KR20230150503A - Unit cooler with air guide - Google Patents

Abstract

The present invention relates to a unit cooler equipped with an air guide, and its purpose is to provide a unit cooler in which all of the air flowing into the inside of the case through the air inlet passes through an evaporator. The present invention for this purpose includes a unit case formed with an air inlet and an air outlet; an evaporator installed inside the unit case to face the air flowing in through the air inlet to induce cooling of the air through heat exchange between the refrigerant and the air; A blower installed in the unit case so as to be located around the air outlet and flowing external air so that it is introduced through the air inlet and then discharged through the air outlet; and a drain plate formed at the bottom of the evaporator to collect condensate generated during the defrosting process of the evaporator and falling to the bottom of the evaporator and discharge it to the outside. An air guide installed between the evaporator and the drain plate to close the gap and guides all of the air flowing in through the air inlet to pass through the evaporator. A unit cooler with an air guide is provided, further comprising: .

Description

Unit cooler with air guide {Unit cooler with air guide}

The present invention relates to a unit cooler, and more specifically, to prevent a portion of the air flowing into the unit cooler from flowing into the drain plate through a gap formed between the evaporator and the drain plate and being discharged from the unit cooler without passing through the evaporator. It relates to a unit cooler designed to improve heat exchange efficiency by including an air guide that closes the gap formed between the evaporator and the drain plate so that all of the incoming air passes through the evaporator.

In general, a freezer is a facility that stores stored items such as fish or meat to prevent them from spoiling, and is designed to prevent spoilage or deterioration of stored items by maintaining the internal temperature at a low level.

In order to maintain the internal temperature of the freezer at a low temperature below zero, a unit cooler is installed inside the freezer.

Figure 1 shows the internal structure of a conventional unit cooler.

The conventional unit cooler 10 consists of an evaporator 30 and a blower 40 installed inside a unit case 20 in which an air inlet 21 and an air outlet 22 are formed, and the evaporator 30 is It forms a refrigeration cycle with the compressor, condenser, and expansion valve shown, and is installed inside the unit case 20 to face the air flowing in through the air inlet 21 to cool the incoming air.

In the unit cooler configured as described above, a drain plate 50 is provided at the bottom of the evaporator 30 to collect and discharge condensed water generated during the defrosting process of the evaporator 50.

The drain plate 50 has an open upper end to allow condensed water falling to the bottom of the evaporator 30 to flow smoothly during the defrosting process of the evaporator 30.

Meanwhile, in order to ensure that the condensate falling from the evaporator 30 flows into the drain plate 50 rather than flowing out to the outside, the evaporator 30 is located within the vertical upper area of the drain plate 50, and in particular, the evaporator 30 exposed to the outside In order to prevent condensate flowing down the back of the evaporator 30 from falling to the outside, the back of the evaporator 30 is located in front of, or inside, the unit case 20 rather than the back of the drain plate 50.

As the back of the evaporator 30 and the back of the drain plate 50 are formed at different positions, a gap is formed between the rear end of the evaporator 30 and the rear end of the drain plate 50, and the water flowing into the unit case is formed. A phenomenon occurs in which part of the air flows into the drain plate through the gap and is discharged into the freezer through the air outlet without passing through the evaporator. In this way, some air flowing through the drain plate without passing through the evaporator causes the unit cooler. There is a problem that refrigeration efficiency is reduced.

In addition, when the evaporator is defrosted, some of the condensate flowing down the back of the evaporator falls and scatters due to collision with the coil or fin of the evaporator, and condensate flying to the rear of the evaporator does not flow into the drain plate but falls to the bottom of the freezer. There is a problem with it falling and contaminating the surrounding area.

Registered Utility Model Bulletin No. 20-0440229 (announced on May 30, 2008)

The present invention was made in consideration of the above problems, and the purpose of the present invention is to provide a unit cooler in which all of the air flowing into the case through the air inlet passes through an evaporator.

Another object of the present invention is to provide a unit cooler that prevents condensate generated during the defrosting process of the evaporator from falling to the rear of the evaporator and contaminating the surrounding area.

Another object of the present invention is to provide a unit cooler that can improve cooling efficiency by allowing air passing through the evaporator to more actively contact the fins of the evaporator.

The present invention, which achieves the above-described object and performs the task of eliminating the drawbacks of the prior art, includes a unit case having an air inlet and an air outlet; an evaporator installed inside the unit case to face the air flowing in through the air inlet to induce cooling of the air through heat exchange between the refrigerant and the air; A blower installed in the unit case so as to be located around the air outlet and flowing external air so that it is introduced through the air inlet and then discharged through the air outlet; and a drain plate formed at the bottom of the evaporator to collect condensate generated during the defrosting process of the evaporator and falling to the bottom of the evaporator and discharge it to the outside. An air guide installed between the evaporator and the drain plate to close the gap and guides all of the air flowing in through the air inlet to pass through the evaporator. A unit cooler with an air guide is provided, further comprising: .

Meanwhile, in the unit cooler equipped with the air guide, a condensate receiver is formed to protrude backward from the air guide or the drain plate with an upward slope and guides condensate falling from the back of the evaporator to the inside of the drain plate. .

Meanwhile, in the unit cooler provided with the air guide, it is made in the form of a plate having an upper surface facing the bottom of the evaporator, and reflects air coming out from the bottom of the evaporator at a position close to the bottom of the evaporator and returns it to the evaporator. A windbreak may be further formed on the air guide.

Meanwhile, in the unit cooler equipped with the air guide, the windbreak may be made of a plate having a wave-shaped cross-sectional structure in which protrusions and grooves are repeated based on the front-back direction of the unit cooler, and a condensate flow port is formed in the groove. You can.

Meanwhile, in the unit cooler provided with the air guide, the protrusion may be formed to have a trapezoidal cross-section, and the groove may be formed to have an inverted trapezoidal cross-section.

Meanwhile, in the unit cooler provided with the air guide, a drain heater may be installed below the protrusion.

According to the present invention having the above features, the air guide installed to close the gap between the back of the evaporator and the drain plate can improve the cooling efficiency of the unit cooler by guiding all of the air flowing into the unit cooler to pass through the evaporator. there is.

Additionally, by preventing condensate generated during the defrosting process of the evaporator from falling out of the drain plate, it is possible to prevent condensation from contaminating the outside of the unit cooler or the bottom of the freezer.

In addition, the cooling efficiency of the air can be further improved by returning the air that flows into the evaporator and then exits the bottom of the evaporator to pass through the evaporator again.

In addition, a windbreaker with a wave-shaped cross-sectional structure can further improve the cooling efficiency of the air by dispersing the air returning to the evaporator in various directions rather than being limited to a specific direction, allowing the returning air to contact the evaporator over a wider range.

In addition, by installing a drain heater using the empty space at the bottom of the protrusion that forms the windshield, not only can the internal space of the unit cooler be used more effectively, but the bottom of the protrusion also provides the function of concentrating the heat generated from the drain heater onto the drain plate. This can more effectively prevent condensate from freezing.

1 is an internal structure diagram of a conventional unit cooler;
2 is a diagram showing the internal structure of a unit cooler according to a preferred embodiment of the present invention;
3 is a side view of an air guide according to a preferred embodiment of the present invention;
Figure 4 is a detailed view showing an air guide installed inside a drain plate according to a preferred embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described in detail in connection with the attached drawings. In describing the present invention, if a detailed description of a related known function or configuration is judged to unnecessarily obscure the gist of the present invention, the detailed description will be omitted.

Figure 2 is an internal structural diagram of a unit cooler according to a preferred embodiment of the present invention, Figure 3 is a side view of an air guide according to a preferred embodiment of the present invention, and Figure 4 is a drain of the air guide according to a preferred embodiment of the present invention. A detailed view showing the state of installation inside the plate is shown.

The unit cooler according to a preferred embodiment of the present invention consists of a unit case 110, an evaporator 120, a blower 130, a drain plate 140, and an air guide 150.

The unit case 110 is made in the shape of an empty box, with an air inlet 111 formed on the back and an air outlet 112 formed on the front, so that the air flowing in through the air inlet 111 flows into the unit. It is configured to pass through the internal space of the case 110 and be discharged through the air outlet 112.

A drain plate 140 is formed at the bottom of the unit case 110 to collect condensate generated during the defrosting process of the evaporator 120 and discharge it to the outside. The drain plate 140 is located at the bottom of the unit case 110. It can be manufactured in the form of a drain plate 140, or it can be configured by installing a separately manufactured drain plate 140 at the lower part of the unit case 110, and installed inside the unit case 110. It is located vertically below the installed evaporator 120 so that condensed water falling from the evaporator 120 naturally flows into the drain plate 140.

The evaporator 120 is installed inside the unit case 110 to face the air flowing into the unit case 110 through the air inlet 111, and operates as a refrigerating unit together with a compressor, condenser, and expansion valve (not shown). It is configured to form a cycle and is configured to cool the air through heat exchange between the air and the refrigerant.

The blower 130 is installed around the air outlet 112 and is configured to suck in the internal air of the unit case 110 and discharge it through the air outlet 112 when operating.

The air guide 150 closes the gap formed between the evaporator 120 and the drain plate 140 and guides all of the air flowing into the unit case 110 to pass through the evaporator 120. The evaporator ( It is made in a block shape with an upper surface in close contact with the bottom of the drain plate 140, a bottom and sides (rear side, left side, right side) in close contact with the bottom and inner side of the drain plate 140, and is located below the rear end of the evaporator 120. It is installed inside the drain plate 140 to be located at.

This air guide 150 can be fixed to the drain plate 140 by fastening bolts.

Meanwhile, there is a condensate receiver 160 that prevents condensate falling from the back of the evaporator 120 from leaving the drain plate 140 and falling to the outside of the unit cooler, and the air flowing into the evaporator 120 flows into the bottom of the evaporator 120. A windshield 170 that prevents the air from being discharged internally to the drain plate 140 may be further formed on the air guide 150.

The condensate receiver 160 is composed of a plate that protrudes backwards with an upward slope from the upper rear surface of the air guide 150 or the drain plate 140 and extends long in the left and right width directions of the evaporator 120. ) is made to receive condensate falling from the back of the drain plate and guide it to the inside of the drain plate 140.

Meanwhile, according to a preferred embodiment of the present invention, the condensate receiver 160 is formed as an integrated structure at the rear upper part of the air guide 150 so that the condensate receiver 160 is also installed during the installation process of the air guide 150. It comes true.

The windbreaker 170 is made of a plate that protrudes forward from the front upper part of the air guide 150 and extends in the left and right width directions of the evaporator 120, and is configured to include an upper surface facing the bottom of the evaporator 120. .

This windshield 170 is installed close to the bottom of the evaporator 120 and faces the bottom of the evaporator 120, and provides a function to reflect air coming out of the bottom of the evaporator 120 and return it to the evaporator 120. I do it.

Meanwhile, the windshield 170 according to a preferred embodiment of the present invention is configured to have a wave-shaped cross-sectional structure including a plurality of protrusions 171 and a plurality of grooves 172.

More specifically, the windshield 170 according to a preferred embodiment of the present invention has a protrusion 171 and a groove 172 formed to extend in the width direction of the evaporator 120 so as to be parallel to the air guide 150. It is made of a plate having a wave-shaped cross section, and a condensate flow port 173 is formed in the groove portion 172.

At this time, a plurality of the condensate water flow ports 173 may be formed to be distributed in the groove portion 172, and each condensate water flow port 173 may be formed as a circular or rectangular hole.

Meanwhile, the protrusion 171 has a trapezoidal cross-section, and the groove 172 has a reverse trapezoidal cross-section, and the protrusion 171 and the groove 172 are repeatedly continuous in front of the air guide 150. They are connected to each other to form a windshield 170 with a wave-shaped structure.

In this way, the windshield 170, which has a wave-shaped structure in which the trapezoid-shaped protrusion 171 and the inverted trapezoid-shaped groove 172 are formed repeatedly and continuously, reflects air coming from the lower part of the evaporator 120 and returns it to the evaporator 120. When sending, the upper surface 171a of the protrusion 171 and the inclined surfaces 171b formed on both sides of the protrusion 171 reflect the air in different directions and send it back, so that the air flows into the evaporator 120 and the evaporator 120 over a wider range. Heat exchange efficiency can be further improved by encouraging heat exchange while in contact.

Meanwhile, a drain heater 180 is installed in the empty space formed below the protrusion 171 to prevent freezing of condensate flowing into the drain plate 140.

In this way, by installing the drain heater 180 in the empty space below the protrusion 171, not only can the space inside the unit case 110 be utilized more effectively, but the bottom of the protrusion 171 is separated from the drain heater 180. Since it provides the function of a reflector that focuses the generated heat on the drain plate 140, freezing of condensate can be prevented more effectively.

In the unit cooler according to the present invention configured as described above, air is introduced into the interior of the unit case 110 by the operation of the blower 130, passes through the evaporator 120, and is discharged through the air outlet 112, and the evaporator ( 120) receives the refrigerant circulating through the compressor, condenser, and expansion valve and cools the air by exchanging heat with the air.

Meanwhile, the gap formed between the rear end of the evaporator 120 and the rear end of the drain plate 140 is completely closed by the air guide 150, so all of the air flowing into the unit case 110 through the air inlet 111 Can be guided to the evaporator 120.

As such, the unit cooler according to the present invention can improve refrigeration efficiency by allowing all of the air flowing into the unit case 110 to pass through the evaporator 120.

In addition, the windshield 170, which is formed to protrude in front of the air guide 150, returns the air that flows into the evaporator 120 and then escapes from the lower part of the evaporator 120 to the evaporator 120 and is used again by the evaporator 120. Let it cool.

Meanwhile, the windmill 170 can widely disperse the air returning to the evaporator 120, leading to more effective cooling of the air.

Meanwhile, during the defrosting process of the evaporator 120, condensate falling from the evaporator 120 flows into the drain plate 140 through the condensate water flow port 173 formed in the windshield 170, and is After gathering in a certain location, it is discharged to the outside.

Meanwhile, the condensate receiver 160, which is formed to protrude toward the rear of the air guide 150, receives condensate falling from the back of the evaporator 120 to a position outside the range of the drain plate 140 and guides it to the drain plate 140, where the condensate flows. This prevents it from falling on the outside of the unit cooler and contaminating the surrounding area.

As described above, the unit cooler according to the present invention improves the flow of incoming air so that all of the incoming air passes through the evaporator 120, and in addition, the air exiting the bottom of the evaporator 120 is returned to the evaporator. By sending it back to (120), energy savings can be realized by increasing the cooling efficiency of the air by the evaporator (120), and the convenience of maintenance can be improved by preventing the surroundings of the unit cooler from being polluted by condensate. It is a very useful invention.

The present invention is not limited to the specific preferred embodiments described above, and various modifications can be made by anyone skilled in the art without departing from the gist of the invention as claimed in the claims. Of course, such changes are within the scope of the claims.

<Explanation of symbols for main parts of the drawing>
111: air inlet 112: air outlet
110: unit case 120: evaporator
130: blower 140: drain plate
150: Air guide 160: Condensate receiver
170: windbreaker 171: protrusion
172: Groove 173: Condensate flow port
180: drain heater

Claims (6)

A unit case 110 having an air inlet 111 and an air outlet 112;
An evaporator 120 installed inside the unit case 110 to face the air flowing in through the air inlet 111 to induce cooling of the air through heat exchange between the refrigerant and the air;
A blower 130 installed in the unit case 110 around the air outlet 112 to allow external air to flow in through the air inlet 111 and then discharged through the air outlet 112; and
In a unit cooler including a drain plate 140 formed at the bottom of the evaporator 120 to collect condensate generated during the defrosting process of the evaporator 120 and falling to the bottom of the evaporator 120 and discharge it to the outside,
It is installed between the evaporator 120 and the drain plate 140 to close the gap formed between the lower rear portion of the evaporator 120 and the drain plate 140, so that all of the air flowing in through the air inlet 111 is blocked. A unit cooler with an air guide, further comprising an air guide 150 that guides the air to pass through the evaporator 120.
In claim 1,
A condensate receiver 160 is formed to protrude backward from the air guide 150 or the drain plate 140 with an upward slope and guides the condensate falling from the back of the evaporator 120 into the interior of the drain plate 140. A unit cooler with an air guide, characterized in that it includes.
In claim 1,
It is made in the form of a plate having an upper surface facing the bottom of the evaporator 120, and reflects air coming out of the lower part of the evaporator 120 at a position close to the bottom of the evaporator 120 and returns it to the evaporator 120. A unit cooler with an air guide, characterized in that a windshield (170) is further formed on the air guide (150).
In claim 3,
The windbreaker 170 is made of a plate with a wave-shaped cross-sectional structure in which protrusions 171 and grooves 172 are repeated based on the front and rear directions of the unit cooler, and a condensate flow port 173 is formed in the groove 172. A unit cooler with an air guide, characterized in that:
In claim 4,
The unit cooler with an air guide, wherein the protrusion 171 has a trapezoidal cross-section, and the groove 172 has an inverted trapezoidal cross-section.
In claim 4,
A unit cooler with an air guide, characterized in that a drain heater 180 is installed at the lower part of the protrusion 171.

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