KR100525489B1 - Defroster for Refrigerator - Google Patents

Abstract

The present invention relates to a defrosting apparatus of a refrigerator, and provides a defrosting apparatus of a refrigerator which senses the air volume of cold air discharged from an evaporator and drives the heater to defrost when the airflow quantity is smaller than a set value. Its purpose is to.

Such an object includes: air flow rate sensing means for sensing an air flow rate at a cold air discharge portion of an evaporator; Comparison means for comparing the detection signal for the air volume with a signal preset by the user and outputting a signal for the comparison result; A microcomputer which receives a comparison result signal output from the comparison means and outputs a driving control signal of the heater according to the comparison result signal; It is achieved by being composed of driving means for driving the defrost heater by receiving the driving control signal output from the microcomputer.

Description

Defroster for Refrigerator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a defrosting apparatus of a refrigerator, and more particularly, to a defrosting apparatus of a refrigerator which senses an air volume of cold air discharged into a refrigerator to perform defrosting.

As shown in FIG. 1, a general refrigerator includes a freezer compartment for storing food in an upper portion of the refrigerator body R, and a freezer compartment for storing food in the lower portion of the freezer compartment.

Compressor (C) is provided in the lower portion of the refrigerator (R) to compress the refrigerant flowing into the gas state to a high pressure to convert to a liquid state, and provides the converted liquid refrigerant to the evaporator (E).

The evaporator (E) vaporizes the high-pressure liquid refrigerant instantaneously to take away the heat of the surroundings to form cold cold air, and thus the cold air is discharged into the interior by the fan (P) installed at the rear of the evaporator (E) Freezing and refrigeration are performed along the cold air passage.

At this time, the cold air generated from the evaporator (E) is blown into the interior by the fan (P), but the moisture around the evaporator (E) is condensed and frozen in the evaporator (E) by cold heat as shown in FIG. Likewise, the sex (S) is sandwiched between the capillary and the capillary tube formed like a coil by the sex (S) is blocked, the cold air is not discharged smoothly into the shed.

Therefore, the heater coil is wound around the evaporator E to drive the heater every predetermined time to remove the defrost.

However, in such a case, there is a problem that the refrigeration and refrigeration efficiency is lowered by not only power waste but also heat generated during frequent defrosting by operating the heater unconditionally every time regardless of the amount of sexual love.

SUMMARY OF THE INVENTION In view of the above problems, an object of the present invention is to provide a defrosting apparatus of a refrigerator that senses the air volume of cold air discharged from an evaporator and drives the heater to defrost when the air volume is smaller than a set value.

In order to achieve the above object, the defrosting apparatus of the present invention comprises: air flow rate sensing means for sensing the air flow rate is located in the cold air discharge portion of the evaporator; Comparison means for comparing the detection signal for the air volume with a signal preset by the user and outputting a signal for the comparison result; A microcomputer which receives a comparison result signal output from the comparison means and outputs a driving control signal of the heater according to the comparison result signal; And a driving means for driving the defrost heater by receiving the driving control signal output from the microcomputer.

On the other hand, the air flow rate sensing means, the windshield to change the moving position according to the amount of cold air discharged through the evaporator; A lever that moves up and down according to the positional change of the windshield; And a push bar connected to the lever to connect or short-circuit the contact portion.

The windshield preferably has a suitable volume so as to best detect the amount of air discharged, and the shape may be formed in various forms such as cup or cardboard.

The present invention configured as described above will be described in detail with reference to the accompanying drawings.

First, the air flow rate detection unit 100 is installed on the front portion or the cold air flow path of the evaporator (E) to detect the air flow rate of the cold air discharged through the evaporator (E), an embodiment of the air flow rate detection unit 100 3 is shown.

When cold air is discharged through the evaporator E, its position is changed back and forth in accordance with the amount of cool air discharged.

That is, if the air volume is large, the windshield 106 is flipped backward, otherwise, the inclination toward the rear will change according to the strength of the air volume.

Accordingly, the pressure rod 107 connected to the windshield 106 varies the degree of pressurization of the lever 108 according to the changed inclination, which causes the lever 108 to sequentially push the push bar 109. Pushed

Therefore, the push bar 109 presses the movable contact 110a in the direction of the fixed contact 110b so that the contact points 110a and 110b are in contact with each other and change according to a signal, i. The resistance value is output to the connection terminal 111.

At this time, the reaction sensitivity is determined by the movement control bar 103 and the elastic body 105 according to the wind pressure applied to the windshield 106, the movement control bar 103 is inserted into the upper end of the lever 108. And the upper and lower sides are elastically supported by the screw 104 and the elastic body 105.

Therefore, when the user turns the adjustment knob 101, the tilt of the movement control bar 103 is converted by the position control plate 102. That is, when the portion of the position adjusting plate 102 far from the central axis of the adjustment knob 101 pushes up the movement adjusting bar 103, the inclination of the movement adjusting bar 103 becomes almost horizontal and the lever ( 108 is not easily moved by the pressure bar 107.

This results in a slow response.

On the contrary, when the portion of the position adjusting plate 102 near the distance from the central axis of the adjusting knob 101 pushes up the movement adjusting bar 103, the inclination of the movement adjusting bar 103 becomes large and the lever 108 becomes larger. Is easily moved by the pressure bar 107.

This results in a sensitive sensitivity.

As a result, the user can adjust the defrosting time according to the amount of cold air discharged through the evaporator (E).

Therefore, when the detection signal for the air volume, that is, the resistance value according to the air volume is output from the air volume detecting unit 100, the comparator 200 receives the result and compares it with a preset reference resistance value ref to compare the result. If the reference resistance (ref) is greater than the resistance value output from the comparator 200, it is because the defrost is not generated or a little generated in the evaporator (E), there is no need to defrost Output a signal of '0'.

On the other hand, if the reference resistance value (ref) is smaller than the resistance value output from the comparator 200 This is a time to generate a lot of defrost in the evaporator (E) and outputs a signal of '1'.

In this case, the reference resistance value ref is stored in the memory 500 through the key input unit 400, and then read by the microcomputer 300 and provided to the comparison unit 200.

Therefore, when the comparison result signal of '1' is output from the comparator 200, the microcomputer 300 outputs a drive control signal to the driver 600. Accordingly, the driver 600 is a defrost heater ( The defrost is performed by driving 700 to heat and melt the frost formed in the evaporator (E).

4 is a view showing another embodiment of the air flow rate detection unit 100 of the present invention, the rotating body 120 to rotate in accordance with the discharged air volume; At least one rotational speed detection mark 122 provided on a side of the rotating body of the rotating body; It is characterized in that it comprises a rotation speed sensor 123 for detecting the number of rotations of the rotation speed detection mark 122 and outputs the detection signal.

This will be described in detail with reference to FIG. 4.

First, the air flow rate sensing unit 100 according to another embodiment of the present invention is installed on the front portion or the cold air flow path of the evaporator (E) to rotate the rotating body 120 according to the air volume of the cold air discharged through the evaporator (E) The number will be different.

That is, the amount of wind (wind pressure) is applied to the plurality of wind holders 121 located on the circumferential surface of the rotating body 120, so that the rotational speed of the rotating body 120 varies according to the amount of wind.

At this time, since the rotation speed detection mark 122 provided at one or more sides thereof rotates in the same manner as the rotation body 120 rotates, the rotation speed detection sensor 123 detects the rotation speed detection mark 122. According to the condition, a signal that detects the air volume is output.

The rotation speed detection sensor 123 may be a light receiving and emitting element, and if there is light reflected from the rotation speed detection mark 122, the rotation speed detection sensor 123 outputs a pulse amount of air volume detection signal.

Therefore, the air volume detection signal in the form of a pulse is applied to the comparator 200, and the comparator 200 compares the reference pulse ref provided from the microcomputer 300 and outputs a result of the comparison. , If the pulse generation period of the air volume detection signal is shorter than the reference pulse (ref), since the defrost is not formed in the evaporator (E) it outputs a signal of '0'.

On the other hand, if the pulse generation period of the air volume detection signal is longer than the reference pulse (ref), since the defrost is formed in the evaporator (E), the signal of '1' is output so that the defrosting operation described above is performed.

While the embodiments of the present invention have been described so far, the present invention is not limited thereto, and various embodiments which can be modified and changed within the true spirit and scope of the claimed principles described in the specification are within the protection scope of the present invention. It should be understood that it belongs.

As described above, the present invention detects the amount of air discharged from the evaporator to determine the formation state of the frost, and the defrosting operation is performed according to the determination result to prevent unnecessary power consumption and to prevent heat generated during frequent defrosting. As a result, there is an effect of overcoming the problem of lowering the freezing and refrigerating efficiency.

1 is a view showing the structure of a typical refrigerator.

2 is a view showing a defrosting apparatus of a refrigerator according to the present invention.

3 is a view showing an embodiment of the airflow sensor of FIG.

FIG. 4 is a view showing another embodiment of the airflow sensor of FIG. 2.

5 is a view showing a state in which defrost on the evaporator.

<Description of reference numerals for main parts of the drawings>

100: air flow detector 106: wind support

107: pressure bar 108: lever

109: push bar 110a: movable contact

110b: fixed contact 200: comparison unit

300: microcomputer 400: key input unit

500: memory 600: driver

700: heater

Claims (3)

delete delete Air flow rate sensing means for sensing the air flow rate at a cold air discharge portion of the evaporator; Comparison means for comparing the detection signal for the air volume with a signal preset by the user and outputting a signal for the comparison result; A microcomputer which receives a comparison result signal output from the comparison means and outputs a driving control signal of the heater according to the comparison result signal; In the defrosting apparatus of the refrigerator comprising drive means for driving a defrost heater by receiving a drive control signal output from the microcomputer, The air flow rate detection means, A rotating body rotating according to the amount of air discharged; A rotational speed detection mark provided on at least one side of the rotating body; And a rotation speed detection sensor configured to detect the number of rotations of the rotation speed detection mark and output the detection signal.