KR20070093633A - Bottle cooler - Google Patents

Abstract

A drink cooler is provided to provide cooled air into a refrigerating compartment at a maximum discharge angle, thereby entirely cooling the refrigerating compartment at a uniform temperature. A drink cooler includes a path(213) formed at a side in a refrigerating compartment(210) for sending air, of which temperature is lowered, upward rapidly, wherein a fan(216) is mounted at a side of the path. The path is formed with a plurality of air discharging holes(217) at an upper part for rapid sending of the air upward, so that the low temperature air is discharged into the refrigerator at a maximum discharge angle.

Description

Beverage Refrigerator {BOTTLE COOLER}

1 is a cross-sectional view schematically showing the internal structure of the refrigerator for drinks according to the present invention.

Figure 2a is a cross-sectional view schematically showing the internal structure of the refrigerator portion of the beverage refrigerator shown in Figure 1 is separated.

FIG. 2B is a partially enlarged view of “A” shown in FIG. 2A.

3 is a cross-sectional view schematically illustrating an internal structure of a heat exchanger of the beverage refrigerator illustrated in FIG. 1 in a separated state.

* Description of the main parts of the drawings *

100 ... beverage refrigerator 210 ... refrigerator

211 ... refrigerator body 212 ... shelves

213 ... Euro 214 ... Outlet

215 ... bulkhead 216 ... feeding fan

217 ... hole 310 ... heat exchanger

311 ... heat exchanger body 312 ... bulkhead

313 ... Condenser Mount 314 ... Evaporator Mount

315 ... evaporator 316 ... condenser

317 ... Compressor 318 ... Inlet

319 ... Feeder 320 ... Inlet

321 ... outlet 322 ... shipping pan

The present invention relates to a refrigerator for drinks.

In general, refrigerators use a compressor, a condenser, and an evaporator as a basic heat exchange means to keep food stored in the refrigerating chamber at a low temperature to prevent food from deteriorating for a long time, or to drink beverages in hot seasons such as hot fat or summer. It is a kind of device for storing.

As people's standard of living improves, there is an increasing desire to consume beverages stored at a suitable temperature, regardless of the environment. For example, the desire to drink a cool drink in the summer, or the desire to drink wine stored at a constant temperature regardless of the season, and the like is a typical example.

In order to satisfy these needs, refrigerators suitable for various types of beverages have been developed.

The beverage refrigerator (also known as a bottle cooler) having a heat exchanger according to the related art has a structure in which a heat exchanger is mounted at a lower portion and a storage space for refrigeration is provided at an upper portion thereof. As described above, in the refrigerator having a structure in which the heat exchanger and the refrigeration part are separated, air cooled in the heat exchanger is introduced through the lower part of the refrigeration part through a blower fan installed in the heat exchanger.

In such a structure, since the low temperature air sinks to the bottom by the natural law, in order to supply the low temperature air to the upper part of the refrigerating unit, the output of the blower fan must be increased. In other words, the air whose temperature is lowered in the heat exchange part must be fed to the upper part of the refrigerating part, so that the entire temperature of the refrigerating part can be evenly lowered through the low temperature air flow descending from the upper part to the lower part. do. Therefore, there is a disadvantage in that the blowing fan must be driven at a high output.

In addition, the low temperature air supplied from the lower part of the refrigerating part due to the shelf or the beverage stored in the refrigerating part is difficult to reach the upper part. In other words, since the efficiency of low temperature air from the lower part to the upper part of the refrigeration unit decreases due to the constituents or the storage materials that impede the flow of the airflow, the temperature difference between the lower part temperature and the upper part occurs, which causes the entire interior of the refrigerating part. Becomes difficult to maintain at a constant temperature. In this case, in the case of a beverage to maintain a constant temperature, such as wine, there is a problem that the storage efficiency is very low.

An object of the present invention is to solve the above problems and an object thereof is to allow the entire temperature of the refrigeration unit to be refrigerated at a uniform temperature.

Another object of the present invention is to increase the temperature efficiency of the refrigerator to the maximum while driving the drive means for supplying low-temperature air to the refrigeration unit of the refrigerator at a minimum output.

Still another object of the present invention is to transfer the air cooled by the heat exchanger to the upper portion of the refrigeration unit so that the low-temperature air from the upper can be moved to the lower side along the air flow so as to lower the temperature of the refrigeration unit within a short time The purpose is to improve performance and reduce power consumption.

The present invention provides a beverage refrigerator having an improved structure to solve the above problems and at the same time achieve the objects according to the present invention.

The beverage refrigerator according to the present invention has a means for feeding the air whose temperature has been lowered by the heat exchanger to the upper portion of the refrigerating portion so that the cold air from the upper portion of the refrigerating portion can be moved downward along the air flow.

Characteristic according to an embodiment of the refrigerator for a beverage according to the present invention is a flow path that can be supplied to the air temperature is lowered on one side of the inside of the refrigerating unit is formed, the structure in which the feeding fan is mounted on any one side of the flow path Is in.

Here, the heat exchanger coupled to the refrigeration unit may be configured to be separated from the refrigeration unit. In addition, a plurality of holes may be formed in the upper side of the flow path to maximize the discharge angle of the cold air discharged and discharged into the refrigerating unit.

In addition, a feeding fan may be further mounted inside the evaporator mounting part of the heat exchanger. In addition, a filter may be mounted to an inlet formed in the evaporator mounting portion of the heat exchanger.

Hereinafter, a beverage refrigerator will be described through examples to help understand the present invention. However, the present invention is not limited to the embodiments described below and may include various modified embodiments that can realize the features of the present invention described above.

The beverage refrigerator 100 according to the present invention includes a refrigeration unit 210 in which the beverage is stored and a heat exchange unit 310 for cooling the air to supply low temperature air to the refrigerating unit 210.

The refrigerating unit 210 may be equipped with a plurality of shelves 212 for displaying a beverage in the refrigerating unit body 211 having a sealed structure. The lower surface of the refrigerating unit body 211 is formed with an outlet 214 connected to the inlet 318 of the heat exchanger body 311 described below.

In addition, one side surface of the refrigerating unit body 211 has a partition wall 215 so that a flow path 213 is formed. The flow path 213 is formed such that air cooled in the heat exchange part 310 is supplied to the refrigerating part 210 and discharged from the upper part of the refrigerating part 210. A lower portion of the flow passage 213 is connected to a feeding port 319 formed at an upper portion of the heat exchanger main body 311, and an upper opening of the flow passage 213 is formed at an upper position inside the refrigerating portion 210. do.

The opening formed in the upper portion of the flow path 213 has a suitable structure in which the cooled air is discharged from the upper position inside the refrigerating unit body 211 so that the cooled air can be diffused to the entire interior of the inner unit body 211. It is preferable to have. That is, for example, the opening may have a dome shape in which a plurality of holes 217 are formed, as shown in FIG. 2B. However, the structure of the opening is not limited to the dome shape, but may be configured in a shape in which the discharge direction of the cooled air can be moved in the entire volume direction inside the refrigerating unit body 211.

In addition, the flow path 213 may have a partition wall 215 configured to have a cylindrical tube structure, or the partition wall 215 may have a plate shape configured to maintain a constant distance from one side of the refrigerating unit body 211. It may be configured. In the case where the flow path 213 is formed in a tubular shape, a plurality of flow paths 213 are formed, so that the flow rate of the supplied cooling air may be smoother.

The feeding fan 216 may be mounted at any position inside the flow path 213. Most preferably, the feeding fan 216 is mounted at an upper position of the flow path 213. At this time, the internal pressure of the opening is lowered by the feeding fan 216 so that the air cooled by the heat exchanger 310 is reduced. May be installed to be sucked up through the flow path 213. At this time, the internal pressure of the refrigerating unit body 211 is relatively increased by the operation of the feeding fan 216 so that the air whose temperature is increased is along the inlet 318 of the heat exchanger unit 311 through the discharge port 214. In order to discharge to the heat exchanger 310, the internal pressure of the flow path 213 is relatively lowered so that the air cooled in the heat exchanger 310 passes through the feed port 319 of the heat exchanger main body 311. It is possible to flow back into the refrigerating unit body 211 along the 213.

The heat exchange part 310 coupled to the refrigerating part 210 is an evaporator mounting part 314 and a condenser mounting part 313 by a partition wall 312 formed inside the heat exchange part body 311 as shown in FIG. 3. Compartment.

The heat exchanger 310 includes an evaporator 315, a condenser 316, a compressor 317 and a delivery fan 322, the evaporator 315 is located in the evaporator mounting portion 314, the condenser 316 And the compressor 317 are located in the condenser mount 313. The evaporator mounting portion 314 and the condenser mounting portion 313 is configured in a completely spaced state without a space connected to each other by the partition 312.

When the evaporator mounting part 314 is combined with the refrigerating part 210, the evaporator mounting part 314 is completely sealed to the outside to block the outside air. In addition, the condenser mounting part 313 is configured so that both sides are open so that outside air is introduced into one side and discharged to the other side.

That is, as shown in FIG. 3, the evaporator mounting part 314 has an inlet port 318 connected to the outlet port 214 of the refrigerating unit body 211 at any one position of the upper surface, and the inlet port 318. A feeding port 3319 is formed at a position opposite to the connection to the flow path 213 of the refrigerating unit body 211. The inlet 318 and the feed port 319 is preferably formed to be distributed to both sides around the evaporator 315.

One position of the evaporator mounting portion 314 may be further provided with a feeding fan (not shown). That is, in order to increase the heat exchange efficiency of the evaporator 315, a feeding fan may be further mounted at a position adjacent to the inlet 318 so that air flow may be generated in the direction of the evaporator 315, and on the other hand, adjacent to the feeding port 319 The feed fan may be further mounted at the position such that the air flow is indirectly pushed toward the feed port 319 at the evaporator 315 position.

The condenser mounting portion 313 of the heat exchanger body 311 is formed with an inlet 320 so that external air can be supplied to one side, and by the condenser 316 on the other side facing the inlet 320. An outlet 321 is formed through which air having an elevated temperature is discharged.

The condenser mounting part 313 is equipped with a condenser 316 and a compressor 317 connected to the evaporator 315, and is equipped with a delivery fan 322 for discharging the air lifted by the condenser 316. . At this time, the delivery fan 322 is preferably mounted in a position adjacent to the outlet 321.

The compressor 317 has an accumulator (not shown) and an expansion valve (not shown) between the condenser 316 and the evaporator 315. As described above, a device composed of a compressor 317, a condenser 316, and an evaporator 315 connected to each other by a connecting tube for heat exchange is generally known, and thus, detailed description thereof will be omitted.

The heat exchanger 310 having the configuration as described above may have a cassette structure to be detachable from the refrigerating unit 310. That is, the heat exchange part 310 may be formed as one independent structure so that the heat exchange part 310 may be combined with the refrigerating part 210 through a conventional detachable structure.

In addition, a filter (not shown) may be mounted at the inlet 318 in the inlet 318 formed at the upper portion of the heat exchanger main body 311 to prevent foreign substances from entering the evaporator mounting unit 314. . The filter may be a filter having a strainer structure as a general filter. Therefore, further detailed description will be omitted.

In the refrigerator for a beverage according to the present invention having the configuration as described above, the air whose temperature is lowered by the heat exchange action according to the operation of the compressor 317, the condenser 316, and the evaporator 315 is caused by the operation of the feeding fan 216. It is discharged from the evaporator mounting portion 314 through the feed port 319 flows through the flow path (213). The air flowing through the flow passage 213 is discharged to the upper portion of the refrigerating unit body 211 through a plurality of holes 217 (opening openings) formed at the end of the flow passage 213, thereby refrigerating unit body 211. It spreads all over the inside. Therefore, the low temperature air diffused to the inner side and the lower side of the refrigerating unit body 211 lowers the internal temperature of the refrigerating unit body 211. Thereafter, the air whose temperature is increased is passed back through the inlet 318 formed on the upper surface of the heat exchanger main body 311 through the outlet 214 formed on the lower surface of the refrigerating unit main body 211 to the evaporator mounting unit 314. The temperature is again lowered by the evaporator 315.

Through such a series of flows, the internal temperature of the refrigerating unit body 211 may be lowered in a short time, and the entire internal temperature of the refrigerating unit body 211 may be maintained uniformly.

Here, as described above, it is possible to further increase the cooling efficiency by further mounting a feeding fan at a position inside the evaporator mounting part 314.

As described above, according to the present invention, since the cooling air is injected at the maximum discharge angle at the upper position of the refrigerating unit body, the entire temperature of the refrigerating unit may be refrigerated at a uniform temperature.

In addition, it is possible to drive the drive means for feeding the low-temperature air to the refrigeration unit with a minimum output to increase the temperature efficiency of the refrigeration to the maximum.

In addition, since the air cooled by the heat exchanger is transferred to the upper portion of the refrigerating portion so that low-temperature air can be moved downward along the air flow from the upper portion to lower the temperature of the refrigerating portion in a short time, thereby improving cooling performance and power consumption. Can be reduced.

Claims (5)

A main body capable of storing a beverage; An outlet formed at one side of the lower portion of the main body to be connected to an inlet of the heat exchanger; A flow path formed by a partition on an inner side of the main body; Beverage beverage refrigerator comprising a refrigeration unit consisting of a feeding fan mounted on one side of the flow path. The beverage refrigerator according to claim 1, wherein the flow passage is formed in a dome shape having a plurality of holes so that the low temperature air discharged from the upper end thereof has a maximum discharge angle. The beverage refrigerator according to claim 1 or 2, wherein the heat exchange part has a structure of a cassette so as to be separated from the refrigeration part. The beverage refrigerator according to claim 3, wherein the heat exchange part is further equipped with a feeding fan inside the evaporator mounting part. The beverage refrigerator according to claim 3, wherein the heat exchange part is equipped with a filter at an inlet.

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