KR102660791B1 - Ice making apparatus using waste ice water - Google Patents

Abstract

We present an ice-making device that utilizes discarded ice water that is simple to install, requires little cost, does not require disassembly, and utilizes the ice water generated in the ice-making process. The device includes an ice maker that includes an evaporator that operates in the process of making ice using ice-making water, a water-cooled unit that cools the condenser by cooling water, and an ice storage tank that stores ice, and the ice water generated from the ice storage tank is distributed to the outside of the ice maker. It includes a discharging ice water pipe and an ice water cooling unit installed outside the ice maker and supplying cooling water to the water cooling unit. The ice water cooling unit generates cooling water by cooling water supplied from the water supply unit by ice water introduced from the ice water pipe. Let's do it.

Description

Ice making apparatus using waste ice water}

The present invention relates to an ice making device, and more specifically, to an ice making device that performs efficient cooling by utilizing ice water generated and discarded during the ice making process.

Generally, ice making is performed by repeating the ice making process and the ice transfer process of sending ice to a storage room. Various methods are applied to the ice-making process, for example, spraying water for ice-making or supercooling. In the ice making process, ice water is generated during the process of making ice, and the ice water is discharged to the outside of the ice making device and discarded. Many factors affect ice making efficiency, but the ambient temperature outside the ice making device has a particularly large influence. For example, when the ambient temperature is above 30℃ in summer, heat dissipation in the condenser is not smooth. In this case, the temperature of the evaporator cannot fall to the standard temperature for producing ice (approximately -15°C). If the temperature does not drop to the above standard temperature, ice will not be created properly.

In order to solve the above problem, a water cooling method such as Korean Patent Publication No. 2003-0073264, which cools the condenser with cooling water, is being applied. However, in the conventional method, the structure for water cooling is installed inside the ice maker, so the structure is complicated and separate installation costs are required. In particular, in order to install it separately on an ice making device that is already in operation, there is a practical difficulty because the ice making device must be disassembled and installed. In addition, in the conventional method, the ice water generated in the ice making process is discharged to the outside and discarded, so it cannot be utilized. The ice water is relatively cold compared to the ambient temperature, substantially approximately 5°C. Accordingly, if the ice water is used in a water cooling method instead of being discarded, there is room for significant improvement in cooling efficiency.

The problem to be solved by the present invention is to provide an ice making device that utilizes discarded ice water that is simple to install, requires little cost, does not require disassembly, and utilizes ice water generated in the ice making process.

An ice-making device using discarded ice water to solve the problem of the present invention includes an evaporator that operates in the process of making ice using ice-making water, a water cooling unit that cools the condenser by cooling water, and an ice storage tank that stores the ice. It includes an ice maker, an ice water pipe that discharges ice water generated from the ice storage tank to the outside of the ice maker, and an ice water cooling unit installed outside the ice maker and supplying the cooling water to the water cooling unit. At this time, the ice water cooling unit cools the water supplied from the water supply unit by ice water introduced from the ice water pipe to generate the cooling water.

The device of the present invention may further include an ice water pipe that discharges ice water issued from the evaporator to the outside of the ice maker. The ice water cooling unit includes a heat exchange tube bent in a zigzag shape. The heat exchange pipe may be located between a plurality of partition walls. The heat exchange tube may be made of a metal material. The heat exchange tube may have a corrugated shape. The water supply unit may simultaneously supply the ice-making water and the cooling water. The ice-making water may be supplied by an ice-making water supply unit. The ice water cooling unit includes a discharge passage through which the ice water that has completed the cooling process is discharged. The water cooling unit is connected to a hot water pipe that discharges hot water, and the amount of water supplied to the ice water cooling unit can be adjusted by the temperature of the hot water flowing through the hot water pipe.

By installing the ice water cooling unit on the outside of the ice maker of the present invention, installation is simple, requires little cost, does not require disassembly, and ice water generated in the ice making process is utilized. In particular, by using ice water, the efficiency of water cooling of the condenser increases.

1 is a block diagram showing a first ice making device according to the present invention.
FIG. 2 is a cross-sectional view illustrating the ice water cooling unit of FIG. 1.
Figure 3 is a block diagram showing a second ice making device according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. The embodiments described below may be modified into various other forms, and the scope of the present invention is not limited to the embodiments described in detail below. Examples of the present invention are provided to more completely explain the present invention to those skilled in the art. In the drawing, the representation is exaggerated for convenience of explanation. Meanwhile, terms indicating location, such as top, bottom, front, etc., are only related to what is shown in the drawing. In practice, the ice maker can be used in any optional orientation, and in actual use, the spatial orientation changes depending on the direction and rotation of the ice maker.

An embodiment of the present invention provides an ice making device that is simple to install, requires little cost, does not require disassembly, and utilizes ice water generated in the ice making process by installing an ice water cooling unit on the outside of the ice maker. To this end, we will look in detail at the ice making device employing the ice water cooling unit and explain in detail the process of cooling the ice making machine using the ice water cooling unit. The ice maker makes ice by repeating the ice-making process and the ice-transfer process of sending the ice to the storage room. The ice making device according to an embodiment of the present invention can be applied to all ice making methods, including spraying or supercooling water for ice making.

Figure 1 is a block diagram showing a first ice making device 100 according to an embodiment of the present invention. However, it is not a drawing in the strict sense, and there may be components not shown in the drawing for convenience of explanation.

According to FIG. 1, the first ice maker 100 includes an ice maker 10, an ice water cooling unit 20, and a water supply unit 30 for water supply. At this time, water is transferred from the water supply unit 30 to the water supply pipe 31, and the water may be tap water or purified water purified from a water purifier. The ice maker 10 includes means for making ice by repeating an ice-making process in which ice is made and a transfer process for sending ice to a storage room. Here, the expression focuses on the ice making unit 12, the water cooling unit 13, and the ice storage tank 18, which are essentially required in the first ice making device 100. The ice storage tank 18 stores ice chunks made in the ice making unit 12. In the ice maker 10, various means including the ice making unit 12, the water cooling unit 13, and the ice storage tank 18 are built into the case 11.

When the water flowing in through the water supply pipe 31 passes through the ice water cooling unit 20, the water cooled by ice water (FW in FIG. 2) flows into the supply pipe 33. At this time, the water flowing into the ice water cooling unit 20 is controlled by the first valve 32. The first valve 32 is a two-way valve and can be operated manually or electronically like a solenoid valve. Ice water (FW) may be water from melted ice stored in the storage unit, ice removal water, water overflowing the storage unit, etc. The water flowing into the supply pipe 33 is supplied into the ice maker 10. In other words, water is supplied to the ice maker 10 through the water supply pipe 31, the ice water cooling unit 20, and the supply pipe 33.

The supply pipe 33 inserted into the ice maker 10 branches into the first ice making water pipe 15 and the cooling water pipe 16 by the second valve 14. The first ice-making water pipe 15 faces the ice-making unit 12, and the cooling water pipe 16 faces the water-cooling unit 13. The second valve 14 is a three-way valve that opens and closes the supply pipe 33, the first ice-making water pipe 15, and the cooling water pipe 16. The ice making unit 12 can make ice by applying all known ice making methods, including spraying or supercooling the ice water supplied from the first ice making water pipe 15. Ice produced from the ice making unit 12 is stored in the ice storage tank 18 in the form of lumps.

Ice water (FW) according to an embodiment of the present invention is introduced into the ice water cooling unit 20 through two paths. The first ice water pipe 17 is a path through which ice water (FW) generated from the ice making unit 12 is input into the ice water cooling unit 20, and the second ice water pipe 19 is a path through which ice generated from the ice storage tank 18 is supplied. Water (FW) is introduced into the ice water cooling unit (20). That is, unlike the prior art, the first and second ice water pipes 17 and 19 do not discard the ice water (FW) generated in the process of making ice in the ice maker 10, but instead use all of it as the ice water coolant 20. ), which serves to cool the feed water. The ice water FW flowing through the first and second ice water pipes 17 and 19 has a relatively low temperature compared to the ambient temperature, and is substantially approximately 5°C.

Meanwhile, the ice maker 10 generates ice using the ice-making water using a refrigerant compressor, condenser, expander, and evaporator. The condenser cools the refrigerant compressed at high temperature and pressure in the compressor and liquefies it by removing condensation heat. The condensation heat is removed by cooling with water cooling, air cooling, etc., and the first ice maker 100 adopts a more effective water cooling method. That is, the water cooling unit 13 cools the condenser by water cooling. The evaporator operates in the process of making ice in the ice making unit 12. Since the compressor, expander, and evaporator are already well known, detailed description thereof will be omitted. Cooling water supplied to the water cooling unit 13 is supplied from a cooling water pipe 16 branched from the supply pipe 33. As described above, cooling water cooled from the ice water cooling unit 20 to ice water (FW) flows through the cooling water pipe 16. Accordingly, if ice water (FW) is used in a water cooling method without discarding it, the cooling efficiency of the water cooling unit 13 is improved.

Hot water generated from the water cooling unit 13 is discharged to the outside through the hot water pipe 40. A thermometer 41 is placed in the hot water pipe 40 to measure the temperature of the hot water. The temperature of the hot water pipe 40 is linked to the first valve 32. Specifically, when the hot water temperature exceeds the appropriate temperature, the first valve 32 is opened to supply the water, and when the hot water temperature is lower than the appropriate temperature, the first valve 32 is closed to supply the water. Reduce . Typically, the hot water temperature is preferably, for example, 40°C. That is, when the hot water temperature exceeds 40°C, the first valve 32 is opened to supply the water, and when the hot water temperature is lower than 40°C, the first valve 32 is closed to supply the water. Reduce. In this way, water can be used efficiently without wasting it.

The ice water cooling unit 20 is disposed outside the ice maker 10 and connected to the water supply unit 30. The internal structure of the ice maker 10 is the same as that of a conventional ice maker. However, there is a difference in that the cooling water cooled to ice water (FW) in the ice water cooling unit 20 flows through the supply pipe 33, the cooling water pipe 16, and the first and second ice water pipes 17 and 19. . The first ice maker 100 does not need to change the structure of a conventional ice maker. Accordingly, compared to conventional ice makers, the first ice maker 100 has a simpler structure and does not require the cost of disassembling the ice maker 10 and changing its interior.

FIG. 2 is a cross-sectional view illustrating the ice water cooling unit 20 of the first ice maker 100 of FIG. 1. At this time, the first ice making device 100 will be described with reference to FIG. 1 .

According to FIG. 2, the ice water cooling unit 20 includes a cooling tube 21, a plurality of partition walls 22, a heat exchange pipe 23, and a discharge passage 24. The discharge passage 24 discharges the ice water (FW) that has been input into the cooling tank 21 and completed the cooling process to the outside of the ice water cooling unit 20. The plurality of partition walls 22 cause the heat exchange pipe 23 to be bent in a zigzag shape. In the heat exchange pipe 23, heat exchange occurs between the feed water flowing inside and the external cooling water (FW), and the feed water forms cooled cooling water. When the heat exchange pipe 23 is bent in a zigzag manner, the area in contact with the ice water (FW) becomes larger than when the water supply pipe 31 and the supply pipe 33 are directly connected without the heat exchange pipe 23, thereby increasing the heat exchange effect.

In order to increase the cooling effect by heat exchange of ice water (FW), the heat exchange pipe 23 may be made of a metal material that has high heat transfer efficiency and is resistant to corrosion, such as stainless steel or copper. The number of partition walls 22, the length of the partition walls 22, and the size of the cooling tube 21 can be appropriately set in consideration of the cooling effect of the heat exchange pipe 23. In addition, the heat exchange tube 23 can be corrugated to increase the surface area where the heat exchange tube 23 is in contact with the coolant FW, thereby further enhancing the heat exchange effect. The ice water cooling unit 20 may be arranged perpendicularly to the ground or horizontally to the ground.

The first ice making device 100 according to an embodiment of the present invention is particularly effective when applied to an environment where the surrounding temperature is high, for example, 30° C. or higher, such as in summer or a hot area. Conventional water-cooled ice makers require a large amount of coolant to lower the temperature of the condenser due to the high temperature of the coolant used in the summer, and all of it is discarded after cooling the condenser. On the other hand, ice water (FW) has a relatively low temperature (substantially approximately 5°C) compared to the ambient temperature, so even if the ambient temperature is high, the cooling water cooled by the feed water is supplied to the water cooling unit 13, making it efficient for cooling the condenser. Water can be saved by reducing the amount of coolant required for cooling.

Figure 3 is a block diagram showing the second ice making device 200 according to an embodiment of the present invention. At this time, the second ice making device 200 is the same as the first ice making device 100 except for the second ice making water pipe 51 connected to the ice making unit 12.

According to FIG. 3, unlike the first ice maker 100, the second ice maker 200 separately supplies ice water for ice making. Specifically, the ice-making water is supplied from the ice-making water supply unit 50 to the ice-making unit 12 through the second ice-making water pipe 51. The first ice maker 100 simultaneously supplied ice water connected to the ice maker 12 and cooling water connected to the water cooling unit 13 from the water supply unit 30. However, the second ice maker 200 supplied ice water connected to the ice maker 12 and cooling water connected to the water cooling unit 13 simultaneously. Thus, the ice-making water and the cooling water are supplied independently. At this time, the ice-making water may be purified water that has gone through a purification process. The cooling water is opened and closed by the third valve 52 and supplied to the water cooling unit 13. The third valve 52 is a two-way valve that opens and closes the supply pipe and cooling water pipes 33 and 16. The third valve 52 may be operated manually or electronically, such as a solenoid valve.

The second ice maker 200 according to an embodiment of the present invention is particularly effective when applied to an environment where the surrounding temperature is high, for example, 30° C. or higher, such as in summer or a hot area. Conventional water-cooled ice makers require a large amount of coolant to lower the temperature of the condenser due to the high temperature of the coolant used in the summer, and all of it is discarded after cooling the condenser. On the other hand, ice water (FW) has a relatively low temperature (substantially approximately 5°C) compared to the ambient temperature, so even if the ambient temperature is high, the cooling water cooled by the feed water is supplied to the water cooling unit 13, making it efficient for cooling the condenser. Water can be saved by reducing the amount of coolant required for cooling.

Above, the present invention has been described in detail with preferred embodiments, but the present invention is not limited to the above embodiments, and various modifications can be made by those skilled in the art within the scope of the technical idea of the present invention. possible.

100, 200; First and second ice making devices
10; ice maker 11; case
12; Ice making unit 13; water cooling part
32, 14, 52; first to third valves
15, 51; 1st and 2nd de-icing water pipes
16; Cooling water pipe
17, 19; 1st and 2nd ice water pipes
18; Ice storage tank 20; Ice water cooling unit
21; Cooling bin 22; septum
23; heat exchange tube 24; discharge path
30; water supply unit 31; feed pipe
33; supply pipe 50; Ice-making water supply department

Claims (10)

An ice maker including an evaporator that operates in the process of making ice with ice-making water, a water-cooled unit that cools the condenser with cooling water, and an ice storage tank that stores the ice;
a first ice water pipe discharging ice water issued from the evaporator to the outside of the ice maker;
a second ice water pipe that discharges ice water generated from the ice storage tank to the outside of the ice maker; and
An ice water cooling unit installed outside the ice maker and supplying the cooling water to the water cooling unit,
The ice water cooling unit cools the water supplied from the water supply unit by ice water supplied from the first ice water pipe and the second ice water pipe to generate the cooling water,
An ice making device utilizing discarded ice water, wherein ice water injected from the first ice water pipe and the second ice water pipe is respectively injected into the ice water cooling unit. delete The ice making device using discarded ice water according to claim 1, wherein the ice water cooling unit includes a heat exchange tube bent in a zigzag shape. The ice making device using discarded ice water according to claim 3, wherein the heat exchange pipe is located between a plurality of partition walls. The ice making device using discarded ice water according to claim 3, wherein the heat exchange pipe is made of a metal material. The ice making device using discarded ice water according to claim 3, wherein the heat exchange pipe has a corrugated shape. The ice making device using discarded ice water according to claim 1, wherein the water supply unit simultaneously supplies the ice making water and the cooling water. The ice making device using discarded ice water according to claim 1, wherein the ice making water is supplied by an ice making water supply unit. The ice making device using discarded ice water according to claim 1, wherein the ice water cooling unit includes a discharge passage through which the ice water that has completed the cooling process is discharged. The method of claim 1, wherein the water cooling unit is connected to a hot water pipe discharging hot water, and the amount of water supplied to the ice water cooling unit is adjusted according to the temperature of the hot water flowing through the hot water pipe. One ice maker.

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