KR20090043825A - Refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator, comprising: a main body cabinet forming a first storage chamber and a second storage chamber, and a refrigerator having an evaporator generating cold air supplied to the first and second storage chambers, wherein the cold air generated in the evaporator A duct member having a first cold air discharge port discharged to the first storage chamber; A refrigeration position for opening the first cold air outlet above a predetermined opening degree so that the first storage compartment is used as a freezing compartment, and refrigerating opening the first cold air outlet outlet below the opening degree so that the first storage compartment is used as a refrigerating compartment; A discharge structure section moving between positions; A sensing unit sensing a position of the discharge structure cutting unit; A temperature controller for adjusting a set temperature of the first storage chamber; And a controller configured to set the set temperature of the first storage chamber to a set refrigeration reference temperature regardless of the set temperature of the temperature control unit when the refrigerating position of the discharge structure cutting unit is sensed by the sensing unit. Thereby, the malfunction of the freezer compartment and the refrigerating compartment switching function can be essentially blocked.

Refrigerator, freezer, changeover, set temperature

Description

Refrigerator {Refrigerator}

The present invention relates to a refrigerator, and more particularly, to a refrigerator capable of fundamentally blocking a malfunction of a freezer compartment and a refrigerator compartment switching function.

In general, a top-mounted refrigerator includes a main cabinet which forms a freezer compartment in the upper part and a refrigerating compartment in the lower part, an evaporator disposed in the rear region of the freezer compartment to generate cold air, and blows cold air generated in the evaporator to the freezer compartment and the refrigerator compartment. And a freezing chamber duct and a refrigerating chamber duct having a blowing fan, and a cold air passage communicating with each other to guide the cold air blown by the blowing fan to the freezing compartment and the refrigerating compartment.

1 is a view showing a conventional top mount freezing chamber duct 140. The freezing chamber duct 140 is provided with a cold air discharge port 147 through which cold air generated in the evaporator is discharged into the freezing chamber. The cold air discharge port 147 is equipped with a damper unit 151 for controlling the amount of cold air discharged to the cold air discharge port 147 by adjusting the opening degree of the cold air discharge port 147 and the amount of cold air moving to the refrigerating chamber duct. In addition, the freezer compartment duct 140 is provided with a damper control unit 153 for operating the damper unit 151.

On the other hand, the freezing chamber duct 140 is equipped with a temperature control unit 170 for adjusting the set temperature of the freezer compartment. The temperature control unit 170 is provided to adjust the freezing temperature step by step. Here, the temperature control unit 170 is provided to set the set temperature to "refrigerated" to switch the freezer compartment to the refrigerating compartment.

In order to switch the freezer compartment to the refrigerating compartment in the conventional refrigerator, turn the temperature control unit 170 to set the set temperature to "refrigerated", and then operate the damper control unit 153 to move the damper unit 151 to discharge the cold air outlet ( The amount of cold air discharged to the cold air outlet 147 should be reduced by reducing the opening degree of the 147. On the contrary, in order to switch to the freezer compartment, turn the temperature control unit 170 to set the set temperature to "frozen", and then operate the damper operation unit 153 to move the damper unit 151 to open the cold air outlet 147. To increase the amount of cold air discharged to the cold air discharge port 147 to be increased. That is, when switching the freezer compartment to the refrigerating compartment or to the freezer compartment again, the user must operate both the temperature control unit 170 and the damper operation unit 157.

However, when the user operates only the temperature control unit 170 without refrigerating the damper control unit 157 in order to switch the freezer compartment to the refrigerating compartment, a large amount of cold air flows into the freezer compartment so that the cold compartment is relatively low. Inflow of the refrigerating compartment is changed to weak cooling may cause a problem that the storage stored in the refrigerating compartment is damaged.

On the contrary, in order to switch the freezer compartment to the refrigerating compartment, and then operate the temperature control unit 170 to freeze in order to switch back to the freezer compartment, if the damper control unit 153 is not operated, less cold air flows into the freezer compartment and the freezer compartment temperature is lowered. It is weakly cooled and the refrigerator may have a lot of cold air, which may cause freezing of the storage.

An object of the present invention is to provide a refrigerator which can fundamentally block malfunctions of the freezer compartment and the refrigerating compartment switching function.

The object of the present invention is a refrigerator having a main body cabinet for forming a first storage chamber and a second storage chamber, and an evaporator for generating cold air supplied to the first and second storage chambers, wherein the cold air generated in the evaporator is provided. A duct member having a first cold air discharge port discharged to the first storage chamber; A refrigeration position for opening the first cold air outlet above a predetermined opening degree so that the first storage compartment is used as a freezing compartment, and refrigerating opening the first cold air outlet outlet below the opening degree so that the first storage compartment is used as a refrigerator compartment A discharge structure section moving between positions; A sensing unit sensing a position of the discharge structure cutting unit; A temperature controller for adjusting a set temperature of the first storage chamber; When the sensing unit detects the refrigeration position of the discharge structure cutting unit, it is achieved by including a control unit for setting the set temperature of the first storage chamber to the set refrigeration reference temperature irrespective of the set temperature of the temperature control unit.

The discharge structure cutting portion includes a damper portion coupled to the duct member to move between the freezing position and the refrigerating position, and a damper manipulation portion approaching and spaced apart from the temperature control portion and manipulating the movement of the damper portion; The sensing unit preferably detects the state of approach and separation of the damper control unit and the temperature control unit.

The sensing unit may be provided with any one of a magnetic and a reed switch, a photosensor, a proximity sensor, and a contact sensor.

The controller may set the set temperature of the first storage chamber based on the set temperature of the temperature control unit when the sensing unit detects the freezing position of the discharge structure cutting unit.

According to the present invention, it is possible to provide a refrigerator which can fundamentally block the malfunction of the freezer compartment and the refrigerating compartment switching function.

Hereinafter, a preferred embodiment of a refrigerator according to the present invention will be described in detail with reference to FIGS. 2 to 4B.

The refrigerator 1 according to the present invention includes the main cabinet 10 forming the first storage chamber 10a and the second storage chamber 10b, and the cold air supplied to the first storage chamber 10a and the second storage chamber 10b. A duct member 40 having a generated evaporator 20, a first cold air outlet 47a through which cold air generated by the evaporator 20 is discharged to the first storage chamber 10a, a freezing position A, and a refrigerated position. (B) the discharge structure cutting section 50 moving between the sensing unit 60, the sensing unit 60 for detecting the position of the discharge structure cutting section 50, and the temperature control unit 70 for adjusting the set temperature of the first storage chamber (10a). ), And when the refrigerating position (B) of the discharge structure section 50 is detected by the sensing unit (60), the set reference temperature of the first storage chamber (10a) is set regardless of the set temperature of the temperature control unit (70). It includes a control unit (not shown) to set to.

In the present embodiment, the main cabinet 10 is the main cabinet 10 of the top mount type refrigerator, in which the first storage chamber 10a and the second storage chamber 10b are partitioned up and down.

The first storage compartment 10a is formed in the upper region of the main cabinet 10 and is generally used as a freezing compartment. The second storage compartment 10b is formed in the lower region of the main cabinet 10 and is generally used as a refrigerating compartment.

The evaporator 20 is disposed in the rear region of the first storage chamber 10a to generate cold air supplied to the first storage chamber 10a and the second storage chamber 10b. In the upper region or the front region of the evaporator 20, a blower fan 30 that blows cold air generated by the evaporator 20 to the first storage chamber 10a and the second storage chamber 10b is disposed. The blowing fan 30 is attached to the duct member 40.

The duct member 40 is disposed in the rear region of the first storage chamber 10a and has a first duct 41a formed therein to guide the cold air blown by the blower fan 30 to the first storage chamber 10a. A second cool air passage 41b disposed in the portion 40a and in the rear region of the second storage chamber 10b to guide the cold air passing through the first cold air passage 41a to the second storage chamber 10b. The duct part 40b is included. Here, the first cold air passage 41a and the second cold air passage 41b communicate with each other.

The first duct portion 40a includes a first duct body 45a having a first cold air flow passage 41a and a first duct cover 49a covering a front region of the first duct body 45a.

At the end of the first cold air passage 41a, a first cold air discharge port 47a for discharging cold air into the first storage chamber 10a is formed in the first duct body 45a. In addition, the first duct body 45a has a discharge structure section 50 for adjusting the opening degree of the first cold air discharge port 47a, a sensing unit 60 for sensing the position of the discharge structure section 50, and 1 is equipped with a temperature control unit 70 for adjusting the set temperature of the storage chamber (10a).

The first duct cover 49a covers the front region of the first duct body 45a. The first duct cover 49a has an opening so that the damper control unit 53 and the temperature control unit 70, which will be described later, are exposed to the first storage chamber 10a, and has an opening in communication with the first cold air discharge port 47a.

The second duct portion 40b is formed with a second cold air passage 41b in communication with the first cold air passage 41a, and cool air flowing through the second cold air passage 41b is discharged to the second storage chamber 10b. A second cold air discharge port 47b is formed.

Here, the flow of cold air is briefly described. First, the cold air generated by the evaporator 20 is blown by the blowing fan 30. Some of the blown cold air flows along the first cold air passage 41a and is discharged to the first cold air discharge port 47a. The remaining cool air flows through the first cold air passage 41a and flows along the second cold air passage 41b and is discharged to the second cold air outlet 47b. Here, the amount of cold air supplied to the first storage chamber 10a varies depending on the position of the discharge structure cutout 50.

The discharge structure section 50 includes a freezing position A for opening the first cold air discharging opening 47a above a predetermined opening degree so that the first storage chamber 10a is used as a freezing chamber, and the first storage chamber 10a is connected to the refrigerating chamber. It moves between the refrigeration position B which opens the 1st cold air | gas outlet 47a to less than the said opening degree so that it may be used. Discharge structure section 50 is coupled to the duct member 40, the damper portion 51 to move between the freezing position (A) and the refrigerating position (B) and the temperature control unit 70 approaches and spaced apart from the damper portion The damper control part 53 which operates the movement of 51 is provided.

The damper part 51 is rotatably coupled to the first duct body 45a to adjust the opening degree of the first cold air outlet 47a. The damper portion 51 is provided in a plate shape having an area corresponding to the opening area of the first cold air discharge port 47a. In the present embodiment, a plurality of through holes 51a are formed in the plate surface of the damper part 51.

In the present embodiment, the freezing position A is a position where the damper part 51 rotates to open the first cold air outlet 47a at a predetermined opening or more to supply a large amount of cold air to the first storage chamber 10a. For example, the position where the damper part 51 rotates more than 30 degrees with respect to the plate surface of the 1st duct main body 45a, and opens the 1st cold air | gas outlet 47a is a freezing position. Here, the rotation angle of the damper unit 51 can be changed depending on the setting.

The refrigeration position B is a position where the damper part 51 rotates below 30 degrees with respect to the plate surface of the 1st duct main body 45a, and opens the 1st cold air | gas outlet 47a. In the present embodiment, the refrigeration position (B) is a relatively small amount of cold air compared to the freezing position (A) in the first storage chamber (10a) by closing the first cold air discharge port (47a) by rotating the damper portion (51). It is a position to supply. In the refrigerating position (B), the cool air is discharged to the first storage chamber (10a) through the through hole (51a) formed in the damper portion (51).

In the present exemplary embodiment, the damper unit 51 rotates with respect to the first duct body 45a and adjusts the opening degree of the first cold air outlet 47a. However, the damper unit 51 is not limited thereto. The first duct body 45a may be slid left or right or up and down to adjust the opening degree of the first cold air outlet 47a.

The damper operation part 53 is provided so that the rotation angle of the damper part 51 may be operated. The damper manipulator 53 is coupled to the other end of the connecting portion 55, one end of which is connected to one side of the damper portion 51, the temperature control portion 70 is approached and spaced apart from the damper portion 51 And an operation knob 57 for operating the rotation of the " In this embodiment, the operation knob 57 is moved in the vertical direction to approach and space the temperature control unit 70.

The detector 60 detects the position of the damper manipulator 53. That is, the sensing unit 60 detects the approaching and separating state of the operation knob 57 and the temperature control unit 70. In this embodiment, the damper portion 51 moves to the refrigerating position B when the operation knob 57 moves downward, and the damper portion 51 moves to the refrigerating position B when the operating knob 57 moves downward. In the refrigerating position B of the damper unit 51, the operation knob 57 is spaced apart from the temperature control unit 70, and in the freezing position A of the damper unit 51, the operating knob 57 is a temperature control unit ( 70).

The sensing unit 60 may be provided in various ways. The sensing unit 60 may be provided as any one of a magnetic 60a, a reed switch 60b, a photosensor, a proximity sensor, and a contact sensor. In the present embodiment, the sensing unit 60 is provided with a magnetic 60a and a reed switch 60b. That is, the magnetic 60a is mounted to the operation knob 57 and the reed switch 60b is mounted to the temperature control part 70. Here, in the refrigerating position B of the damper portion 51, the magnetic 60a is spaced apart from the reed switch 60b so that the reed switch 60b does not operate, and in the freezing position A of the damper portion 51, The magnetic 60a approaches the reed switch 60b so that the reed switch 60b operates. The operation signal of the reed switch 60b is transmitted to the controller.

On the other hand, the reed switch 60b may be provided at any position approaching and spaced apart according to the movement of the operation knob 57. For example, the reed switch 60b may be mounted on the plate surface of the first duct body 45a to approach and be spaced apart from the magnetic 60a according to the movement of the operation knob 57.

In the present description, the magnetic 60a is mounted on the operation knob 57 and the reed switch 60b is mounted on the temperature controller 70. However, the magnetic 60a is mounted on the temperature controller 70. It goes without saying that the reed switch 60b may be mounted to the operation knob 57.

The temperature controller 70 is provided to adjust the set temperature of the first storage chamber 10a. The temperature control unit 70 may select any one of four levels of freezing strength of "special freezing"-"strong freezing"-"medium freezing"-"weak freezing" as the set temperature of the first storage chamber 10a. . Here, the number of steps of the freezing strength is variable.

On the other hand, the temperature control unit 70 is provided to select the "refrigeration" to drive the first storage compartment (10a) to the refrigerator compartment.

When the sensing unit 60 detects the refrigeration position B of the discharge structure cutting unit 50, the control unit sets the set temperature of the first storage chamber 10a regardless of the set temperature of the temperature control unit 70. Set to. For example, even if the temperature control unit 70 is located at the set temperature of "strong freezing" in the state in which the refrigerating position B of the damper unit 51 is sensed in the sensing unit 60, the control unit may be configured to be used in the first storage chamber. Set the set temperature to the set refrigeration reference temperature. Here, the refrigeration reference temperature is set to 4 ° C, but this value is variable.

If the temperature control unit 70 is located at the set temperature of the "refrigeration" in the state in which the refrigerating position (B) of the damper unit 51 is detected in the sensing unit 60, the control unit is the set temperature of the first storage chamber (10a) Set to the set refrigeration reference temperature.

When the freezing position A of the discharge structure cutting unit 50 is detected by the sensing unit 60, the controller sets the set temperature of the first storage chamber 10a based on the set temperature of the temperature adjusting unit 70. . For example, when the temperature control unit 70 is located at a set temperature of "special freezing" in a state where the freezing position A of the damper unit 51 is detected by the sensing unit 60, the control unit "special freezing". Set the set temperature to the temperature set according to (eg -20 ℃).

Hereinafter, the operation of the refrigerator 1 according to the present invention will be described in detail with reference to FIGS. 4A to 5.

First, the sensing unit 60 detects the position of the damper unit 51 (S1).

If it is detected in step S1 that the damper unit 51 is the freezing position (A), the controller determines the position of the temperature control unit 70 (S3).

If it is determined in step S3 that the position of the temperature control unit 70 is bad, the control unit sets the set temperature (for example, -18 ° C) to the temperature set in "medium freezing" (S5). Here, the control unit determines that the temperature control unit 70 is defective when the temperature control unit 70 is in the "cold" position, or when the temperature control unit 70 spans the intermediate region of each step during the freezing strength step.

On the other hand, if the position of the temperature control unit 70 is normally located in any one step of the freezing step in step S3, the set temperature is set to a temperature set according to the position of the temperature control unit 70 (S7).

On the other hand, if it is detected in step S1 that the damper unit 51 is the refrigeration position (B), the controller sets the set temperature to the refrigeration reference temperature regardless of the position of the temperature control unit 70 (S9).

As described above, when the refrigerating position B of the damper unit 51 is sensed by the sensing unit 60, the refrigerating unit may set the set temperature of the first storage chamber 10a unconditionally regardless of the position of the temperature adjusting unit 70. By setting the reference temperature, it is possible to fundamentally prevent the malfunction of the freezer compartment and the refrigerating compartment switching function.

1 is a view showing a freezer compartment duct of a conventional refrigerator,

2 is a side cross-sectional view showing a schematic view of a refrigerator according to the present invention;

3 is a view showing a state of the first duct portion of the refrigerator according to the present invention;

4A and 4B are enlarged views illustrating an operating state of the damper unit in a state in which the first duct cover is removed from FIG. 3;

5 is a control flowchart of the refrigerator according to the present invention.

Explanation of symbols on the main parts of the drawings

1: refrigerator 10: main cabinet

10a: 1st storage room 10b: 2nd storage room

20: evaporator 30: blowing fan

40: duct member 40a: first duct portion

40b: 2nd duct part 47a: 1st cold air | gas outlet

50: discharge structure section 51: damper section

53: damper control unit 60: detection unit

70: temperature control unit

Claims (4)

A refrigerator having a main body cabinet forming a first storage chamber and a second storage chamber, and an evaporator for generating cold air supplied to the first and second storage chambers, A duct member having a first cold air discharge port through which cold air generated by the evaporator is discharged into the first storage chamber; A refrigeration position for opening the first cold air outlet above a predetermined opening degree so that the first storage compartment is used as a freezing compartment, and refrigerating opening the first cold air outlet outlet below the opening degree so that the first storage compartment is used as a refrigerator compartment A discharge structure section moving between positions; A sensing unit sensing a position of the discharge structure cutting unit; A temperature controller for adjusting a set temperature of the first storage chamber; And a controller configured to set the set temperature of the first storage chamber to a set refrigeration reference temperature regardless of the set temperature of the temperature control unit when the sensing unit detects the refrigeration position of the discharge structure cutting unit. The method of claim 1, The discharge structure cutting portion includes a damper portion coupled to the duct member to move between the freezing position and the refrigerating position, and a damper manipulation portion approaching and spaced apart from the temperature control portion and manipulating the movement of the damper portion; The detection unit is a refrigerator, characterized in that for detecting the proximity and separation of the damper control unit and the temperature control unit. The method of claim 2, The detection unit is a refrigerator, characterized in that provided with any one of a magnetic and a reed switch, photosensors, proximity sensors and contact sensors. The method according to any one of claims 1 to 3, And the control unit sets a set temperature of the first storage compartment based on a set temperature of the temperature control unit when the sensing unit detects a freezing position of the discharge structure cutting unit.

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