KR20140060114A - A water-cooled ice machine - Google Patents

Abstract

The present invention relates to a water-cooled ice machine, and more specifically, to a small-size ice machine that performs condenser cooling of the ice machine by cooling water and allows an efficiency of the ice machine to be increased by controlling a circulation apparatus of cooling water through linking the operation of cooling water circulation apparatus and the ice machine together. The present invention provides a water-cooled ice machine comprising an ice-making unit provided with a supply pipe and a discharge pipe for ice-making water for supplying and discharging ice-making water by using a cooling system for circulation of a refrigerant through a compressor, a condenser, an expansion valve and an evaporator; a cooling water pump for supplying cooling water from a water tank for storage of cooling water to a cooling unit for cooling the condenser; a cooling water circulation apparatus consisting of a heat exchange unit connected with a water tank for releasing heat of the cooling water flowing out of the cooling unit; and a control unit to control the same, wherein a discharge control valve is provided in the middle of the discharge pipe for ice-making water to be connected with the water tank, and an overflow drainage pipe is connected to a certain part on the top of the water tank. In addition, a temperature sensor is mounted and a blower fan is additionally provided in the cooling water inlet part of the heat exchange unit, while an exhaust fan is additionally mounted on the water tank.

Description

A water-cooled ice machine < RTI ID = 0.0 >

The present invention relates to a water-cooled type ice maker, and more particularly, to a water-cooled type ice maker in which a condenser is cooled by a cooling water, and a cooling water circulating device and an ice maker are operated to control the cooling water circulating device, To a water-cooled ice maker.

Generally, an ice maker performs an ice-making process in which water is supplied into an ice-making chamber to freeze ice, and an ice-making process in which ice is removed by supplying hot gas after ice is produced and ice is transferred to an ice- , And repeats this operation to continuously perform ice-making

Generally, the performance of an ice-maker can be varied depending on the efficiency of heat dissipation from the condenser to the outside. The air-cooled ice maker cools the heat of the condenser by external air and the water-cooled ice maker cools by water. Recently, a water-cooled ice maker has been widely used to improve the ice making performance by cooling the condenser using water because the ground performance is lowered and the failure rate is high.

A schematic structure of such a conventional water-cooled ice maker is illustrated in FIG.

The ice maker 1 comprises a freezing section 10 for making ice and a cooling system for controlling the temperature of the freezing section. The cooling system includes a general compressor 21, a condenser 22, an expansion valve 23, (24).

Water is supplied to the ice-making part through the ice-making water inlet to fill the ice-making container appropriately formed, and the ice-making water is ice-cooled by heat exchange with the evaporator by the operation of the cooling system.

On the other hand, when the hot gas is supplied to the ice making part for easy detachment of the ice cubes, the surface of the ice is melted and is easily released from the container, and then discharged through the transfer device (not shown) . At this time, a small amount of water and the remaining ice-making water melted on the surface of the ice generated at the time of ice-making are discharged to the outside through the ice-making water outlet.

The refrigerating system of the icemaker generally circulates the refrigerant to perform heat exchange with the refrigerant. In operation, the refrigerant gas of low temperature and low pressure introduced from the evaporator is converted into high temperature and high pressure through the compressor, And the condenser discharges the heat to the outside and is liquefied into the low temperature and high pressure refrigerant liquid. The refrigerant thus liquefied flows to the expansion valve. In the expansion valve, the refrigerant is expanded to a low-temperature and low-pressure refrigerant, and the refrigerant is sent to the evaporator. The refrigerant evaporates while being absorbed by the evaporator, The temperature of the ice making unit is kept at a low temperature state where the ice can be frozen by absorbing the heat in the ice making unit, so that the ice making water put in the ice making unit is ice-cooled.

The refrigerant passing through the condenser is directly introduced into the evaporator without passing through the expansion valve according to the change of the direction of the solenoid valve 26, and the hot gas is supplied to the evaporator.

The water-cooled ice maker includes a cooling unit using cooling water for efficiently exchanging the heat of the condenser during the ice making, and a cooling water inlet 41 and a cooling water outlet 42 for circulating cooling water are formed in the cooling unit.

On the other hand, a control unit for controlling the solenoid valve and the cooling system is further provided.

In the water-cooled type ice maker, various water-cooled structures are possible depending on how the cooling water to be circulated in the cooling section is to be supplied.

The simplest method uses a structure in which a water pipe such as a water pipe is connected to a cooling water inlet of a cooling part to supply cooling water and a cooling water discharged after being used for cooling is directly discharged to a sewer through a cooling water outlet. And is widely used because it is easy to supply cooling water, but it has a disadvantage that the amount of water used is very large.

As a structure of another water-cooled ice maker, a domestic registration room 20-0138409 describes a structure in which water drained from an ice maker is used for cooling a condenser. This is because the iced water discharged from the ice- However, the amount of water thus discharged is relatively small, and there is a limitation that it is generated only during the ice making process, not the ice making process in which the condenser is operated.

On the other hand, in the Utility Model Application No. 20-2010-0012479, a separate water tank 44 is provided, and a small amount of cold drain water discharged from the ice-maker during ice-making is mixed with the cooling water of the water tank and circulated to the cooling unit to cause heat exchange with the condenser However, since circulation of the water tank cooling water is performed when the compressor operates in conjunction with the operation of the compressor, the water tank cooling water is circulated even during the freezing, thereby lowering the temperature of the refrigerant in the condenser. There is a problem.

Therefore, there is still a demand for a water-cooled type ice maker that reduces the amount of cooling water used in a water-cooled type ice maker for heat-exchanging heat radiated from a condenser by using cooling water, do.

The present invention is intended to improve and complement the cooling water circulation technology of the above-mentioned conventional water-cooled type ice maker and to improve the saving of cooling water used for a small water-cooled type ice maker used for a business use less than 1 ton and ice making efficiency.

By complementing the cooling water circulation path of the existing ice maker, it is possible to design the cooling water circulation system consisting of the icing of the icemaker and the linking operation, thereby preventing the water consumption which is abandoned in large quantity and efficiently using the cooling function of the ice maker. And to provide a highly water-cooled ice maker.

Further, it is desired to improve the energy efficiency by controlling the operation of the cooling water pump during the icing and the icing, and to improve the spatial efficiency by enabling the cooling water circulating device to be desorbed from the ice making part.

According to an aspect of the present invention, there is provided a water-cooled ice-maker provided with an ice-making water supply pipe for supplying and discharging ice-making water using a cooling system for circulating a coolant through a compressor, a condenser, an expansion valve, A cooling water pump for supplying cooling water from the water tank for storing the cooling water to the cooling part for cooling the condenser and a heat exchange part for discharging the heat of the cooling water flowing out from the cooling part and connected to the water tank The water-cooled ice maker comprises a water circulation device and a control part for controlling the water circulation device, wherein a discharge control valve is provided in the middle of the ice-making water discharge pipe and connected to the water tank, do.

In addition, a temperature sensor is installed in the cooling water inflow portion of the heat exchanging portion, and further, a blowing fan is further provided, and an exhaust fan is further installed in the water tank.

During the freezing, the controller causes the refrigerant to flow through the compressor, the condenser, the expansion valve, and the evaporator. At this time, the controller activates the cooling water pump of the cooling water circulating device. During the freezing, the refrigerant flows through the pressure extractor, the condenser and the evaporator In this case, the cooling water pump of the cooling water circulation device may be stopped, and the cooler circulation device may be separately provided so as to be removably attached to the ice-making portion.

The present invention having the above-described structure relates to a structure of a cooling water circulating apparatus for a water-cooled ice-maker for lowering the temperature of a refrigerant in a condenser by causing heat exchange with a condenser of an ice maker. The cooling water has a circulating path through which heat- It is possible to efficiently perform heat exchange with the condenser through the cooling water of the condenser, and to use the cold water generated during the condensation as the cooling water, thereby improving the cooling efficiency.

In addition, the overflow drain pipe is connected to the water tank, and the cold water generated during the ice storage is supplied to the water tank, and a certain amount of water flows out through the overflow drain pipe, thereby preventing the cooling water from being corrupted.

Further, the energy efficiency can be improved by controlling the operation of the cooling water pump during the icing operation and the icing operation, and the spatial efficiency can be improved by allowing the cooler circulation apparatus to be desorbed from the freezing section.

1 is a schematic view of a conventional water-cooled ice-
2 is a schematic view of a water-cooled ice-maker having a conventional cooling water circulating device
3 is a schematic view of a water-cooled ice-maker according to an embodiment of the present invention;

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

Here, the same reference numerals are used for the same components, and detailed descriptions of known functions and configurations that may unnecessarily obscure the gist of the present invention are not repeated, and the embodiments of the present invention are not limited to the average knowledge And the like, the shape and size of the elements in the figures may be exaggerated or omitted for clarity of explanation.

3, the water-cooled ice-maker is supplied with relatively low-temperature cooling water to the cooling unit 140 and the relatively high-temperature cooling water flowing out from the cooling unit is recovered And circulates the cooling water.

 That is, the circulating refrigerant is circulated through the compressor 121, the condenser 122, the expansion valve 123 and the evaporator 124. The ice-making water supply pipe 131 and the ice- A pump 145 for supplying cooling water from the water tank 144 for storing cooling water to the cooling unit for cooling the condenser, And a control unit (150) for controlling the cooling water circulating unit and the heat exchanging unit (143) connected to the water tank. The ice-making water discharge pipe is connected to the water tank and the discharge control valve 160, and a water overflow drain pipe 142 is connected to a predetermined upper end portion of the water tank.

The cooling water inlet 147 of the heat exchanger is equipped with a temperature sensor 146 and a blowing fan 147. The water tank is further equipped with an exhaust fan 141.

During the freezing, the controller causes the refrigerant to flow through the compressor, the condenser, the expansion valve, and the evaporator. At this time, the controller causes the pump of the cooling water circulation device to operate. When the refrigerator is freezing, the refrigerant flows through the compressor, the condenser and the evaporator. The cooling water pump of the circulation device may be stopped, and the cooler circulation device may be separately provided to detachably attach to the ice-making part.

Generally, the temperature of the cooling water flowing into the cooling unit is relatively low, about 15 to 20 DEG C, and the temperature of the cooling water flowing out of the cooling unit after absorbing heat from the condenser is about 35 to 40 DEG C and relatively high.

Accordingly, it is necessary to lower the temperature of the cooling water flowing out of the cooling section to flow into the cooling section. To this end, a heat exchanging section is provided and a pump is required for circulation of the cooling water.

In order to improve the performance of the water-cooled ice-maker, it is necessary to suppress the circulation of unnecessary cooling water. To this end, it is necessary for the control unit to control the operation of the pump at the time of ice making and at the time of ice making.

That is, since it is necessary to cool the heat of the condenser quickly by putting cool refrigerant into the ice-making portion during the ice making operation, the control portion operates the pump to operate the cooling water circulating device, The circulation of the refrigerant not only changes the flow direction of the refrigerant by the solenoid valve so that the refrigerant enters the evaporator immediately without passing through the expansion valve but also does not need to lower the temperature of the condenser so that the operation of the pump is stopped .

The operation of the water-cooled ice maker will be described in more detail. When the ice maker is operated after the water supply valve (not shown) is opened to supply water to the ice maker through the ice- Pressure refrigerant gas which is evaporated in the condenser is compressed and supplied at a high temperature and a high pressure so that the condensing operation is performed well in the condenser. The refrigerant gas is radiated from the condenser and heat exchanged into high-pressure liquid refrigerant, Pressure state, and is supplied to the evaporator. The refrigerant supplied to the evaporator is converted into a low-pressure gas while absorbing the heat, and is then sent to the compressor. In this process, the ambient temperature is lowered due to the evaporator that absorbs the ambient heat. The changing ice is produced.

In this way, a portion of the ice surface is melted through the ice-making process, and the ice is easily detached from the ice-making part, and the thus-removed ice is transferred out of the ice-making part through the conveying member (not shown).

In this process, the high-temperature and high-pressure refrigerant gas discharged from the compressor is directly supplied to the evaporator by the solenoid valve in a state in which heat exchange is not sufficiently caused in the condenser, and the refrigerant gas of high temperature and high pressure supplied to the evaporator And the ice is easily detached.

In this way, it is possible to efficiently obtain ice by controlling the operation of the solenoid valve and the heat exchange operation in the condenser during the ice-making process and the ice-making process. In order to continuously obtain ice, the ice- Of the total volume.

At this time, the discharge control valve 160 provided in the ice-making water discharge pipe is opened to dissolve the molten water and the remaining ice-making water left in the ice-making water discharge pipe through the ice- Enter the tank.

Since the water entering the water tank is cold water which melts the ice surface when it is iceing, the temperature of the water is lowered when it is mixed with the water in the water tank, and since the temperature of the lowered water causes the heat exchange with the condenser during the ice making, Performance can be improved.

In addition, a separate cooling water circulating device is provided in order to lower the temperature of the refrigerant when the heat exchanging with the condenser occurs more easily during the deicing, so that heat exchange with the condenser occurs.

The cooling water circulation apparatus comprises a water tank for storing cooling water, a cooling water pump for circulating the cooling water, and a heat exchange unit for lowering the temperature of the high temperature cooling water that has been heat-exchanged in the condenser.

As described above, when the water tank is moved to the stored water, water generated from the ice maker flows into the water tank, and the amount of water is continuously increased. Therefore, an overflow water pipe is installed at a certain upper part of the water tank, When the tank is cold, it is discharged to the outside.

In addition to storing a certain amount of water in the water tank, the discharge of water out of the water tank also has the effect of preventing the decay of water by allowing a small amount of water to be continuously supplied to the water tank,

In addition, a separate exhaust fan is created in the upper part of the water tank to discharge the water vapor generated in the water tank, thereby making it possible to adjust the humidity in the place where the cooling water circulation device is installed.

On the other hand, since the cooling water having heat exchange in the condenser is sent to the condenser by lowering the temperature in the heat exchanging part, heat exchange with the condenser can be smoothly performed. Therefore, in order to lower the temperature in the heat exchanging part, And further comprises a blower fan separate from the temperature sensor at an inlet side of the heat exchanger to which the cooling water flows. When the temperature sensed by the temperature sensor is equal to or higher than a preset temperature, the blower fan is operated, Allow coolant temperature to drop well.

It is not necessary to lower the refrigerant temperature of the condenser at the time of ice storage so that the operation of the cooling water pump is stopped to stop the circulation of the cooling water as well as the flow of the refrigerant in the cooling system, The hot gas is supplied to the evaporator so that the surface of the ice melts easily so that the ice can be easily removed.

On the other hand, since the ambient temperature is relatively high due to the seasonal factors, the cooling water temperature is high during the ice making operation, the heat exchange with the condenser is not performed well, and the ice making efficiency may be reduced. Therefore, when the temperature sensed by the temperature sensor is higher than the set temperature The control valve is opened so that a part of the deicing water flows into the water tank to lower the temperature of the cooling water or the discharge control valve is periodically opened at a time interval set by the timer (not shown) so that a part of the deicing water flows into the water tank It is possible.

Since the cooling water circulation device and the discharge control valve can control the icing water entering the water tank connected to the icing water discharge pipe in the middle of the icing water discharge pipe and the overflow drain pipe, the efficiency of the heat exchanging of the condenser is improved, There is an advantage that water corruption can be prevented.

In addition, the operation of the cooling water circulating device and the cooling system is appropriately controlled during the icing and icing operations so as to complement each other, thereby reducing the consumption of energy, thereby effectively operating the ice maker, thereby saving energy.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Accordingly, the scope of the present invention should not be limited to the above-described embodiments, but should be construed according to the appended claims.

1, 100: Ice-maker
10, 110:
21, 121: compressor 22, 122: condenser 23, 123: expansion valve
24, 124: evaporator 25, 125: filter dryer 26, 126: solenoid valve
31: iced water inlet 32: iced water outlet
40, 140: cooling section
41: cooling water inlet 42: cooling water outlet
43, 143: heat exchanger 44, 144: water tank
45, 145: Pump 46, 146: Temperature sensor
50, 150:
131: ice water supply pipe 132: ice water discharge pipe
142: overflow pipe
160: Exhaust control valve

Claims (6)

A condensing unit, an expansion valve, and an evaporator, a freezing unit having a de-iced water supply pipe and a de-iced water discharge pipe for supplying and discharging de-icing water using a cooling system, A water-cooled type ice maker comprising a pump for supplying cooling water from a water tank to a cooling section, a cooling water circulation device including heat of cooling water flowing out of the cooling section and connected to a water tank, and a control section for controlling them,
The ice-making water discharge pipe is connected to the water tank,
A discharge control valve is provided in the middle of the ice-making water discharge pipe,
Wherein a water overflow drain pipe is connected to a predetermined upper portion of the water tank.
The method according to claim 1,
Wherein a temperature sensor is mounted on the cooling water inflow portion of the heat exchanger, and a blowing fan is further provided.
3. The method of claim 2,
Wherein the water tank is equipped with an exhaust fan.
3. The method of claim 2,
Wherein the control unit opens the discharge control valve at a time interval that is sensed by the temperature sensor at a set temperature or at a time interval set by the timer even when the ice-making is being performed.
4. The method according to any one of claims 1 to 3,
The controller controls the cooling water pump of the cooling water circulating device to flow through the compressor, the condenser, the expansion valve, and the evaporator during the ice making, and allows the refrigerant to flow through the compressor, the condenser and the evaporator during the ice- So that the cooling water pump of the apparatus is stopped.
5. The method of claim 4,
Wherein the cooling water circulating device is separately provided so as to be detachably attached to the ice-making part.

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