KR0109514Y1 - Tamper equipment of refrigerators - Google Patents

Abstract

The present invention relates to a damper device of a refrigerator. In the refrigerator, a damper pipe of the damper device is a pipe without a bend, and is installed in parallel with a flow path where cold air flows. The present invention relates to controlling a refrigerator to maintain a temperature in a refrigerator at a predetermined temperature. The present invention relates to a refrigerator damper device which reduces flow resistance and flow loss of cold air due to bending of a damper device.

Description

Damper device of refrigerator

1 is a schematic cross-sectional view of a refrigerator provided with an example of a conventional damper device.

Figure 2 (a) (b) is an illustration of the operation of the conventional damper device of FIG.

3 is a schematic cross-sectional view of a refrigerator in which one example of a damper device of the present invention is installed.

Figure 4 (a) is a partial cutaway view of the damper device of Figure 3;

(b) (c) is an operation example showing the opening and closing of the damper tube of (a).

Figure 5 (a) (b) is an illustration of the operation of the main part of the damper device showing another embodiment of the present invention.

6 is a flow resistance table comparing the flow resistance of the cold air of the present invention and the conventional one.

7 is a characteristic diagram of flow rate and voltage which shows the characteristics of the flow rate and voltage of the present invention and the conventional one.

* Explanation of symbols for main parts of the drawings

100: damper pipe 110: temperature sensor

120: STOP switch 130: motor

140: gear 150: control panel

The present invention provides a damper device for a refrigerator, and more particularly, a damper device for controlling the flow of cold air in a refrigerator, in parallel with a flow path through which cold air flows, to reduce the flow resistance and reduce flow loss and flow resistance. It is about.

A refrigerator is a device that keeps food in a fresh state without deterioration by maintaining a temperature in a refrigerator at a predetermined temperature by repeatedly performing a refrigeration cycle of compression, condensation, expansion, and evaporation of a refrigerant.

In such a refrigerator, a cooling chamber is provided to be isolated from a freezing chamber or a refrigerator compartment, and an evaporator is installed in this cooling chamber to blow cold air generated through the evaporation process of the freezing cycle into a flow path connected to the inside of the refrigerator by a fan operated by a motor. The flow path is provided with a damper device for controlling the flow of cold air to maintain the temperature in the refrigerator at a predetermined temperature.

The conventional damper device having such a function is composed of a damper tube and a damper,

First, the damper 20 is provided with a cold air control plate 21 (hereinafter, abbreviated as control plate) installed by the fixing pin 22 at one end of the S-shaped lever 23, the control lever 24 at the other end ) And a spring 26 for adjusting the initial tension by the adjustment plate 25 is installed, and the pivot 26, which is operated by a capillary tube (not shown) installed in the chamber, is installed at the end where the spring 26 is installed. ) Is installed (see Figure 2).

The conventional damper configured as described above is not provided in parallel with the flow channel due to its structure, and is configured to install the control plate 21 in the bent portion 10 of the damper pipe in which the flow path is bent (FIG. 1).

The damper device configured as described above controls the flow of cold air by opening and closing the damper pipe as shown in FIG.

When the temperature inside the refrigerator rises, the capillary tube installed inside the refrigerator expands and pushes the pivot 27 as shown in FIG. 2 (a), which pivots the initial tension of the spring 26 provided in the lever 23. By pushing the lever 23, the throttle plate 21 opens the damper pipe 10 to supply the cool air generated in the evaporator to the inside of the refrigerator.

When the internal temperature is lowered to a predetermined temperature, the capillary tube contracts and pulls back the spring 26 and the pivot 27 as shown in FIG. 2 (b), and the control plate 21 blocks the damper tube 10 in the opposite manner. To shut off the supply of cold air.

The damper device operated as described above has a problem that about 30% occurs when the total flow resistance is set to 100% because the flow resistance of the cold air becomes very large due to the bending of the damper tube.

In addition, due to the large flow resistance as described above, the flow rate flowing into the refrigerating chamber is reduced. Accordingly, when the cold air flows, the load on the fan motor is relatively large, and the capacity of the cold air flow path and the fan motor must be increased. There was also a problem in terms of efficiency.

An object of the present invention is to solve the problems of the conventional damper device as described above, to provide a damper device for minimizing the flow resistance.

The secondary purpose of the present invention is to increase the heat flow in the evaporator by increasing the flow rate of the cold air by reducing the flow resistance, and to reduce the power consumption of the fan motor and increase the cooling speed efficiency in the high.

The object of the present invention is achieved by a damper device consisting of a damper tube without bending and a damper for opening and closing it.

In order to achieve the above object, the present invention provides a non-bending damper pipe installed in parallel with a flow path, a control panel for opening and closing the damper pipe, a motor for operating the control panel, and a rotational speed of the motor at an appropriate rotational speed. It is composed of a damper consisting of a plurality of gears to decelerate and transmit to the control panel, the temperature sensor for controlling the motor and a stop switch, characterized in that to reduce the flow resistance generated by the cold air passing through the damper device.

Hereinafter, the damper device of the present invention will be described in detail with reference to the accompanying drawings compared with a conventional damper device.

FIG. 1 is a schematic cross-sectional view of an example of a conventional damper device installed in a refrigerator, and FIG. 2 (a) (b) illustrates an operation of the conventional damper device of FIG.

The damper device is composed of a damper tube (10) forming a bent tube perpendicular to the flow path, and a damper (20) provided in the damper tube (10), the damper (20) is an S-shaped lever ( 23, a cold air control plate 21 provided at the end of the lever 23 by the fixing pin 22, a spring 26 provided at the other end, and a capillary tube installed in the chamber, thereby interlocking the lever 23. It is composed of a pivot 26, which is controlled by the adjustment lever 24 and the adjustment plate 25 for adjusting the initial tension of the spring 26, the pivot 26 is a lever (according to the temperature in the refrigerator). 23) by pushing or pulling to open and close the damper pipe 10, the problem of the flow resistance generated in the conventional damper device has been described above.

3 is a schematic cross-sectional view of a refrigerator in which an example of a damper device of the present invention is installed, and FIG. 4 (a) is a partial cutaway view of only a damper device.

Damper pipe 100 is a pipe without bending to form a sliding groove in a proper position is installed in parallel with the flow path.

The damper is installed in the sliding groove control panel 150 for opening and closing the damper pipe, the motor 130 for driving the control panel 150, and a plurality of speed to reduce the rotational speed of the motor to the control panel 150 A gear 140, a temperature switch (not shown) and a stop switch 120 for turning the motor 130 on and off (ON / OFF) are configured.

The control panel 150 is in the shape of a fan, but the control panel 150 may be any shape that can open and close the damper pipe, and thus may have various shapes, and is not limited to the fan shape. 120 also controls the motor by detecting the rotation of the control panel, there may be various modifications such as a limit (LIMIT) switch.

The damper device configured as described above opens and closes the damper pipe as shown in FIG. 4 (b) (c).

When the temperature in the refrigerator rises above the set value, the temperature sensor detects this and rotates the motor 130.

Then, as shown in (b), the rotation of the motor 130 rotates the opening of the control panel 150 toward the damper tube 100 through the plurality of gears 140 to open the damper tube, and the control panel 150 is the damper tube 100. When fully opened, press the stop switch 120 installed at an appropriate position in the damper tube to turn off the power of the motor 130 and stop the rotation.

When the damper pipe 100 is opened as described above, cold air generated by the evaporator is introduced into the refrigerator by the fan and lowered below a predetermined temperature.

As described above, when the temperature in the refrigerator drops below a predetermined temperature, the temperature sensor operates the motor 130 to turn the closing portion of the control panel 150 toward the damper tube 100. When the control panel closes the damper tube, the stop switch Stop the motor from rotating.

5 is a view showing another embodiment of the present invention, wherein a refrigerator damper device is installed in a refrigerator and is operated by contraction and expansion of the capillary 210 and the capillary tube 210 contracted and expanded by the temperature in the refrigerator. The control panel 230 is installed in the 220 and the damper tube 100 and connected to the piston 220 to rotate horizontally and vertically to open and close the damper tube.

Various modifications are possible in addition to the above embodiment, and all the control of the flow of cold air by opening and closing the damper pipe installed in parallel with the flow path without any bending is within the scope of the damper device of the present invention.

6 is a table comparing the flow resistance of cold air with the present invention and the conventional one, and when the flow resistance generated by the conventional damper is set to 100% as shown in the flow resistance table, the flow path connected to the damper pipe in the present invention At 20% and 5% resistance reductions, the flow resistance can be reduced by as much as 25%.

In addition, comparing the present invention and the conventional flow resistance in the graph of FIG. 6 showing the characteristics of the flow rate and the voltage, it can be seen that the voltage applied to the motor for rotating the fan can supply at least a larger flow rate than the conventional one.

The present invention as described above can occupy a smaller installation space than the existing damper device and can lower the flow resistance of the damper device, thereby supplying a large amount of cold air in the refrigerator, thereby improving cooling efficiency and cooling speed efficiency, and also cooling air. The load of the moving fan motor is less, so there is less noise, and there is also an economic effect to reduce the power consumption.

Claims (4)

A damper device for a refrigerator, comprising: a damper pipe (100) formed in a straight pipe without parallel with a flow path of the refrigerator, and a damper for opening and closing the damper pipe (100). According to claim 1, wherein the damper control panel 150 for opening and closing the damper tube 100, the motor 130 for driving the control panel through the reduction gear 140, and senses the temperature inside the motor ( And a stop switch (120) for turning off the power of the motor (130) according to the rotation of the control panel. 2. The damper tube according to claim 1, wherein the damper is installed in the chamber, and the capillary tube 210 contracts and expands due to the temperature in the chamber, the piston 220 actuated by the contraction and expansion of the capillary tube 210, and the damper tube. Damper device of the refrigerator, characterized in that the control panel 230 is installed and connected to the piston to open and close the damper pipe. The refrigerator damper device according to claim 2, wherein the control panel (150) is fan-shaped.