KR200345579Y1 - A device to control cool air quantity for refrigerator - Google Patents

Abstract

The present invention by adjusting the amount of cold air supplied into the freezer compartment of the refrigerator as a mechanical structure to control the temperature inside the freezer, the refrigeration duct 200 provided in the refrigerator of the present invention refrigeration duct (300) The cold air flow port 230 is formed in communication with, and guides the cold air circulated by the blower fan 170 on the upper side of the cold air flow port 230, but is spaced apart from each other at the inlet side of the cold air flow port 230 A first guide plate 240 and a second guide plate 250 having a cold air passage 260 formed therebetween so that cold air flows therebetween are coupled to respective guide plates 240 and 250 and guide plates 240. It is provided with a rotating plate 400 having a circular opening and closing protrusions 410, 420 is installed to be rotatable along the (250) but the cold air passage 220 is formed to open and close the cold air passage 260 according to the rotation. will be. The temperature control of the refrigerator freezer according to the present invention can be made as a mechanical configuration without using a conventional thermostat can prevent the malfunction of the conventional electronic components to occur, and also a simple mechanical configuration In effect, the manufacturing cost of the refrigerator can be reduced.

Description

A device to control cool air quantity for refrigerator

The present invention relates to a refrigerator, and more particularly, to a refrigerator device for adjusting the amount of cold air to facilitate the temperature control of the refrigerator as a simple mechanical configuration.

In general, the refrigerator is a device for supplying the cold air generated by the operation of the refrigeration cycle to the storage compartment for storing foodstuffs to keep the stored foodstuffs fresh for a long time.

The conventional structure of such a refrigerator has a main body 10 formed of a wall foamed with urethane foam to form an external appearance as shown in FIG. 1, and a freezing chamber 11 in which frozen food is stored above the main body 10. Is formed, and a refrigerating chamber 12 partitioned by the freezing chamber 11 and the partition wall 13 is provided below the freezing chamber 11.

The rear wall of the freezing chamber 11 is provided with a heat exchanger (not shown) for generating cold air, and a blowing fan 14 for circulating cold air is installed above the heat exchanger. And the front side of the blower fan 14, the refrigeration duct 15 for guiding the flow of cold air is driven by the blower fan 14 is provided.

The front surface of the refrigeration duct 15 is provided with a duct cover 16 formed with a plurality of cold air outlet 20 in the upper and lower sides. The cold air flow passage of the refrigeration duct 15 has a cold air flow passage 21 communicating with a refrigeration duct (not shown) in the lower portion, and is bent along the rotational direction of the blower fan 14 at the periphery of the blower fan 14. Fork flow paths are formed.

And between the upper cold air discharge port 20 and the lower cold air outlet 21 of the refrigeration duct 15 is provided with an amount of cold air for adjusting the temperature inside the freezing chamber (11). This cool air volume control device is provided with a thermostat (17) operating by the bellows principle, the rotary switch 18 for the operation of the thermostat (17) is mounted on the cover 16, the refrigeration In the duct 15, a temperature sensor 19 is installed to detect a temperature in the freezer compartment 11 and transmit a temperature signal to indicate a temperature state of the freezer compartment 11.

Therefore, the temperature of the freezer compartment 11 of the refrigerator is achieved by turning on / off the compressor (not shown) by the thermostat 17 installed in the freezer compartment 11. In addition, a separate damper (not shown) is installed in the refrigerating duct to control the temperature of the refrigerating chamber 12.

The conventional refrigerator air amount adjusting device is used by applying a thermostat 17 that operates separately, the thermostat 17 is a precise electronic product, so there is a risk of malfunction even if some problems occur Therefore, although the precision is high, the operation stability of the refrigerator is lowered, and there is a problem of increasing the manufacturing cost of the refrigerator by using a precise electronic component such as the thermostat 17.

The present invention is to solve the above-mentioned problems, an object of the present invention is to provide a refrigerator air amount control device for controlling the temperature of the refrigerator more stably by adjusting the amount of cold air as a mechanical structure.

1 is a perspective view of a conventional refrigerator.

2 is a side cross-sectional view of the refrigerator according to the present invention.

3 is a perspective view showing a refrigerator according to the present invention.

Figure 4 is an enlarged perspective view showing a cold air amount control device of the refrigeration duct according to the present invention.

5 a and b is a state diagram of the operation of the cold air amount control device of the refrigeration duct according to the present invention.

* Description of the symbols for the main parts of the drawings *

100 ... body 110 ... freezer

160 ... heat exchanger 200 ... frozen duct

230.Cold air outlet 240 ... First guide plate

260 cold passage 300 refrigeration duct

400 ... rotating plate 410 ... first closing protrusion

420 ... 2nd closing protrusion 430 ... rotating shaft

In order to achieve the above objects, the present invention provides a compressor having a freezing compartment and a refrigerating compartment partitioned by partition walls therein, the compressor being installed under the main body to compress the refrigerant to a high pressure. An evaporator and a blower fan installed on the rear wall of the main body, a refrigeration duct installed in front of the evaporator and guiding cold air blown by the blower fan into the freezer compartment, communicating with the freezing duct, and supplying cold air into the refrigerating compartment. A refrigerator having a guiding refrigeration duct, wherein the refrigeration duct has a cold air flow port communicating with the refrigeration duct at a lower portion thereof, and guides the cold air blown by the blower fan to an upper side of the cold air flow port. The first guide plate and the second guide plate are provided on the upstream side of the sphere spaced apart from each other and formed with a cold air passage through which cold air flows therebetween, and each of the guide plates has a cold air passage formed to be in communication with the cold air passage. Is formed and has an opening and closing protrusion to the communication and blocking the cold air passage and the cold air passage through the rotation is performed It characterized in that the front plate is installed.

Hereinafter, one preferred embodiment according to the present invention will be described in detail with reference to the drawings.

The refrigerator according to the present invention has a main body 100 having a wall foamed with urethane foam as shown in FIGS. 2 and 3, and a freezer compartment in which frozen food is stored above the main body 100. The 110 is formed, and the refrigerating chamber 120 partitioned by the freezing chamber 110 and the partition wall 130 is provided below the freezing chamber 110.

In addition, the freezer compartment 110 and the refrigerating compartment 120 are installed by hinged to one side of the front surface of the freezer compartment door 140 and the refrigerating compartment door 150 to open and close the interior thereof.

On the other hand, the rear wall of the freezing chamber 110 is provided with a heat exchanger 160 for generating cold air, and the blower fan 170 for circulating cold air is installed above the heat exchanger 160. In addition, a freezing duct 200 is installed in the freezing chamber 110 and a refrigerating duct 300 is installed in the refrigerating chamber 120 to guide circulation of the cold air to the front side of the blowing fan 170 by the circulation of the blowing fan 170. It is.

The refrigeration duct 200 is provided with a duct cover 210 formed with a cold air outlet 220 in front of the refrigeration duct 200, the cold bottom of the refrigeration duct 200 so that the cold air flows into the refrigeration duct (300) The cold air flow port 230 is formed in communication with the 300, and the upper side of the cold air flow port 230, the guide plate protruding in a streamline so that the flow path is formed to be bent in accordance with the rotation direction of the blower fan 170 is streamlined. 240, 250 are provided.

The freezing duct 200 is distributed to the cold air outlet 230 to adjust the amount of cold air supplied to the refrigeration duct 300 to adjust the temperature of the freezing chamber 120 according to the amount of cold air supplied to the freezing compartment 110. A structure is provided.

Hereinafter, this cold air amount control structure will be described in more detail with reference to FIG. 4.

As shown, first, the first guide plate 240 and the second guide plate 250 are formed on the upper side of the cold air flow opening 230, and each of the guide plates 240 and 250 has a shape corresponding to each other. It is formed to be bent, but is formed in an arc shape having the same circumference.

Each of the guide plates 240 and 250 is spaced apart from each other, which passes through the cold air passage 260 so that the cold air circulated by the blowing fan 170 passes between the guide plates 240 and 250. The separation angle θ of the guide plates 240 and 250 is approximately 90 degrees.

Therefore, as the cold air passage 260 is opened and closed, the amount of cold air supplied from the freezing chamber 110 to the refrigerating chamber 120 is adjusted.

At this time, the opening and closing of the cold air passage 260 for adjusting the amount of cold air is made by the rotary plate 400 which opens and closes the cold air passage 260 by being inserted into each of the guide plates 240 and 250 described above.

The rotating plate 400 is formed in a circular plate shape, and two opening and closing protrusions 410 and 420 on which the guide plates 240 and 250 are fitted are formed on the inner surface thereof. The opening and closing protrusions 410 and 420 may include a first opening and closing protrusion 410 and a first opening and closing protrusion 410 and the above-described guide plate 240 and 250 which protrude in a vertical direction from the circumferential end of the rotating plate 400. It is provided with a second opening and closing protrusion 420 formed to be spaced apart a little larger than the thickness of the protruding.

Each of the first opening and closing protrusions 410 and the second opening and closing protrusions 420 may have a width equal to the width of the cold air passage 260, that is, a first cold air passage 411 cut into a width of about 90 degrees. The second cold air passage 421 is formed, and each of the cold air passages 411 and 412 is formed at a position in communication with each other.

In addition, between the cold air flow port 230 and the cold air passage 260 is formed a projection shaft 270 for coupling of the rotating plate 400, the projection shaft 270 is a central axis protruding in a cylindrical shape in the middle 271 and a coupling shaft 272 protruding outward from the central shaft 271, and the coupling shaft 272 forms a locking step 272a at its upper end. And the lower portion of the protruding shaft 270 is formed with a guide groove 280 for allowing the cold air passing through the cold air passage 260 to be guided to the cold air flow opening 230.

In addition, a rotating shaft 430 having a hollow 432 is formed at the center of the rotating plate 400 so that the protruding shaft 270 is fitted, and the locking jaw 272a of the coupling shaft 272 is provided inside the rotating shaft 430. The engaging groove 431 is formed, the outer side of the rotating plate 430 is formed with an outer rotation shaft 440 penetrating through the duct cover 210 of the freezing duct 200.

The hollow 441 is also formed in the outer rotation shaft 440, which is provided in a rectangular shape. And the duct cover 210 of the refrigeration duct 300 is coupled to the hollow 441 of the outer rotary shaft 440 is provided with a rotary switch 180 to allow the user to operate with the rotary shaft 440 from the outside, The rotary switch 180 is formed with a rectangular projection 181 is coupled to the hollow 411 of the outer rotation shaft 440.

On the other hand, the temperature control of the refrigerating chamber 120 is made by the thermostat 310 and the temperature detection sensor 310a installed in the refrigeration duct 300, the refrigeration duct through the cold air outlet 230 of the refrigeration duct 200 The cold air introduced into the 300 adjusts the cold air temperature in the refrigerating chamber 120 by turning on / off the driving of the compressor 190 according to the temperature state detected by the temperature sensor 310a. And the operation of the thermostat 310 at this time is made by the knob 320 installed on the rear wall of the refrigerating chamber (120).

Hereinafter will be described for the freezing duct cold air distribution of the refrigerator according to the present invention configured as described above.

As shown in FIG. 5A, when the freezing chamber 110 is left in the "weak cooling" state, the freezing passage 411 formed on the opening / closing protrusions 410 and 420 of the rotating plate 400 by rotating the rotating plate 400. When 421 communicates with the cold air passage 260 between the first guide plates 240 and 250 and the second guide plates 240 and 250, the cold air passes through the cold air passage 260. It proceeds to the cold air outlet 230 through the guide groove 280.

In this case, the cold air of the freezing compartment 110 is smoothly distributed to the refrigerating duct 300, whereby a smaller amount of refrigerant is supplied to the freezing compartment 110, and a larger amount of refrigerant is supplied to the refrigerating compartment 120.

As shown in FIG. 5B, in the state in which the rotating plate 400 is coupled to the protruding shaft 270 of the freezing duct 200, the cold air passage 260 of the freezing duct 200 and the cold air passage of the rotating plate 400 are formed. When the spheres 411 and 421 are in communication with each other, the cool air in the heat exchanger 160 is almost supplied into the freezer compartment 110, and a very small amount of cool air is supplied to the rotating plate 400 and the guide plate 240. It is supplied to the refrigerating chamber 120 through the refrigerating duct 300 through the gap of (250). Thus, the freezer compartment 110 is in a "cold" state.

On the other hand, the temperature control in the refrigerating chamber 120 is made by controlling the driving of the compressor 190 to be in a set temperature state according to the temperature detected by the temperature sensor 310a.

Temperature control of the refrigerator freezer according to the present invention as described above can be made as a mechanical configuration without using a conventional thermostat can prevent the malfunction of the conventional electronic components to occur, and also a simple mechanism In this configuration, it is possible to reduce the manufacturing cost of the refrigerator.

Claims (4)

A compressor which forms an exterior and has a freezing compartment and a refrigerating compartment formed by partition walls therein, and is installed at a lower portion of the main body to compress the refrigerant to a high pressure. An evaporator and a blower fan installed on the rear wall of the main body, a refrigeration duct installed in front of the evaporator and guiding cold air blown by the blower fan into the freezer compartment, communicating with the freezing duct, and supplying cold air into the refrigerating compartment. A refrigerator having a guiding refrigeration duct, The refrigeration duct is formed in the lower portion of the cold air duct communicating with the refrigeration duct, The first guide plate and the second guide plate are formed on the upper side of the cold air flow port to guide the cold air blown by the blower fan, but are spaced apart from each other on the upstream side of the cold air flow port to form cold air passages through which cold air flows. , And a cold plate configured to communicate with the cold passage, and a rotating plate having an opening and closing protrusion to allow the cold passage and the cold passage to communicate with each other according to rotation. The circular opening and closing protrusion of claim 1, wherein the first opening and closing protrusion is formed on the circumference of the rotating plate and the second opening and closing protrusion is formed to have a smaller diameter than the first opening and closing protrusion. Refrigerator comprising a. 3. The cold air passage of claim 2, wherein the cold air passage comprises a first cold passage opening formed in the first opening and closing opening, and a second cold passage opening formed in the second opening opening, wherein the second cold passage opening and the second cold passage opening each other. Refrigerator, characterized in that formed to communicate. According to claim 1, Between the cold air flow passage and the cold air passage is formed with a protruding shaft protruding so that the rotating plate is coupled, the inner surface of the rotating plate is characterized in that the rotating shaft formed with a hollow to the projection shaft is provided Refrigerator.