shown. When the cold air passage 12a is opened, the connecting portion 34a of the link 34 connected to the baffle 30 is moved from the A position to the B position. Counterclockwise movement of the connecting portion 34a means that the position of the connecting portion 34a is moved from the top to the bottom. In this case, a gap (hereinafter referred to as an upper inlet) is formed between the left and right links 34 and the left and right hinge pins 32a and above the baffle 30. Therefore, the discharged cold air may be introduced into a gap (upper inlet) of the upper portion of the link 34 so as to pass through the rear surface 31r of the baffle. This positional relationship is shown in FIG. 5B.

  That is, when the baffle 30 opens the cold air passage 12a, a portion of the cold air of the portion A 'which is the side to which cold air is supplied based on FIG. 5A is directed to B' through the inlet of the cold air passage 12a of the damper. It flows, but part flows to C '. The high-speed (about 2 m / s) wind flowing to the C 'flows to the rear surface 31r of the baffle 30. When the baffle 30 is closed by the flow, water droplets attached to the rear surface 31r of the baffle 30 immediately evaporate and diffuse. Therefore, freezing can be prevented from occurring on the rear surface 31r of the baffle 30 as in the related art.

It should be noted that in the above structure, the size of the upper inlet for determining the air volume of the cold air to suppress the freezing of the rear surface 31r of the baffle 30 and the angle of rotation of the link 34 when the cold air passage 12a is opened. (C), as will be seen in FIG. 5B.

As shown, it can be seen that determining the air volume of the cold air flowing to the rear surface 31r of the baffle 30, the length (L) of the link 34. As the length L of the link 34 increases, the total cross-sectional area of the upper inlet also increases. However, due to this, as the rotation angle of the hinge pin 32a increases, the torque increases, and the length L of the link 34 is considered in consideration of the fact that the life of the motor is shortened, and limitations on the installation of the damper device. Should be adjusted to an appropriate level.

5A, the rotational angle C of the link 34 is a high speed cold air discharged through the upper inlet when the cold air passage 12a is opened by the baffle 30. The baffle 30 should be designed to sufficiently touch the rear surface 31r. That is, when the rotation angle C of the link 34 is excessively small, when the cold air passage 12a is opened, the baffle 30 has a parallel or negative angle with respect to the horizontal. do. In this case, since the cold air discharged through the upper inlet does not directly touch the rear surface 31r of the baffle 30, dew does not sufficiently evaporate from the dew formed on the rear surface 31r of the baffle 30.

On the contrary, if the rotation angle C of the link 34 is excessively large, when the cold air passing hole 12a is opened, the height H1 of FIG. 5B becomes small, so that the total cross-sectional area of the upper inlet becomes small. . In this case, the removal efficiency of water droplets and the like on the rear surface 31r of the baffle 30 is lowered. In addition, the rear surface 31r of the baffle 30 acts as a resistance of the cold air discharged, thereby reducing the amount of cold air discharged into the refrigerating compartment, thereby extending the cooling time of the refrigerating compartment.

As described above, the anti-freezing effect of the rear surface 31r of the baffle 30 according to the rotation angle C of the link 34 and the effect of reducing the amount of cold air discharge are connected to the connection angle of the link 34 and the baffle 30. It depends on (a). Accordingly, the rotation angle C of the link 34 may minimize the reduction of the amount of cold air discharged into the refrigerating chamber in consideration of the connection angle a of the link 34 and may be a rear surface of the baffle 30. It shall be designed to maximize the effect of anti-icing of 31r).

6 is an explanatory view showing the cold air flow when the cold air passage 12a is opened by the baffle 30 of the damper device for a refrigerator according to the embodiment of the present invention. As shown, when the cold air passage 12a is opened by the baffle 30, the upper side C 'of the rear surface 31r of the baffle 30 is the same as the bottom side B' of the baffle 30. It can be seen that high speed cold air is discharged.

The damper device according to the present invention as described above has the effect of preventing the freezing of the baffle by evaporating the water droplets on the back surface of the baffle with a high speed cold discharged through the cold air passing hole when the cold air passing hole is opened by the baffle. Can be planned.

In addition, another effect of the damper device according to the present invention is that it is not necessary to use a heater for preventing the damper freezing, it is possible to reduce the material cost.

Claims (1)

A damper body installed on a supply path of cold air and having a cold air passage hole; A baffle for opening and closing the cold air passing hole; And, A link connected to the baffle at a predetermined angle and rotatably supported on both sides of a damper body; When the cold air passing hole is opened, the center of rotation of the baffle is provided at one end of the link so that the cold air discharged through the cold air passing hole by the link rubs the rear surface of the baffle. Refrigerator damper device characterized in that.

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