KR100504048B1 - Refrigerator - Google Patents

Abstract

The present invention relates to a refrigerator, and an object thereof is a simple structure using a single fan and a motor, and is provided on both sides of the discharge duct and the discharge duct provided on both sides of the refrigerator compartment evaporator to achieve a uniform distribution of the refrigerator compartment cold air. It is provided between the suction duct, and the discharge duct and the evaporator provided with a guide duct and a blowing fan provided to guide the cold air of the evaporator to the rear discharge duct.

The present invention is provided on both sides of the outer evaporator, the suction inlet is formed on the upper end and the lower end is in communication with the evaporator, provided on both sides between the suction duct and the evaporator, a plurality of cold air discharge ports are formed in the vertical direction and the upper end is in communication with the evaporator Guide ducts formed on both sides of the cold air inlet hole opened to the rear side to guide the cold air generated by the evaporator with the discharge duct and the discharge duct, and guide parts communicating with the upper end of the discharge duct, and the cold air inlet hole of the guide duct. And a cooling fan supply device for a refrigerating chamber provided with a blowing fan rotatably installed in the guide duct to suck the air into the guide unit.

Description

Refrigerator

The present invention relates to a refrigerator, and more particularly, to a refrigerator compartment cold air supply device that sucks the refrigerator compartment air into a cold compartment and supplies the same to the refrigerator compartment again.

In general, the refrigerator is configured to supply the cold air obtained by performing the freezing cycle to the freezer compartment and the refrigerating compartment to keep the food stored therein for a long time. Recently, the refrigerator maintains an optimal state for the food storage form of the freezer compartment and the refrigerating compartment. Independent cooling refrigerators have been proposed that have separate evaporators installed in the freezer compartment and the refrigerating compartment.

1 is a side cross-sectional view schematically showing such a refrigerator. As shown in the drawing, the independent cooling refrigerators are provided with cold air supply devices 30 and 40 separately behind the freezing compartment 10 and the rear side of the refrigerating compartment 20, respectively. The freezer compartment 10 is provided with an evaporator 31 and a blower fan 42 in the cold air supply device 30. The freezer compartment 10 sucks air from the freezer compartment 10 into the evaporator 31 and passes through the freezer compartment. Forced air again.

The cold air supply device 40 of the refrigerating chamber 20 is formed above the rear wall. Here, the evaporator 41 and the blowing fan 42 for blowing the cold air to the front side are also provided above the evaporator 41. In the front part of the evaporator 41, an inlet port 43 into which the refrigerating chamber 20 is sucked in air and a discharge port 44 through which cold air is discharged are formed, and the cold air distribution discharge port is formed so as to properly distribute the cold air to the entire refrigerating chamber 20. A cold air distribution duct 45 having 46 arranged up and down is installed at the center of the rear wall surface. Inside the cold air distribution duct 45, a rotary blade 47 that rotates by a separate motor is incorporated.

Therefore, when the blowing fan 42 and the rotary blade 47 of the refrigerating compartment 20 is rotated, the refrigerating compartment 20 air flows into the lower part of the evaporator 41 through the suction port 43, and the cold air generated while passing through Is evenly supplied to the refrigerating chamber 20 through the discharge port 44 and the cold air distribution discharge port 46 by the forced blowing force of the blowing fan 42 and the rotary blade 47. In particular, by driving the rotary blade 47 built in the cold air distribution duct 45, evenly distributed cold air in every corner of the refrigerating chamber 20, rotates so as not to escape the cold air even if the door 21 is opened to intercept cold air The refrigerating chamber 20 temperature is kept constant.

However, such an independent cooling refrigerator required a blowing fan, a rotor blade, and a respective motor to drive the cold air of the refrigerator compartment evaporator uniformly to the refrigerator compartment. As a result, the assembly process is complicated and manufacturing costs are increased.

In addition, there is a problem in that the power consumption of the refrigerator is increased due to each of the motors driven to act as a factor to lower the power consumption rating.

The present invention is to solve this problem, the object of the present invention, a simple structure using a single fan and a motor, the discharge duct and the discharge is provided on both sides of the refrigerator compartment evaporator to achieve a uniform distribution of the refrigerator compartment cold air It is to provide a refrigerator provided with a suction duct provided on both sides of the outside of the duct, and a guide duct and a blowing fan provided between the discharge duct and the evaporator to guide the cold air of the evaporator to the rear to guide the discharge ducts on both sides.

The present invention for achieving the above object is a refrigerator having a cold air supply device is installed on the rear wall of the refrigerating chamber is built in the main body formed in the freezer compartment and the refrigerating compartment is partitioned inside, so as to supply cold air to the refrigerating compartment. The cold air supply device includes a suction duct provided at both outer sides of the evaporator and formed at an upper end thereof, and having a lower end communicating with the evaporator, and provided at both sides between the suction duct and the evaporator. A discharge duct formed at an upper end thereof to communicate with the evaporator, and formed at both sides of the cold air inlet hole which is opened to the rear side to guide the cold air generated by the evaporator by the discharge duct and the outside of the cold air inlet hole to communicate with an upper end of the discharge duct. Guide duct consisting of a guide portion, cold air inflow of the guide duct That provided by the air blowing fan that is installed to be rotated by sucking the cool air in the interior of the duct so as to guide air flow to parts of the guide features.

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

Figure 2 is a side cross-sectional view showing the overall structure of the refrigerator according to the present invention, Figure 3 is a front view schematically showing a refrigerating chamber, Figure 4 is a perspective view showing a blowing fan and a guide duct. 5 is a perspective view showing another embodiment according to the present invention.

First, an embodiment according to the present invention will be described with reference to FIGS. 2, 3, and 4. As shown in the figure, the inside of the main body 100 forming an outer shape is partitioned up and down by the intermediate partition 150, the freezer compartment 110 is formed on the upper side, and the refrigerating chamber 120 is formed on the lower side. In addition, a plurality of shelves 160 are installed in the freezing compartment 110 and the refrigerating compartment 120 to store and store food, and a vegetable box 170 is provided below the refrigerating compartment 120. In addition, the doors 130 and 140 are hinged to the front of the main body 100 in a rotatable manner to open and close the freezing compartment 110 and the refrigerating compartment 120.

On the other hand, in the rear of the freezing chamber 110 and the refrigerating chamber 120, the cold air supply device (200, 300) for generating and supplying the cold air is configured separately.

First, the cold air supply device 200 for the freezer compartment is installed on the rear wall of the freezer compartment 110, an evaporator 210 for generating cold air, a circulation fan 220 provided at the center of the upper side of the evaporator 210 to force cold air, It consists of a motor 230 for driving the circulation fan 220 and the evaporator cover 240 to cover them, etc., the cold air discharge port 241 in which the cold air of the evaporator 210 is discharged to the freezing chamber 110 on the upper part of the evaporator cover 240. ) Is provided, and an air inlet 242 through which air in the freezer compartment 110 flows into the evaporator 210 is formed.

In addition, the cold air supply device 300 for a refrigerating compartment is a characteristic component of the present invention, and is configured to discharge cold air uniformly throughout the inside of the refrigerating compartment 120. For this purpose, a rectangular evaporator is formed on the rear wall center of the refrigerating compartment 120. The 310 is installed upright, which is covered by the cover insulation 351 and the evaporator cover 350. The upper part of the evaporator 310, the motor 321 and the blowing fan to suck the air of the refrigerating chamber 120 to the lower part of the evaporator 310 and forcibly blows the cool air generated while passing through the evaporator 310 to the refrigerating chamber 120. 320 is provided.

The motor 321 is fixedly installed on the rear side of the refrigerating compartment, and is provided to drive the motor shaft protruding toward the refrigerating compartment when power is applied, and the motor cover 326 is provided at the front thereof to be protected from moisture.

The blower fan 320 is a turbo fan provided in a cross-flow type, and sucks cold air generated from the rear lower side to cool the air in both sides by the evaporator cover 350 and the guide duct 390 to be installed later. It is prepared to blow air. The blowing fan 320 is provided in front of the shaft portion 320a and the shaft portion 320a provided to be coupled to the motor shaft, and a cover portion 320c provided with an inner side bent from the rear side in a lateral direction, and The outer peripheral rear side of the cover portion (320c) is installed at an angle orthogonal to the shaft portion (320a) and consists of a plurality of wing portions (320b) that are provided to be bent in the direction of rotation.

That is, the shaft portion 320a is provided with a circular rod, and a rear portion of the shaft portion 320a is provided with a groove not shown so that the rotating shaft of the motor 321 can be inserted and coupled therebetween, and the shaft portion 320a and the wing portion 320b are spaced apart from each other. As a result, the cool air on the rear side flows in between them and is guided by the curved inner surface of the cover portion 320c to blow the cool air laterally by the rotational force of the wing portion 320b. In the cross flow type blowing fan 320, the larger the number of the wing portions 320b, the larger the air volume can be obtained. In proportion to this, the load transmitted to the motor 321 also increases, so the number of the wing portions 320b is desired. The air volume is adjusted to match the output of the motor 321.

On the other hand, the outer side of the blowing fan 320 is provided with a guide duct 390 for guiding the blowing force generated in the blowing fan 320 in both directions. The guide duct 390 is installed on the upper side of the evaporator 310, and is provided with a cold air inlet 393 in the center so that cold air can flow in the rear and move forward, and the rear of the cold air inlet 393. The motor cover 326 is provided with a motor shaft protruding forward. The front end of the motor shaft extends forward of the cold air inlet hole 393 and is coupled to the blowing fan 320.

A guide part 391 is provided outside the blowing fan 320 provided in front of the cold air inlet hole 393 to guide the sucked cold air in both directions. The guide portion 391 is closed by the cover insulation 351 and the evaporator cover 350 in front so that the blowing force of the blowing fan 320 is quickly moved to the discharge ducts 331 and 332 to be installed later.

That is, the guide part 391 guides the blowing force of the blowing fan 320 to the upper ends of the discharge ducts 331 and 332 in both directions, thereby preventing cold air from being re-introduced into the evaporator 310 and at the same time making a quick movement. It is prepared to be.

As a result, cold air generated in the evaporator 310 is guided to both sides of the guide duct 390 by the cold air inlet hole 393 and the guide portion 391 by the suction force generated when the blower fan 320 is driven.

In addition, the left and right sides of the guide duct 390, the discharge ducts 331 and 332 for evenly discharging the cold air forcedly blown in both directions by the blowing fan 320 to the refrigerating chamber 120 and the air in the refrigerating chamber 120 are evaporator 310. Suction ducts (341, 342) are guided to. A guide duct 390 is provided at the center of the discharge ducts 331 and 332 so as to communicate with the installation space of the blower fan 320 and the motor 321, and both sides of the discharge ducts 331 and 332 are symmetrically along both ends of the evaporator 310. It extends downward. On both sides of the discharge ducts 331 and 332, a plurality of cold air discharge ports 333 spaced by a predetermined interval are arranged up and down. In addition, the centers of the suction ducts 341 and 342 are in communication with the lower end of the evaporator 310, and both sides thereof are extended in the upward direction to surround both sides of the discharge ducts 331 and 332.

That is, the upper ends of the suction ducts 341 and 342 extend symmetrically to the upper side of the rear wall of the refrigerating chamber 120, and the suction ports 343 are formed at both sides thereof so that the air in the refrigerating chamber 120 is suctioned at the uppermost end thereof. Accordingly, the air that has completed the heat exchange operation and rises above the refrigerating chamber 120 is introduced into the evaporator 310 through the suction port 343.

The cold air supply device 300 for the refrigerating compartment has a discharge plane (331,332) and the suction duct (341,342) symmetrically planarly formed at both ends of the evaporator 310, the inside of the refrigerating chamber 120 due to the installation of the cold air supply device Minimize the reduction in volume.

Hereinafter, another embodiment of the present invention will be described with reference to FIG. 5. Another embodiment of the present invention will be described with the same name and the same reference numerals because the other components except for the blowing fan is the same as the embodiment.

The blowing fan 400 is installed inside the guide duct 390. The blower fan 400 is an axial propeller fan, and is provided to suck cold air generated from the rear lower side to blow cold air in a lateral direction between the evaporator cover 350 and the guide duct 390 provided forward. will be. The blower fan 400 includes a shaft portion 400a provided to be coupled to a motor shaft (not shown) and a plurality of wings 400b extending outwardly from the shaft portion 400a. The shaft portion 400a is provided with a circular rod, and a rear side of the shaft portion 400a is provided with a groove not shown so that the rotation shaft of the motor 321 can be inserted and coupled thereto, and a plurality of wing portions 400b are coupled to the outer circumferential side to the outside. Extended. The number of the wing portions 400b is adjusted to suit the air volume and the output of the motor 321. Three wing portions 400b of the present invention are provided in a balanced manner.

The operation of the refrigerator according to the present invention configured as described above is as follows. When the blowing fans 320 and 400 of the refrigerating compartment cold air supply device 300 are rotated by the motor 321, the air located above the refrigerating compartment 120 passes through the inlets 343 and the suction ducts 341 and 342. It is sucked, and flows along it and flows into the bottom of the evaporator 310. In addition, the introduced air is changed into cold while passing through the evaporator 310 by the suction blowing force of the blowing fan 320.

The cold air generated through the evaporator 310 passes through the cold air inlet hole 393 of the guide duct 390 by the suction force of the blower fans 320 and 400, and the cold air passed through the blower fans 320 and 400 is blown through the blower fan 320. ) Is closed by the evaporator cover 350 and the cover insulating material 351 is moved to both sides opened. At this time, the cold air is quickly moved by the guide portion 391, and is sealed with the evaporator 310 side, thereby preventing re-inflow to the evaporator.

The cold air passing through the guide portion 391 flows along the discharge ducts 331 and 332, and is discharged to the refrigerating chamber 120 through the cold air discharge port 333. At this time, the discharge ducts 331 and 332 extend symmetrically along both side ends of the evaporator 310, and since the cold air discharge ports 333 are arranged up and down to be spaced apart at a predetermined interval, the inside of the refrigerating chamber 120 and the shelf ( 160 is supplied as a kankan to cool the food evenly.

In addition, the air that has completed the heat exchange operation in the refrigerating compartment 120 rises to the upper space of the refrigerating compartment 120 by a natural convection phenomenon, and the air is introduced back into the evaporator 310 through the suction ports 343 and the suction ducts 341 and 342. It is converted to cold and continuously circulated.

That is, the cold air supply device 300 for a refrigerating compartment according to the present invention moves quickly toward the discharge ducts 331 and 332 without the cold air discharged by the blowing fans 320 and 400 into the evaporator 310 due to the guide duct 390. In addition, since the cold air is evenly distributed and discharged in the refrigerating chamber 120 without a separate driving means, temperature deviation does not occur throughout the refrigerating chamber 120 to uniformly cool the stored food. In addition, since the air having completely completed the heat exchange action is introduced back into the evaporator 310 through the suction port 343 located above the refrigerating chamber 120, the heat exchange efficiency of the refrigeration cycle is improved. In addition, by installing discharge ducts 331 and 332 and suction ducts 341 and 342 around the evaporator 310 to planarize the cold air supply device 300, the internal volume of the refrigerating chamber 120 occupied by the cold air supply device 300 is minimized. You can do it.

As described in detail above, the refrigerator according to the present invention provides a guide duct on the outside of the blower fan so that the cold air blown from the blower fan is quickly moved without re-introduction to the evaporator, and is symmetrically centered on the evaporator provided at the center of the rear wall of the refrigerator compartment The discharge duct formed by the multiple stages of the cold air discharge port and the suction duct formed at the top of the suction port allows uniform cold air discharge to the entire refrigerating chamber without a separate operation means, so that a temperature difference does not occur throughout the inside of the refrigerating chamber, There is an advantage that the heat exchange efficiency is improved. In addition, by planarizing the cold air supply device provided in a simple structure, it is possible to minimize the internal volume of the refrigerating chamber occupied by the cold air supply device.

1 is a side cross-sectional view showing a conventional refrigerator.

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

3 is a front view schematically showing a refrigerator compartment of the refrigerator according to the present invention.

Figure 4 is a perspective view showing a blowing fan and a guide duct according to the present invention.

5 is a perspective view showing another embodiment according to the present invention.

Explanation of symbols on the main parts of the drawings

120: refrigerator 310: evaporator 320, 400: blowing fan

331,332: discharge duct 341,342: suction duct 350: evaporator cover

390: guide duct 391: guide part 393: cold air inlet

Claims (3)

A refrigerator having a cold air supply device installed on a rear wall of a refrigerator compartment, having a body formed by partitioning a freezer compartment and a refrigerator compartment therein, and having an evaporator built in the center to supply cold air to the refrigerator compartment, The cold air supply device is provided on both sides of the outside of the evaporator, the suction inlet is formed at the upper end and the lower end is in communication with the evaporator, provided on both sides between the suction duct and the evaporator, a plurality of cold air outlets are formed in the vertical direction A discharge duct having an upper end communicating with the evaporator, and a cold air inlet hole which is opened to the rear side to guide the cold air generated by the evaporator with the discharge duct and externally formed at both sides of the cold air inlet hole to communicate with the upper end of the discharge duct. And a blower fan rotatably installed inside the guide duct to suck the cold air into the cold air inlet hole of the guide duct and blow the cold air into the guide unit. The method of claim 1, The blower fan is provided in front of the cold air inlet, and the inside of the refrigerator characterized in that the cross flow type turbo fan provided with a plurality of wings orthogonal to the cold air inlet. The method of claim 1, The blowing fan is a refrigerator characterized in that the axial flow propeller fan provided in front of the cold air inlet.