KR100565489B1 - A direct-type refrigerator having multi-room and multi-door - Google Patents

Abstract

The present invention relates to a direct-cooling refrigerator capable of minimizing a temperature variation in a storage compartment, wherein the plurality of storage compartments are divided by barrier parts, and in the direct-cooling refrigerator equipped with a plurality of doors to open and close each of the plurality of storage compartments. A blow passage is formed in at least one of the doors so that the cold air of the storage chamber is sucked and discharged, and a blower is mounted at one side of the blow passage, and the air discharge port of the blow passage is located at a portion farther from the barrier part. It is characterized in that it is formed more on the portion near the barrier portion.

Direct Cooling Refrigerator, Barrier Section, Storage Room, Door, Blower, Blowing Path, Air Outlet

Description

A direct-type refrigerator having multi-room and multi-door}

1 is a perspective view of a direct-cooling refrigerator according to the prior art,

2 is a perspective view of one embodiment of a direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention;

3 is an internal configuration of an embodiment of a direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention;

Figure 4 is a bottom view showing a door of an embodiment of a direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention,

5 is a plan view illustrating a flow path guide mounted to a door of an embodiment of a direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention.

<Explanation of symbols on main parts of the drawings>

202: outer casing 204, 206: storage compartment

208, 210: refrigerant pipe 212, 214: inner casing

216: insulation 226,228: door

230,240: blowing flow path 232,242: air intake

234, 244: air outlet 234a, 244a: first air outlet

234b, 244b: second air outlet 236, 246: communication path

236a, 246a: first communication path 236b, 246b: second communication path

250,260: blower 251,261: rotating shaft

252,262: Blowing motor 254,264: Blowing fan

270,272: door casing 274,276: euro guide

304,306: packing

The present invention relates to a direct-cooling refrigerator having a plurality of storage compartments and doors, and more particularly, to a direct-cooling refrigerator having a plurality of storage compartments and doors for minimizing the temperature variation of the storage compartment.

In general, a refrigerator maintains the inside of a storage compartment such as a freezer compartment or a refrigerating compartment at a low temperature by using a refrigeration cycle of a refrigerant consisting of a compressor, a condenser, an expander, and an evaporator, and is classified into an intercooled refrigerator and a direct-cooled refrigerator according to whether cold air is circulated.

The intercooled refrigerator is to cool the storage compartment by forcibly circulating cold air through a fan by installing an evaporator outside the storage compartment, and the direct cooling refrigerator is surrounded by an evaporator to cool the storage compartment by conduction and natural convection.

Since the intercooled refrigerator cools the storage compartment while the cold air is forcedly circulated, the temperature inside the storage compartment can be maintained uniformly, but the flow path structure of the cold air is complicated and there is a possibility of refrigerant leakage. Since the temperature is kept low by conduction and natural convection, the temperature difference between the center and the edge of the storage compartment and the temperature difference between the upper part and the lower part are larger than those of the intercooled refrigerator, but there is an advantage that the structure is simple and there is little possibility of leakage of the refrigerant.

1 is a perspective view showing a direct-cooling refrigerator according to the prior art.

As illustrated in FIG. 1, in the conventional direct-cooling refrigerator, a plurality of storage compartments 20 are formed by barriers 10 arranged vertically in the outer casing 2, and each of the storage compartments 20 is formed. A door 30 for opening and closing is provided.

The plurality of storage compartments 20 are each formed by an inner casing 22 made of a metal surrounded by a heat insulating material filled in the outer casing 2, and a refrigerant passes through the outer circumferential surface of each of the inner casings 22. Refrigerant pipes are mounted.

However, in the direct-cooling refrigerator according to the prior art, the temperature distribution of each of the storage compartments 20 is determined by the heat load invading through the heat insulating material and the door 30 and the diameter and position of the refrigerant pipe, and the center of the storage compartment 20. On the side, the temperature is higher than the edge side of the storage compartment 20, and in the edge side of the storage compartment 20, the portion closer to the outer casing 2 is closer to the barrier 10, and the temperature becomes higher. Each of the storage compartments 20 has a problem that a temperature deviation occurs.

The present invention has been made to solve the above-mentioned problems of the prior art, by increasing the cold air flow in the portion close to the barrier to minimize the temperature variation between the portion close to the barrier and the portion far away from the barrier direct cooling type The purpose is to provide a refrigerator.

Direct cooling type refrigerator having a plurality of storage compartments and doors of the present invention for solving the above problems and the outer casing to form an appearance; A plurality of inner casings spaced apart from the inside of the outer casing, each of which has a storage chamber formed therein, and a refrigerant pipe is attached thereto; A heat insulating material disposed between the outer casing and each of the plurality of inner casings and between the plurality of inner casings; A plurality of doors installed to open and close the storage chambers, respectively; A flow path guide provided in each of the plurality of doors, an air inlet is formed at the center of the bottom, a plurality of air outlets are formed at the bottom edge, and a communication path communicating with the air inlet and the air outlet is formed; In the direct-cooling refrigerator including a blower provided in the door, the flow path guide is formed with a first air outlet in each of the corners of the bottom edge of the flow path guide, and the plurality of the plurality of bottom edges of the flow path guide It is characterized in that the plurality of second air outlets are formed only between the corner portion of the corner side facing the two doors.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view of one embodiment of a direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention, and FIG. 3 is an internal configuration diagram of an embodiment of a direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention.

In the direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention, as illustrated in FIGS. 2 and 3, the storage compartments 204 and 206 having an upper surface are formed inside the outer casing 202 forming the exterior, and the refrigerant is also used. A plurality of inner casings 212 and 214 equipped with flowing refrigerant tubes 208 and 210 are disposed, and a heat insulating material is provided between the outer casing 202 and the plurality of inner casings 212 and 214 and between the plurality of inner casings 212 and 214. 216a and 216b are disposed.

The top cover 217 is disposed at the upper end of the outer casing 202 and the upper end of the inner casing 24 to cover the upper ends of the heat insulating materials 216a and 216b.

A machine chamber 218 is formed below the outer casing 202, and a compressor 220 compresses the evaporated refrigerant at high temperature and high pressure while passing through each of the refrigerant pipes 208 and 210 in the machine chamber 218. The condenser 222 in which the refrigerant compressed by the compressor 220 condenses by heat exchange with the surroundings, and an expansion mechanism 224 in which the refrigerant is expanded to low temperature and low pressure so that the refrigerant condensed in the condenser 222 can be easily evaporated ) Is placed.

The condenser 222 is composed of a refrigerant pipe 222a through which the refrigerant passes and an electrothermal metal member 222b to which the refrigerant pipe 222a is fixed.

The refrigerant pipes 208 and 210 mounted on each of the inner casings 212 and 214 may be connected in series, but are preferably connected in parallel to allow sufficient cooling in each storage chamber 204 and 206. When the 208 and 210 are connected in parallel, the evaporated refrigerant passing through each of the refrigerant pipes 208 and 210 is combined and then introduced into the compressor 220 and compressed, and the refrigerant expanded by the expansion mechanism 224 is dispersed. It is introduced into each refrigerant pipe (208, 210).

The inner casings 212 and 214 are formed in a rectangular cylindrical shape having an upper surface and an inner portion to form the storage chambers 204 and 206 therein, and the thermal conduction of the refrigerant passing through the refrigerant pipes 208 and 210 and the air inside the storage chambers 204 and 206 are used. It is made of a heat-transfer metal member such as aluminum so as to constitute an evaporator together with the refrigerant pipes (208, 210).

The heat insulator 216a and 216b are disposed between the outer casing 202 and the inner casings 212 and 214 so as to surround the circumferential and bottom surfaces of the inner casings 212 and 214, and between the plurality of inner casings 212 and 214. It is foamed in and filled.

On the other hand, the one side portion (212a, 214a) facing the plurality of inner casing (212, 214) and the heat insulating material (216b) disposed between the plurality of inner casing (212, 214) facing the cold air between the plurality of storage compartments (204, 206) It acts as a barrier part A that prevents movement and thermal movement.

The direct-cooling refrigerator having the plurality of storage compartments and doors is provided with a plurality of doors 226 and 228 for opening and closing the top surface of each of the storage compartments 204 and 206, and at least one of the plurality of doors 226 and 228 may be used. Blowing flow paths 230 and 240 are formed to discharge the cold air after being sucked in, and a blowing force is generated inside the doors 226 and 228 in which the blowing flow paths 230 and 240 are formed to suck and discharge cold air in the storage chambers 204 and 206. Blowers 240 and 250 are mounted.

The blow passages 230 and 240 and the blowers 240 and 250 may be provided only in a part 226 of the plurality of doors 226 and 228, but are most preferably provided in all of the plurality of doors 226 and 228.

Each of the air flow passages 230 and 240 may include air inlets 232 and 242 where cold air is sucked into the storage chambers 204 and 206 and air outlets 234 and 244 where cold air sucked into the doors 226 and 228 is discharged back into the storage chambers 204 and 206. And communication paths 236 and 246 communicating the air intake ports 232 and 242 and the air discharge ports 234 to guide the cold air sucked into the air intake ports 232 and 242 to be discharged through the air discharge ports 234 and 244. .

The air outlets 234 and 244 are closer to the barrier portion A than to the portion closer to the outer casing 202 so that the cool air around the barrier portions 212a.214a and 216b can be circulated more quickly. Is formed.

The blowers 250 and 260 are disposed in the center of the door 226 and the blower motors 252 and 262 protruding downward from the rotation shafts 251 and 261, and the blower fans 254 and 264 built into the rotation shafts 251 and 261 of the blower motors 252 and 262. It consists of.

In addition, the doors 226 and 228 are formed in the door casings 270 and 272 forming the exterior, and the inside of the door casings 270 and 272 to form bottom surfaces of the doors 226 and 228 and the air flow paths 230 and 240 formed therein. (274,276).

Reference numeral 300 is a back cover mounted to the back of the machine room 218, reference numeral 302 is a ventilation hole formed in the back cover 280, and reference numerals 304 and 306 are the bottom edges of each of the doors 226 and 228. A rectangular packing member disposed at the outermost side, and reference numerals 308 and 310 are heat insulating members filled in the doors 226 and 228, respectively.

4 is a bottom view showing a door of one embodiment of a direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention, and FIG. 5 is mounted to a door of an embodiment of a direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention. A top view of the flow guide is shown.

Although the flow path guides 274 and 276 may be formed in a circular shape, as illustrated in FIGS. 4 and 5, the flow guides 274 and 276 may be formed in polygons, particularly quadrangles.

The air inlets 232 and 242 are formed at the centers of the bottom surfaces of the flow path guides 274 and 276 so that the cool air at the center of the storage chamber can be sucked upward.

The air outlets 234 and 244 are formed at first corners of the edges of the flow path guides 274 and 276 to discharge cold air sucked into the doors 226 and 228 to four corner portions of the storage chambers 204 and 206. A second gap formed between an air outlet port 234a and 244a and a corner side vertex portion in which the plurality of doors 226 and 228 face each other so as to discharge cold air sucked into the doors 226 and 228 to the side of the barrier unit; It consists of air discharge ports 234b and 244b.

The first air outlets 234a and 244a are formed in a symmetrical manner with a line connecting the vertices of the flow path guides 274 and 276 with the air intake ports 232 and 242 interposed therebetween.

The plurality of second air outlets 234b and 244b are formed to be spaced apart from each other.

The communication paths 236 and 246 cross the first communication paths 236a and 246a formed crosswise on the upper surfaces of the flow path guides 274 and 276 and the ends of the first communication paths 236a and 246a to communicate with each other. And second communication paths 236b and 246b formed in a quadrangular shape along the upper edges of the tops 274 and 276.

In addition, the flow path guides 274 and 276 constitute lower surfaces of the doors 226 and 228 and the lower panels 274a and 276a in which the air inlets 232 and 242 and the plurality of air outlets 234a, 234b, 244a and 244b are formed. It is attached to the upper surface of the lower panel (274a, 276a) to form the communication paths (236, 246) and in consideration of the heat insulating performance of the doors (226, 228) composed of a plurality of upper insulation (274b, 276b) made of foamed plastic It is desirable to be.

The lower panels 274a and 276a are preferably made of a plastic injection molding or a metal member in consideration of aesthetics.

Referring to the operation of an embodiment of a direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention configured as described above are as follows.

First, when the compressor 220 is driven, the high temperature and high pressure gas refrigerant compressed by the compressor 200 is condensed by being exchanged with external air while passing through the refrigerant pipe 222a of the condenser 222. 224 is expanded to a low temperature low pressure refrigerant which is easy to evaporate, absorbs heat from the storage compartments 204 and 206 while passing through the refrigerant pipes 208 and 210 constituting the evaporator, and evaporates, and circulates back to the compressor 220. During the compression, condensation, expansion, and evaporation of the refrigerant as described above, the air in the storage chambers 204 and 206 is exchanged with the refrigerant passing through the refrigerant pipes 208 and 210 by conduction and natural convection to cool.

When each of the blower motors 252 and 262 is driven, each of the blower fans 254 and 264 generates a blowing force, and the cool air at the center side of the storage chambers 204 and 206 is blown upwards to provide the air intakes of the doors 226 and 228. 232,242). The cold air sucked in this way is guided to each of the first communication paths 236a and 246a of the communication paths 236 and 246, and is distributed in four directions before and after the flow path guides 274 and 276, and the distributed cold air is connected to the communication path ( The second communication paths 236b and 246b of 236 and 246 are guided to the vertex portions of the flow path guides 274 and 276.

The cold air moved to the vertex portions of the flow path guides 274 and 276 is discharged downward through each of the first air discharge ports 234a and 244a and blown downward along the corner portions of each of the inner casings 212 and 214.

Cold air blown downward along the edges of each of the inner casings 212 and 214 collides with the bottom of the inner casings 212 and 214, and then gathers into the inner lower center of each of the storage compartments 204 and 206, and again the center of the storage compartments 204 and 206. As the upper side is blown upward, the central side of the storage chambers 204 and 206 are cooled and then circulated to the air inlets 232 and 242 of the flow path guides 274 and 276.

Meanwhile, some of the cold air that is guided to each of the two communicating paths 236b and 246b and moved to the vertex portion of the flow path guides 246 and 248 is passed through the second air outlets 234b and 244b. Discharged downward to accelerate the cold air circulation in the vicinity of the barrier unit A, discharged downward through each of the first air outlets 234a and 244a, and then collected into the inner lower center of each of the storage chambers 204 and 206. Circulated in combination with cold.

That is, the cool air inside the storage compartments 204 and 406 circulates in the center of the storage compartments 204 and 406, the interior of the doors 226 and 228, the edges of the storage compartments 204 and 406, and the lower part of the storage compartments 204 and 406, and the internal temperature of the storage compartments 204 and 406. It is maintained uniformly as a whole, in particular, by circulating more cold air near the barrier unit (A) to minimize the temperature deviation due to the difference in thermal insulation performance by the barrier unit (A).

On the other hand, in the direct-cooling refrigerator having a plurality of storage compartments and doors according to the present embodiment, the blower and the flow path guide are mounted to each of the plurality of doors, but the present invention is not limited to the above-described embodiment, and the blower and the flow path guide are provided in plurality. Of course, it is also applicable to a case where only a part of the doors are mounted.

The direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention has the advantage of minimizing the temperature variation in the storage compartment by circulating cold air in the vicinity of the barrier portion between the plurality of storage compartments.

In addition, a cold air circulation passage structure of a direct-cooling refrigerator having a plurality of storage compartments and doors according to the present invention, an air inlet is formed at the center of the bottom of the door, and a plurality of air outlets are formed at the bottom edge of the door. A communication path is formed at the air inlet port and the air outlet port so that the cool air of the storage compartment circulates in the center side of the storage compartment, the interior of the door, the edge side of the storage compartment, and the lower portion of the storage compartment. There is an advantage to minimize the temperature deviation between.

Claims (4)

An outer casing forming an appearance; A plurality of inner casings spaced apart from the inside of the outer casing, each of which has a storage chamber formed therein, and a refrigerant pipe is attached thereto; A heat insulating material disposed between the outer casing and each of the plurality of inner casings and between the plurality of inner casings; A plurality of doors installed to open and close the storage chambers, respectively; A flow path guide provided in each of the plurality of doors, an air inlet is formed at the center of the bottom, a plurality of air outlets are formed at the bottom edge, and a communication path communicating with the air inlet and the air outlet is formed; In the direct-cooling refrigerator configured to include a blower installed in the door, The flow path guide has a first air discharge port formed at each vertex portion of the bottom edge of the flow path guide, and a plurality of flow path guides are formed only between the edge side vertex portions of the bottom edge of the flow guide where the plurality of doors face each other. The second air outlet is spaced apart from the direct cooling refrigerator having a plurality of storage compartments and doors. delete The method of claim 1, The first air outlet is a direct-cooling refrigerator having a plurality of storage compartments and doors, characterized in that a plurality of the symmetry is formed between the vertices of the flow path guide and the line connecting the air intake. delete

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