KR102051672B1 - Ice making system and controlling method thereof - Google Patents

Abstract

When making cold water by ice, ice water tank prevents water overflow and supplies relatively low temperature water to ice making unit to make ice making easily, and the ice making system which independently supplies cold water and manufactures cold water using ice and its The control method is disclosed.
Ice making system according to an embodiment of the present invention the water storage tank 200; An ice making unit 300 configured to manufacture ice I from water supplied from the water storage tank 200 and disposed below the water storage tank 200; The water supplied from the water storage tank 200 is stored and the ice (I) or cooled cooling water produced in the ice making unit 300 is supplied to cool the stored water, and the lower side of the ice making unit 300 is cooled. A cold water tank 400 disposed; And a circulation part 600 configured to supply the water cooled in the cold water tank 400 to the water storage tank 200, wherein the water storage tank 200 is cooled in the cold water tank 400. The partition member 210 is provided to distinguish the circulation area S1 to which water is supplied and the storage area S2 partitioned therefrom, and the cooled water accommodated in the circulation area S1 of the water storage tank 200. It may be configured to be supplied to the ice making unit 300.

Description

ICE MAKING SYSTEM AND CONTROLLING METHOD THEREOF

The present invention relates to an ice making system for manufacturing ice and a control method thereof, and more particularly, to prevent water from overflowing a cold water tank during the production of cold water by ice, and to supply ice at a relatively low temperature to the ice making unit. The present invention relates to an ice making system and a method of controlling the same, which are easily carried out and which independently supply ice and manufacture cold water using ice.

The ice making system manufactures ice, which includes an ice making unit for making ice.

For example, Korean Patent Application No. 2005-0099663, which discloses an ice making system 10 including an ice making unit 30 for manufacturing ice I, as shown in FIG. 12. have.

The ice making unit 30 includes an immersion member 31 connected to an evaporator 33 in which a refrigerant flows, as shown in FIG. 12, and water so that the immersion member 31 is immersed in ice (I). ) And a tray member 32 that rotates between an ice making position where the ice sheet is generated and a ice removing position where the ice I is separated from the immersion member 31.

Accordingly, when the coolant flows in the evaporator 33 by driving the refrigerating cycle while the water is contained in the tray member 32 and the immersion member 31 is locked, ice I is generated in the immersion member 31. do. When the ice I having a predetermined size is generated, the ice I formed on the immersion member 31 is immersed in the immersion member 31 by rotating the tray member 32 to the freezing position and allowing the immersion member 31 to be heated. ).

On the other hand, the conventional ice making system 10 may supply the ice (I) produced by the ice making unit 30 to the cold water tank 40 to cool the water stored in the cold water tank 40 to produce cold water. To this end, the grill 70 is rotatably connected to the tray member 32 as shown in FIG. In addition, a slide plate 80 having a groove 81 is formed below the ice making unit 30, and a cold water tank 40 is provided below the slide plate 80. In addition, as shown in the water storage tank 20 and the cold water tank 40, the water supply pipe 24 provided with an on-off valve 25 is connected. Therefore, when the open / close valve 25 is opened, the water of the water storage tank 25 is supplied to the cold water tank 40 through the water supply pipe 24.

With this configuration, as described above, the relatively low temperature remaining in the tray member 32 at the freezing position of the tray member 32 is transferred to the cold water tank 40 through the groove 81 of the slide plate 80. Supplied. Accordingly, the water stored in the cold water tank 40 can be cooled.

In addition, the ice I separated from the immersion member 30 falls on the slide plate 80. When the tray member 32 rotates to the ice making position in this state, the grill 70 connected to the tray member 32 pushes the ice I dropped on the slide plate 80 toward the front of the slide plate 80. do.

Accordingly, some of the ice I is supplied to the cold water tank 40 through the groove 81 of the slide plate 80 to cool the water stored in the cold water tank 40. Then, the remaining ice (I) is supplied to the ice reservoir 50 through the millier outlet (81a) to the front of the slide plate 80 by the grill 70 is stored.

By such a configuration, for example, even in a state where ice I is in the ice reservoir 50, ice I is produced in the ice making unit 30 to cool the water stored in the cold water tank 40, There is a problem that must be supplied to both the cold water tank 40 and the ice storage 50. In addition, even if the water stored in the cold water tank 40 is at an appropriate temperature, that is, even if the ice reservoir 50 is not enough ice (I) even if cooled to a predetermined desired temperature, the ice (I) in the ice making unit 30 There is a problem that must be supplied to supply both the cold water tank 40 and the ice storage (50). That is, there is a problem that the supply of ice and cold water production using ice is not made independently.

On the other hand, in such a configuration, the water stored in the cold water tank 40 and cooled as described above may be supplied to the ice making unit 30. To this end, as shown in FIG. 12, one side of the circulation pipe 61 is connected to the cold water tank 40, and the other side of the circulation pipe 61 may supply water to the tray member 32 of the ice making unit 30. It can be provided at a position.

However, when the water level of the cold water tank 40 becomes the water replenishment water level, that is, the low water level while the water is supplied to the tray member 32, the water storage tank 20 to the cold water tank 40 through the water supply pipe 24 Water is supplied. As a result, the cold water tank 40 is at full water level. As described above, when the ice I is formed in the immersion member 31 and defrosted, the residual water and the ice I contained in the tray member 32 are supplied to the cold water tank 40. There is a problem that water can overflow.

In addition, the overflow of the cold water tank 40 may occur when a large amount of ice I is supplied to the cold water tank 40 and stored, and the ice I stored in the cold water tank 20 melts.

The present invention is made by recognizing at least one of the needs or problems occurring in the conventional ice making system as described above.

One aspect of the present invention is to supply the water of the cold water tank to the water storage tank while preventing the water overflow of the cold water tank while producing cold water by supplying the ice or ice water produced in the ice making unit to the cold water tank. It is.

Another aspect of the object of the present invention is to supply water having a relatively low temperature to the ice making unit to make ice making easier.

Another aspect of the object of the present invention is to supply the ice to the ice storage and cold water production using the ice to be made independently.

Another aspect of the object of the present invention is to make ice freely easy to ice and to avoid noise during the freezing.

An ice making system related to an embodiment for realizing at least one of the above problems may include the following features.

The present invention basically supplies the ice or cooled cooling water produced in the ice making unit to a cold water tank to cool the water stored in the cold water tank, and the relatively temperature cooled in the ice making unit for the production of ice or separately from the production of ice. The low coolant is supplied to the cold water tank and the water stored in the cold water tank including the relatively low temperature coolant is supplied to the water storage tank and then to the ice making unit.

As an aspect of the present invention, a water storage tank into which water is introduced and stored; An ice making unit configured to produce ice from water supplied from the water storage tank, the ice making unit disposed below the water storage tank; A cold water tank in which water supplied from the water storage tank is stored, and ice or cooled cooling water manufactured in the ice making unit is supplied to cool the stored water, and a cold water tank disposed below the ice making unit; And a circulation unit configured to supply water cooled in the cold water tank to the water storage tank.
The water storage tank is provided with a partition member for distinguishing between the circulation area and the storage area is supplied to the water cooled in the cold water tank,
Provided is an ice making system configured to supply the cooled water contained in the circulation region of the water storage tank to the ice making unit.

In this case, the circulation unit circulation pipe connected to the cold water tank and the water storage tank; And a pump provided in the circulation pipe; It may include.

In addition, the circulation pipe may be connected to the water storage tank at least a part through the cold water tank.

Then, the cooling water cooled in the ice making unit can be supplied to the cold water tank.

In addition, the water including the cooling water supplied to the cold water tank may be supplied to the circulation region of the water storage tank through the circulation.

And, one side of the circulation pipe included in the circulation portion may be connected to the cold water tank of the side to which the cooling water is supplied.

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The other side of the circulation pipe is connected to the circulation zone of the water storage tank, and one side of the ice-making water supply pipe is connected to the circulation zone of the water storage tank for supplying water from the water storage tank to the ice storage unit, and the other side of the circulation pipe. Can be connected to.

In addition, the other side of the circulation pipe and one side of the water supply pipe for ice making may be connected to the lower portion of the water storage tank.

And, at the same time as the supply of the water containing the cooling water from the cold water tank through the circulation pipe to the water storage tank or after a predetermined time, the supply of water containing the cooling water from the water storage tank through the water supply pipe for ice making to the ice making unit is Control unit to be made; It may further include.

In addition, the control unit is connected to the pump provided in the circulation pipe and the on-off valve provided in the ice-making water supply pipe, the control unit drives the pump and at the same time open or close the valve or drive the pump after a predetermined time after the opening and closing valve Can open

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In addition, the partition member may be provided in the water storage tank so that water flows between the circulation region and the storage region.

And, the upper end of the partition member may be located lower than the middle water level and higher than the low water level of the water storage tank.

In addition, one or more flow holes may be formed in the partition member.

In addition, the cold water tank may be provided with a partition member for distinguishing a circulation region in which water including cooling water exists and a storage region partitioned therefrom.

In addition, the partition member may be provided in the cold water tank so that water flows between the circulation region and the storage region.

The lower end of the partition member may be spaced apart from the bottom of the cold water tank by a predetermined interval.

In addition, one or more flow holes may be formed in the partition member.

The ice making unit may include an evaporator through which a refrigerant flows.

In addition, the ice making unit may include a thermoelectric module.

In addition, one side of the water supply pipe with an on-off valve is connected to the water storage tank for supply of water from the water storage tank to the cold water tank and the other side may be connected to the cold water tank.

In addition, the cold water tank may be provided with a full water level sensor.

In addition, when the water level of the cold water tank is lower than the high water level in the control unit connected to the high water level sensor, the control unit opens the on-off valve to supply the water of the water storage tank to the cold water tank through the water supply pipe to maintain the high water level of the cold water tank. You can do that.

And, the ice storage for supplying and storing the ice produced in the ice making unit; It may further include.

In addition, the cold water tank is provided with a first guide member for guiding the ice produced in the ice making unit to the cold water tank, and a second guide for guiding the ice to the ice reservoir in association with the first guide member between the cold water tank and the ice reservoir. The member may be rotatably provided.

In addition, a second guide member may be rotatably provided between the cold water tank and the ice reservoir to supply the ice produced in the ice making unit to the cold water tank or to guide the ice to the ice reservoir.

In addition, the water storage tank may be supplied with water from the filtration unit including at least one water purification filter for filtering the introduced water.

In another aspect, the present invention comprises an ice making unit configured to produce ice with water supplied from a water storage tank, and a cold water tank for supplying ice or cooled cooling water produced in the ice making unit to cool the stored water. A control method of an ice making system, comprising: determining whether a level of the cold water tank corresponds to a predetermined level; The water supply step of the water storage tank for supplying the water contained in the cold water tank to the water storage tank when the water level of the cold water tank is more than a predetermined level: And to the ice making unit for supplying the water contained in the water storage tank to the ice making unit Including; water supply step;
The water storage tank is provided with a partition member for distinguishing between the circulation area and the storage area is supplied to the water cooled in the cold water tank,
The water supply step to the ice making unit provides a control method of the ice making system configured to supply the cooled water contained in the circulation region of the water storage tank to the ice making unit.

Preferably, the water supply step of the water storage tank may be performed when the water level of the cold water tank becomes a full water level.

Also preferably, the water supply step of the water storage tank may be performed by driving a pump provided in the flow path between the cold water tank and the water storage tank.

More preferably, the water supply step to the ice making unit may be performed at the same time as the water supply step to the water storage tank, or after a predetermined time elapses after the water supply step to the water storage tank is performed. have.

Preferably, the water supply step to the ice making unit may be performed by opening and closing the valve provided in the flow path between the water storage tank and the ice making unit.

As described above, according to an embodiment of the present invention, the cold water is supplied to the cold water tank by supplying the ice produced in the ice making unit or the cooling water cooled in the ice making unit, and the water of the cold water tank is supplied to the ice making unit. It can be supplied to the water storage tank to be supplied to prevent the water overflow of the cold water tank.

In addition, according to an embodiment of the present invention, by supplying water having a relatively low temperature to the ice making unit, ice making may be easily performed, and thus ice making efficiency may be improved.

In addition, according to an embodiment of the present invention, the supply of ice to the ice storage and the cold water production using the ice through the second guide member can be made independently.

In addition, according to an embodiment of the present invention, by using a heating unit, ice can be easily defrosted and noise can not be generated during defrosting.

1 is a view showing an embodiment of an ice making system according to the present invention.
2 is a view showing another embodiment of an ice making system according to the present invention.
3 is a view showing another embodiment of an ice making system according to the present invention.
4 is a view showing another embodiment of an ice making system according to the present invention.
5 is a view showing another embodiment of an ice making system according to the present invention.
6 to 11 are views showing the operation of the embodiment of the ice making system according to the present invention shown in FIG.
12 is a view showing a conventional ice making system.

In order to help the understanding of the features of the present invention as described above, it will be described in more detail with respect to the ice making system and its control method according to an embodiment of the present invention.

Hereinafter, the described embodiments will be described based on the embodiments best suited for understanding the technical features of the present invention, and the technical features of the present invention are not limited by the described embodiments. It is intended to illustrate that the invention can be implemented as described embodiments. Accordingly, the present invention may be modified in various ways within the technical scope of the present invention through the embodiments described below, and such modified embodiments fall within the technical scope of the present invention. And, hereinafter, in order to help the understanding of the embodiments described, in the reference numerals described in the accompanying drawings, among the components that will have the same function in each embodiment is represented by the same or an extension line number.

Embodiments related to the present invention basically cool the water stored in the cold water tank by supplying the ice or cooled cooling water produced in the ice making unit to the cold water tank, and for the production of ice or cooling in the ice making unit separately from the production of ice. The low temperature cooling water is supplied to the cold water tank, and the water stored in the cold water tank including the relatively low temperature cooling water is supplied to the water storage tank and then to the ice making unit.

1 to 5, the ice making system 100 according to the present invention includes a water storage tank 200, an ice making unit 300, a cold water tank 400, and a circulation part 600. Can be configured.

As shown in FIG. 6, the water storage tank 200 may be stored with water introduced therein. To this end, the water storage tank 200 may be connected to the inlet pipe 220 having the on-off valve 230 as shown in the embodiment shown in Figures 1 to 5. In addition, the inlet pipe 220 may be connected to a water supply source (not shown). The water supply source is, for example, if the ice making system 100 according to the present invention is provided in a water purifier (not shown), it is provided with a water purifier to filter the incoming water and includes a filtration part (not shown) including one or more water filters (not shown). May not be used). In this case, when the on-off valve 230 provided in the inlet pipe 220 is opened, water filtered by the purified water filter may be introduced into and stored in the water storage tank 200 through the inlet pipe 220. However, the water supply source is not limited thereto, and any water well-known may be used as long as it is connected to the water storage tank 200 to supply water to the water storage tank 200. On the other hand, the water storage tank 200 has a suitable size so that the water contained in the cold water tank 400 can be supplied when the water level of the cold water tank 400 is above a certain level as described below.

In addition, the ice making unit 300 may be configured to manufacture ice I from water supplied from the water storage tank 200.

In order to supply water from the water storage tank 200 to the ice making unit 300, one side of the ice making water supply pipe 260 equipped with the opening / closing valve 270 as shown in FIGS. 1 to 5 is water. It may be connected to the storage tank 200 and the other side may be connected to the ice making unit 300. Accordingly, when the on-off valve 250 is opened, as shown in FIG. 6, the water stored in the water storage tank 200 is transferred to the ice making unit 300 through the ice making water supply pipe 260, for example, ice making in the illustrated embodiment. It may be supplied to the tray member 320 of the unit 300.

Such water supply to the ice making unit 300 may be performed at a time when the ice making unit 300 needs to be driven.

In order to manufacture the ice I, the ice making unit 300 may include an evaporator 330 included in a known refrigeration cycle as shown in FIGS. 1 to 3 and 5 to which a refrigerant flows. .

In this case, the ice making unit 300 may include one or more immersion members 310 and tray members 320 in addition to the evaporator 330 described above as shown in FIGS. 1 to 3 and 5.

As shown in FIG. 7, ice I may be generated in one or more immersion members 310. To this end, the immersion member 310 may be connected to the above-described evaporator 330 as in the embodiment shown in FIGS. 1 to 3 and 5. Accordingly, as shown in FIG. 7, when the coolant flows through the evaporator 330 while the immersion member 310 is immersed in the water contained in the ice making tray 320, the coolant also flows in the immersion member 310. Flow. In addition, ice (I) may be generated in the immersion member 310 as shown in FIG. 2 by cooling the water contained in the ice making tray 320.

On the other hand, in order to defrost the ice I formed in the immersion member 310, it is necessary to heat the immersion member 310. To this end, according to an embodiment of the present invention may be configured to supply a hot refrigerant to the evaporator 330 using a refrigeration cycle. However, when a hot refrigerant flows through the evaporator 330, a solenoid valve (not shown) must be installed between a flow path for supplying a high temperature refrigerant to the evaporator 330 and a flow path for supplying a low temperature refrigerant. Not only does the noise occur when opening and closing, there may be a problem that a failure occurs in the solenoid valve when the opening and closing operation is performed for a long time. Such a solenoid valve is installed by welding to a tube through which the refrigerant flows to prevent the leakage of the refrigerant. However, the repair of the failed solenoid valve requires a cut of the tube provided with the solenoid valve, which may cause a problem that is not easy to repair. have.

In order to solve the problems caused by the use of the solenoid valve, the present invention may be provided with a heating unit 700 connected to the evaporator 330, as shown in Figures 1 to 3 and 5. Accordingly, as shown in FIGS. 8 and 9, when the ice making tray 320 is rotated to the freezing position, the heating unit 700 is driven, and the immersion member 310 may be heated. As a result, as illustrated in FIGS. 8 and 9, the ice I generated in the immersion member 310 may be separated from the immersion member 310. As described above, when the ice I is separated from the immersion member 310, the ice I may move to the cold water tank 400 or the ice storage 500 to be described later as shown in FIG. 9.

The heating unit 700 is not particularly limited, and may be any known as long as it is provided in the evaporator 330 to heat the immersion member 310 so that the ice I is separated from the immersion member 310. .

Therefore, when the heating unit 700 is used, the ice I may be defrosted more easily than the ice I is defrosted by the hot refrigerant. In addition, since the solenoid valve is not provided, noise is not generated during the defrosting, and it is preferable because the repair / exchange is easy.

However, the present invention is more preferable to use a separate heating unit 700, and does not exclude the deicing of the ice (I) by the hot refrigerant.

In addition, in order to manufacture the ice (I), the ice making unit 300 may include a thermoelectric module 330 ′ as shown in FIG. 4. In this case, the ice making unit 300 may include one or more immersion members 310 and a tray member 320 in addition to the above-mentioned thermoelectric module 330 ′ as shown in FIG. 4.

The immersion member 310 may be connected to the thermoelectric module 330 ′ as shown in FIG. 4. In this case, as illustrated, the immersion member 310 and the thermoelectric module 330 'may be connected by a cold sink 340'. In addition, a heat sink 350 ′ having a fan 360 ′ may be connected to the thermoelectric module 330 ′.

By this configuration, when the thermoelectric module 330 'is driven while the immersion member 310 is immersed in the water contained in the ice making tray 320, the cold sink 340' from the immersion member 310, the thermoelectric module 330 ') And the heat sink 350' may be sequentially heat transfer. Accordingly, the water contained in the ice making tray 320 in which the immersion member 310 is cooled and the immersion member 310 is cooled may generate ice I in the immersion member 310.

When the thermoelectric module 330 'is driven in reverse, that is, when the power in the opposite direction to generate ice I in the immersion member 310 is applied to the thermoelectric module 330', heat is transferred to the immersion member 310. This can be done. As a result, the immersion member 310 may be heated to separate the ice I generated in the immersion member 310.

Therefore, defrosting can be easily performed without providing the heating unit 700, and noise can be generated during the defrosting.

The tray member 320 may rotate between the ice making positions shown in FIGS. 6 and 7 and the ice removing positions shown in FIGS. 8 and 9. In the ice making position, the tray member 320 may contain water so that the immersion member 310 is locked. For example, as described above and illustrated in FIG. 6, the on / off valve 270 provided in the ice making water supply pipe 260 is opened so that the water in the water storage tank 200 passes through the tray member 320 through the ice making water supply pipe 260. Can be supplied. As described above and illustrated in FIG. 7, when a cool refrigerant flows to the evaporator 330 or power is applied to the thermoelectric module 330 ′, ice I may be generated in the immersion member 310. .

The ice I may be separated from the immersion member 310 in the freezing position. For example, in the defrosting position as shown in FIGS. 8 and 9, when the heating unit 700 is heated or the power in the opposite direction is applied to the thermoelectric module 330 ′ as described above, ice from the immersion member 310 (I) can be separated. That is, the ice I may be defrosted.

As shown in FIGS. 8 and 9, the defrosting position of the tray member 320 is cooled by the immersion member 310 in which ice I is generated and left in the tray member 320 or immersed in the tray member 320. The relatively low temperature coolant may be a position to be supplied to the cold water tank (400). Accordingly, relatively low temperature cooling water contained in the tray member 320 may be supplied to the cold water tank 400.

Meanwhile, the configuration of the ice making unit 300 is not limited to the immersion type including the immersion member 310 connected to the evaporator 330 or the thermoelectric module 330 'described above. The ice making unit 300 may be, for example, a spray type for spraying water into an ice making groove (not shown) formed in an ice making frame (not shown) to generate ice in the ice making groove. In addition, the ice making unit 300 may be a water flow type to allow the water to flow in the ice making groove of the ice making frame to generate ice in the ice making groove. The configuration of the ice making unit 300 is not limited to the above-described configuration, and any configuration known in the art may be used as long as it is configured to manufacture ice I from water supplied from the water storage tank 200.

The cold water tank 400 may store water supplied from the water storage tank 200 as shown in FIGS. 6, 10, and 11. To this end, as shown in the embodiment shown in Figures 1 to 5, one side of the water supply pipe 240 provided with the on-off valve 250 may be connected to the water storage tank 200. And, the other side of the water supply pipe 240 may be linked to the cold water tank (400). That is, the other side of the water supply pipe 240 as shown in the embodiment may be located adjacent to the cold water tank (400).

Therefore, when the on-off valve 250 is opened because the water supply to the cold water tank 400 is required, the water stored in the water storage tank 200 is connected to the water supply pipe 240 as shown in FIGS. 6, 10, and 11. It may be supplied to the cold water tank 400 through and stored in the cold water tank (400).

The cold water tank 400 may be provided with a high water level sensor 460 as shown in the embodiment shown in FIG. Through the high water level sensor 460, it is possible to know whether the water level of the cold water tank 400 has reached high water level.

At this time, if it is detected that the water level of the cold water tank 400 is lower than the high water level in the control unit (not shown) connected to the high water level sensor 460 (if it is detected that the high water level is not), the control unit in FIGS. 6 and 10 and 11 As shown in the drawing, the on / off valve 250 may be opened. As a result, water of the water storage tank 200 may be supplied to the cold water tank 400 through the water supply pipe 240. And, accordingly, the water level of the cold water tank 400 can be maintained to the full water level.

As such, when the water level of the cold water tank 400 maintains the full water level, the height difference between the water level of the cold water tank 400 and the water discharge pipe 440 may be constant at all times. Accordingly, when the water stored in the cold water tank 400 is discharged to the outside through the water discharge pipe 440 is opened, as shown in Figure 11, the water discharge pipe 440 is always a certain amount of water discharge pipe 440 Can be discharged to the outside through.

In addition, if the water level of the cold water tank 400 maintains the full water level, the user can receive a certain amount of cold water continuously when the user takes cold water, and thus the cold water extraction flow rate as the water level of the cold water tank 400 is reduced. There is an advantage that the problem of reduction is solved.

However, the method of maintaining the water level of the cold water tank 400 in the present invention is not limited to the case of maintaining the full water level as described above, as used in a typical cold water tank, the water of the water through the water discharge pipe 440 When the water level of the cold water tank 400 is lowered through extraction, such as water replenishment level, the on / off valve 250 is opened to supply water from the water storage tank 200 to the cold water tank 400, and when the water level becomes full It is also possible to close the on-off valve 250 so that the water supply from the storage tank 200 to the cold water tank 400 is blocked.

The cold water tank 400 may be supplied with ice (I) manufactured in the ice making unit 300 as shown in FIG. 8 or cooling water cooled in the ice making unit 300 as shown in FIGS. 8 and 9. have. Accordingly, water stored in the cold water tank 400 may be cooled. That is, the cold water tank 400 is supplied with ice and / or water from the ice making unit 300 to cool the water contained in the cold water tank 400.

Meanwhile, when ice and / or water is supplied to the cold water tank 400, the water level of the cold water tank 400 is increased. In this case, the water accommodated in the cold water tank 400 is circulated through the circulation unit 600 as described below. It is supplied to the water storage tank 200.

As illustrated in FIGS. 1 to 5, in order to supply the ice I to the cold water tank 400, the cold water tank 400 may be provided with a first guide member 420. As illustrated in FIG. 8, the ice I produced in the ice making unit 300 may be guided to the cold water tank 400 by the first guide member 420. In the illustrated embodiment, the ice I separated from the immersion member 310 at the freezing position of the tray member 320 may be guided to the cold water tank 400 by the first guide member 420.

That is, as illustrated in FIG. 8, the ice I separated from the immersion member 310 falls into the first guide member 420 and moves along the first guide member 420, and then the cold water tank 400. It may be stored in the cold water tank 400 by moving into the cold water tank 400 through the interval between the first guide member 420.

The ice making system 100 according to the present invention may further include an ice storage 500 as shown in the embodiment shown in FIGS. 1 to 5.

As illustrated in FIG. 9, the ice storage 500 may be supplied with ice (I) manufactured in the ice making unit 300. To this end, a second guide member 430 may be rotatably provided between the cold water tank 400 and the ice storage 500. As illustrated in FIG. 9, the second guide member 430 may guide the ice I to the ice storage 500 in association with the first guide member 420 described above.

That is, when guiding the ice I to the cold water tank 400 as shown in FIG. 8, the second guide member 430 has a gap between the cold water tank 400 and the first guide member 410. It will rotate to the position where it is. And, as shown in Figure 9 when the ice (I) to guide the ice reservoir 500, the second guide member 430 is the gap between the cold water tank 400 and the first guide member 410 The blocking will rotate to the position.

Accordingly, as shown in FIG. 9, the ice I separated from the immersion member 310 falls into the first guide member 420, and the first guide member 420 and the second guide member 430 are dropped. Follow the ice storage (500). Then, it is dropped into the ice reservoir 500 and stored in the ice reservoir 500.

Meanwhile, even when the second guide member 430 is rotatably provided between the cold water tank 400 and the ice storage 500 without the first guide member 410 provided in the cold water tank 400, the ice making unit 300 Ice (I) produced in the) may be supplied to the cold water tank 400 or guide the ice (I) to the ice storage (500).

That is, in a state where the first guide member 410 is not provided in the cold water tank 400, the ice I manufactured in the ice making unit 300 at the rotational position shown in FIG. 9 by the second guide member 430. It may be of sufficient length to guide it to the ice reservoir 500. Accordingly, the ice I produced in the ice making unit 300 may be guided to the ice storage 500. Also, in this configuration, when the second guide member 430 rotates to the position shown in FIG. 8, since the upper portion of the cold water tank 400 is opened, the ice I manufactured in the ice making unit 300 is It may be supplied to the cold water tank (400).

By such a configuration, the supply of ice (I) to the ice reservoir 500 and the cold water production using the ice (I) for supplying the ice (I) to the cold water tank 400 to produce cold water can be made independently.

On the other hand, the ice stored in the ice storage 500 is melted over time, the water melted in this way can be drained to the outside through a separate pipe, the water storage tank through the circulation unit 600 to be described later The configuration supplied to 200 is also possible.

The circulation unit 600 may be configured to supply water stored in the cold water tank 400 to the water storage tank 200 as shown in FIG. 10.

That is, when the water level of the cold water tank 400 is increased due to ice and / or water supplied from the ice making unit 300 to the cold water tank 400 for cooling the water contained in the cold water tank 400, the cold water tank 400 In order to prevent the overflow of water, the circulation unit 600 is configured to supply the water stored in the cold water tank 400 to the water storage tank 200 when the water level of the cold water tank 400 is above a certain level. At this time, the water supply to the water storage tank 200 through the circulation unit 600 may be performed when the full water level of the cold water tank 400 is detected, but is not limited thereto.

For example, the high water level, which is a standard of water supply from the cold water tank 400 to the water storage tank 200 through the circulation unit 600, may be set to be the same as the high water level that blocks the water supply to the cold water tank 400. In addition, it is possible to set higher than the full water level to block the water supply to the cold water tank (400).

The circulation unit 600 may include a circulation pipe 610 and a pump 620 as shown in the embodiment shown in Figures 1 to 5. The circulation pipe 610 may be connected to the cold water tank 400 and the water storage tank 200 as shown in the illustrated embodiment. In addition, the pump 620 may be provided in the circulation pipe 610. Accordingly, when the pump 620 is driven, water stored in the cold water tank 400 may be supplied to the water storage tank 200 through the circulation pipe 610 as shown in FIG. 10.

On the other hand, Figures 1 to 11 illustrate that only the water stored in the cold water tank 400 is supplied to the water storage tank 200, the circulation unit 600 is not only the water stored in the cold water tank 400, but also ice Ice melted water generated in the reservoir 500 may also be configured to supply the water storage tank 200. In this case, the circulation part 600 forms a flow path to introduce the water generated in the ice reservoir 500 and the water stored in the cold water tank 400 into the pump 620, and drives the pump 620. The water in the ice reservoir 500 and the cold water tank 400 may be supplied to the water storage tank 200. Alternatively, the circulation unit 600 may be provided with a separate pump or a circulation pipe to supply the ice melted water generated in the ice reservoir 500 to the water storage tank 200.

In addition, at least a portion of the circulation pipe 610 may be connected to the water storage tank 200 by passing through the cold water tank 400 as shown in FIG. 5. Accordingly, the length of the circulation pipe 610 for connecting the cold water tank 400 and the water storage tank 200 may be shortened. As a result, the rate of temperature rise of the water flowing through the circulation pipe 610 may be lowered.

In addition, even if the temperature of the water flowing through the circulation pipe 610 is increased, the water flowing through the circulation pipe 610 may be cooled by the water stored in the cold water tank 400. Accordingly, the temperature of the water flowing through the circulation pipe 610 may not be increased.

That is, even if a separate heat insulating member is not provided in the circulation pipe 610, as described later, the water having a relatively low temperature supplied to the cold water tank 400 may not increase its temperature through the circulation pipe 610. It may be to be supplied to the water storage tank 200. And, condensation water may not form in the circulation pipe 610.

With this configuration, since water close to 0 ° C. may be supplied to the ice making unit 300 as described below, the ice I may be easily manufactured in the ice making unit 300. In addition, the manufacturing time of the ice (I) can be shortened, and the ice (I) can be manufactured with relatively little energy.

1, 3, 4, and 5, the circulation pipe 610 may be provided with a check valve 630. As a result, when the driving of the pump 620 is stopped, the water of the water storage tank 200 may be prevented from flowing back to the cold water tank 400 through the circulation pipe 610 and the pump 620.

And, if there is no check valve 630 in the circulation pipe 610 as shown in the embodiment shown in Figure 2, the other side of the circulation pipe 610 is beyond the wall of the water storage tank 200, the water storage tank 200 Can be located inside (lower). In addition, an air hole 611 may be formed at the other side of the circulation tube 610 as shown in FIG. 2. Accordingly, even when there is no check valve 630, when the driving of the pump 620 is stopped, the water of the water storage tank 200 flows back to the cold water tank 400 through the circulation pipe 610 and the pump 620. Can be prevented.

Meanwhile, as shown in FIGS. 8 and 9, the cooling water cooled in the ice making unit 300 may be supplied to the cold water tank 400. That is, as illustrated and described above, ice (I) is generated and remaining in the tray member (320) or the immersion member (310) is immersed separately from the manufacture of the ice (I) soaked in the cooled tray member (320). Cooling water, such as water, may be supplied to the cold water tank 400 at a defrosting position. The cooling water may be close to 0 ° C because ice (I) is generated and left, or the immersion member 310 is immersed and cooled. Therefore, the temperature of the cooling water may be relatively lower than the temperature of the water stored in the cold water tank 400. As a result, the temperature of the water stored in the cold water tank 400 may be lowered.

However, a configuration in which the coolant having a relatively low temperature is supplied to the cold water tank 400 that is manufactured and left or cooled in the ice making unit 300 is not limited to the illustrated embodiment, and the ice making unit 300 ) And a cold or low temperature cooling water, which is left or cooled, is produced and supplied to the cold water tank 400 from the ice making unit 300 through a pipe (not shown) connected to the cold water tank 400). Any known structure may be used.

In addition, as illustrated in FIG. 10, water including cooling water having a relatively low temperature supplied to the cold water tank 400 may be supplied to the water storage tank 200 through the circulation unit 600. Accordingly, the temperature of the water storage tank 200 may be lowered. And, even if ice (I) is supplied to the cold water tank 400 for cooling the water stored in the cold water tank 400, when the water level of the cold water tank 400 reaches a certain level, the water stored in the cold water tank 400 is circulated Since the water is supplied to the water storage tank 200 through the unit 600, the cooling water having a low temperature is supplied from the ice making unit 300 to the cold water tank 400 or the ice I supplied to the cold water tank 400 melts. Even when the water level rises, it is possible to prevent the water overflow of the cold water tank 400.

Meanwhile, as shown in FIGS. 1 to 4, one side of the circulation pipe 610 of the circulation unit 600 may be connected to the cold water tank 400 on the side to which water is supplied, including cooling water having a relatively low temperature. have. For example, as shown in the illustrated embodiment, one side of the circulation pipe 610 may be connected to the right side of the cold water tank 400 as shown in the drawing, in which a relatively low temperature cooling water supplied from the ice making unit 300 exists. Therefore, as described above, water including relatively low temperature cooling water supplied from the ice making unit 300 may be supplied to the water storage tank 200 by driving the pump 620 provided in the circulation pipe 610. have.

As shown in FIG. 10, water including cooling water having a relatively low temperature supplied to the water storage tank 200 may be supplied to the ice making unit 300. Accordingly, ice (I) may be manufactured in the ice making unit 300 using water including cooling water having a relatively low temperature. As such, since the water including the relatively low temperature cooling water supplied to the ice making unit 300 is close to 0 ° C., the ice I may be easily manufactured in the ice making unit 300. In addition, the manufacturing time of the ice (I) can be shortened, and the ice (I) can be manufactured with relatively little energy.

To this end, the other side of the circulation pipe 610 as shown in the embodiment shown in Figures 1 to 5 may be connected to the water storage tank 200. In addition, one side of the ice-making water supply pipe 260 is provided with an opening and closing valve 270 may be connected to the water storage tank 200 of the other side of the circulation pipe 610 is connected. For example, the other side of the circulation pipe 610 is connected to the right side of the water storage tank 200, as shown in the embodiment shown in Figures 1 to 5, and one side of the ice-making water supply pipe 260 as shown in the drawing It may be connected to the right side of the water storage tank 200.

The other side of the ice making water supply pipe 260 may be connected to the ice making unit 300. For example, as shown in FIGS. 1 to 5, the other side of the ice making water supply pipe 260 may be connected to the ice making unit 300 so as to be adjacent to the tray member 320.

By such a configuration, when the on-off valve 270 is opened as described above and shown in FIG. 10, water including cooling water having a relatively low temperature supplied to the water storage tank 200 through the circulation pipe 610 is used for ice making. The ice making unit 300 through the water supply pipe 260, in the illustrated embodiment, may be supplied to the tray member 320 of the ice making unit 300 to be contained in the tray member 320. Accordingly, water having a relatively low temperature, for example, water containing coolant close to 0 ° C as described above may be supplied to the tray member 320.

Meanwhile, the other side of the circulation pipe 610 and one side of the ice making water supply pipe 260 may be connected to the lower portion of the water storage tank 200 as shown in FIG. 1. For example, as shown in the illustrated embodiment, the other side of the circulation pipe 610 and one side of the ice making water supply pipe 260 may be connected to the lower right side of the water storage tank 200 as shown in the drawing.

Accordingly, water including cooling water having a relatively low temperature may be supplied from the cold water tank 400 to the lower portion of the water storage tank 200. As a result, even though the water containing the coolant having a relatively low temperature is supplied to the water storage tank 200, the temperature of the water stored in the relatively high temperature water storage tank 200 and the water including the coolant having a relatively low temperature Due to the difference, convection may not occur in the water storage tank 200. Therefore, the water including the coolant having a relatively low temperature may be mixed with the water stored in the water storage tank 200 having a relatively high temperature. Therefore, water containing coolant having a relatively low temperature is easily transferred to the ice making unit 300 and the tray member 320 of the ice making unit 300 in the illustrated embodiment through the ice making water supply pipe 260 as described above. Can be supplied.

However, the position at which the ice making water supply pipe 260 and the circulation pipe 610 are installed in the water storage tank 200 is not limited to the above, and is lower than room temperature from the water storage tank 200 to the ice making unit 300. Various modifications would be possible if temperature water could be supplied.

Meanwhile, the ice making system 100 according to the present invention may further include the aforementioned controller (not shown). The control unit via the ice-making water supply pipe 260 at the same time as the supply of water containing the coolant from the cold water tank 400 through the circulation pipe 610 to the water storage tank 200 or after a predetermined time (preset time) The water containing the cooling water from the tank 200 to the ice making unit 300 may be supplied. Accordingly, water containing a relatively large amount of cooling water is supplied from the cold water tank 400 to the water storage tank 200 through the circulation pipe 610, and the ice making unit 300 through the ice making water supply pipe 260. For example, in the illustrated embodiment, it may be supplied to the tray member 320 of the ice making unit 300.

To this end, the control unit may be connected to the pump 620 provided in the circulation pipe 610 and the on-off valve 270 provided in the ice-making water supply pipe 260. The controller may open the on / off valve 270 at the same time as driving the pump 620 or drive the pump 620 after a predetermined time. In this case, the predetermined time may be a time for supplying the water storage tank 200 to the water storage tank 200 through the circulation pipe 610 by driving the pump 620, including the relatively low temperature cooling water stored in the cold water tank (400) It is not limited to this. For example, before water is supplied from the ice making unit 300 to the cold water tank 400, it is possible to drive the pump 620 to lower the level of the cold water tank 400, in which case the pump 620 is driven. After the predetermined time elapses for the next ice making, the on / off valve 270 may be opened to supply water from the water storage tank 200 to the ice making unit 300.

As described above, in addition to the pump 620 or the valve 270, the control unit includes a tray member 320 and an evaporator 330, a refrigeration cycle, a thermoelectric module 330 ', a fan 360', and a heating unit ( 700, a motor (not shown) for rotationally driving the second guide member 430, a heating unit 700 or other open / close valves 230, 250, 290, 450 or the above-described high water level sensor 460. Any configuration can be connected to the required configuration.

On the other hand, as shown in Figures 2 and 3 and 5, the water storage tank 200 may be provided with a separating member 210. As shown in the embodiment shown by the separating member 210, the water storage tank 200 may be divided into a circulation area (S1) and a storage area (S2).

In the circulation region S1, water including cooling water having a relatively low temperature supplied from the cold water tank 400 may be present. In the embodiment shown in Figures 2, 3, and 5, the water including the coolant having a relatively low temperature is supplied from the cold water tank 400, and the circulation zone S1 is located on the right side of the water storage tank 200. This can be formed.

In the storage region S2, other water, for example, water of a relatively high temperature water source introduced from the water supply source through the inlet pipe 220 may exist in the embodiment shown in FIGS. 2, 3, and 5. have. In the illustrated embodiment, the storage area S2 may be formed on the left side of the water storage tank 200 as shown in the drawing, in which water having a relatively high temperature flows from the water supply source through the inlet pipe 220.

In this case, there is a relatively high temperature of water introduced from the water supply source through the circulation region (S1) and the inlet pipe 220, where the water containing the cooling water having a relatively low temperature is present by the separating member (210). The storage area S2 is divided. Therefore, the water containing the relatively low temperature cooling water supplied from the cold water tank 400 is to be minimized by mixing with other water, that is, the relatively high temperature water stored in the water storage tank 200 by the convection caused by the temperature difference. Can be.

The division bonsai 210 may be provided in the water storage tank 200 so that water flows between the circulation region S1 and the storage region S2. To this end, the upper end of the partition member 210 may be located lower than the middle water level and higher than the low water level of the water storage tank 200 as shown in the illustrated embodiment.

When the upper end of the separating member 210 is higher than the water level of the water storage tank 200, water flows between the circulation region S1 and the storage region S2 of the water storage tank 200 by the separating member 210. You can't. In addition, when the upper end of the partition member 210 is lower than the water level of the water storage tank 200, the water storage tank 200 is divided into a circulation region (S1) and the storage region (S2) by the partition member 210. Becomes difficult.

In addition, one or more flow holes 211 may be formed in the dividing member 210 as shown in FIGS. 2, 3, and 5. Water may flow between the circulation area S1 and the storage area S2 of the water storage tank 200 through the flow hole 211, and in this case, the height of the upper end of the partition member 210 may be as described above. The water storage tank 200 may not be limited to be positioned below the low water level and higher than the low water level.

In addition, the separator 410 may be provided in the cold water tank 400 as shown in FIG. 3. Like the embodiment shown by the separating member 410, the cold water tank 400 may also be divided into a circulation area (S1) and a storage area (S2).

In the circulation area S1, the ice making unit 300 and the ice I supplied from the tray member 320 of the ice making unit 300 in the embodiment shown in FIG. 3 are generated and remain or are separate from the generation of the ice I. There may be a relatively low temperature cooling water cooled by the immersion member 310, that is, a cooling water whose temperature is close to 0 ℃ as described above. In the illustrated embodiment, the coolant having a relatively low temperature is supplied from the ice making unit 300, that is, the tray member 320 of the ice making unit 300, and the circulation area S1 is located on the right side of the cold water tank 400. This can be formed.

In the storage region S2, other water, in the embodiment illustrated in FIG. 3, may have relatively high temperature water supplied from the water storage tank 200 through the water supply pipe 240. In the illustrated embodiment, a relatively high temperature water supplied from the water storage tank 200 is introduced through the water supply pipe 240, so that the storage area S2 may be formed on the left side of the cold water tank 400. Can be.

In this case, the water storage tank 200 through the water supply pipe 240 and the circulation zone (S1) where the water containing the coolant relatively low temperature, that is, the temperature is close to 0 ℃ by the separating member 410 is present. Storage area (S2) in which water having a relatively high temperature introduced from is present. Therefore, water containing a large amount of cool water having a relatively low temperature may be supplied from the cold water tank 400 to the water storage tank 200 through the circulation pipe 610, and water containing a large amount of cool water having a relatively low temperature. The ice making unit 300 may be supplied to the tray member 320 of the ice making unit 300 in the embodiment shown in FIG. 3 through the ice making water supply pipe 260.

The partition bonsai 410 may be provided in the cold water tank 400 so that water flows between the circulation region S1 and the storage region S2. To this end, the lower end of the partition member 410 may be spaced apart from the bottom of the cold water tank 400, as shown in the embodiment shown in FIG. In addition, one or more flow holes 411 may be formed in the separating member 410 as shown in the illustrated embodiment. Water flows between the circulation region S1 and the storage region S2 of the cold water tank 400 through a gap between the lower end of the separator 410 and the bottom of the cold water tank 400 or the flow hole 411. Can be.

Meanwhile, the water stored in the cold water tank 400 cooled by the water and ice I stored in the water storage tank 200 is respectively stored in the water storage tank 200 and the cold water tank 400 as shown in FIG. It is discharged to the outside through the connected water discharge pipe (280,440) can be supplied to the user. That is, when the on-off valves 290 and 450 provided in the water discharge pipes 280 and 440 respectively open, the water stored in the water storage tank 200 is cooled through the water discharge pipe 280 and the cold water tank cooled by the ice I ( The water stored in 400 may be discharged to the outside through the water discharge pipe 440 and supplied to the user.

In this case, when it is detected by the control unit that the water level of the cold water tank 400 is lower than the full water level, the control unit may open and close the valve 250 as shown in FIG. Accordingly, as shown in FIG. 10, the water of the water storage tank 200 may be supplied to the cold water tank 400 through the water supply pipe 240.

Next, the control method of the ice making system that can be performed through the configuration of the control unit of the ice making system described above will be described.

As described above, the control method of the ice making system according to an aspect of the present invention can be applied to an ice making system having a water storage tank 200, an ice making unit 300, a cold water tank 400, and a circulation unit 600. have.

Specifically, the control method of the ice making system according to an embodiment of the present invention, the ice making unit 300 is configured to manufacture the ice (I) from the water supplied from the water storage tank 200, and in the ice making unit 300 The method relates to a control method of an ice making system including a cold water tank (400) for cooling the stored water by supplying manufactured ice (I) or cooled cooling water, wherein the water level of the cold water tank (400) is at a predetermined level. Determining whether the corresponding water, and if the water level of the cold water tank 400 is more than a predetermined level water supply step of supplying water to the water storage tank 200 to supply the water contained in the cold water tank 400 to the water storage tank 200 Can be configured.

At this time, the water supply step of the water storage tank may be performed when the water level of the cold water tank 400 becomes a full water level. The water level may be set equal to the water level to block the water supply to the cold water tank 400, it may be set higher than the water level to block the water supply to the cold water tank (400).

The water supply step of the water storage tank may be performed by driving a pump 620 provided in the circulation pipe 610 between the cold water tank 400 and the water storage tank 200.

On the other hand, the control method of the ice making system according to an embodiment of the present invention, at the same time as the water supply step of the water storage tank, or after a predetermined time after the water supply step of the water storage tank is performed The water supply to the ice making unit for supplying the water contained in the water storage tank 200 to the ice making unit 300 may be performed.

At this time, the water supply step to the ice making unit may be performed by opening and closing the valve 270 provided in the ice-making water supply pipe 260 between the water storage tank 200 and the ice making unit 300. More specifically, at the same time as driving the pump 620 to perform the water supply step of the water storage tank, or after a predetermined time elapses after the pump 620 is driven by opening and closing the valve 270 The water contained in the storage tank 200 may be supplied to the ice making unit 300.

As described above, according to an embodiment of the present invention, the cold water is supplied to the cold water tank by supplying the ice produced in the ice making unit or the cooling water cooled in the ice making unit, as well as water of the cold water tank to the ice making unit. It can be supplied to the water storage tank to supply water to prevent the overflow of the cold water tank.

In addition, according to one embodiment of the present invention, by supplying water having a relatively low temperature to the ice making unit, ice making can be easily performed, and thus ice making efficiency can be improved.

In addition, according to one embodiment of the present invention, the supply of ice to the ice storage and the cold water production using the ice through the second guide member can be made independently, by using a heating unit to easily defrost ice There may be no noise during the defrosting.

The ice making system described above is not limited to the configuration of the above-described embodiment, but the embodiments may be configured by selectively combining all or some of the embodiments so that various modifications can be made.

10, 100: ice making system 20, 200: water storage tank
210,410 Division member 211,411 Flow hole
220: inlet pipe 24,240: water supply pipe
260: water supply pipe for ice making
25, 230, 250, 270, 290, 450: on-off valve 280, 440: water discharge pipe
300: ice making unit 310: immersion member
320: tray member 330: evaporator
330 ': Thermoelectric module 340': Cold sink
350 ': Heatsink 360': Fan
40,400: cold water tank 420: first guide member
430: second guide member 460: high water level sensor
500: ice storage 600: circulation
61,610: Circulation pipe 611: Air hole
62,620: Firm 630: check valve
700: heating unit 70: grill
80: slide plate 81: groove
81a: outlet I: ice
S1: cyclic area S2: storage area

Claims (33)

A water storage tank 200 into which water is introduced and stored;
An ice making unit 300 configured to manufacture ice I from water supplied from the water storage tank 200 and disposed below the water storage tank 200;
The water supplied from the water storage tank 200 through the water supply pipe 240 is stored and the ice (I) or cooled cooling water manufactured by the ice making unit 300 is supplied to cool the stored water, and the ice making is performed. A cold water tank 400 disposed below the unit 300; And
A circulation unit 600 configured to supply water cooled in the cold water tank 400 to the water storage tank 200;
Including;
The water storage tank 200 is provided with a separating member 210 for dividing the circulation area (S1) is supplied with the water cooled in the cold water tank 400 and the storage area (S2) partitioned therefrom,
The cold water tank 400 is provided with a partition member 410 for distinguishing the circulation area (S1) in which the water containing the cooling water exists and the storage area (S2) partitioned therefrom,
The circulation unit 600 includes a circulation pipe 610 connected to the cold water tank 400 and the water storage tank 200, and a pump 620 provided at the circulation pipe 610.
One side of the circulation pipe 610 is connected to the circulation region (S1) of the cold water tank 400, the other side is connected to the circulation region (S1) of the water storage tank 200,
One side of the water supply pipe 240 is connected to the water storage tank 200 and the other side is connected to the storage area (S2) of the cold water tank 400,
One side of the ice making water supply pipe 260 is a circulation area of the water storage tank 200 so that the cooled water accommodated in the circulation area S1 of the water storage tank 200 is supplied to the ice making unit 300. (S1) and the other side is the ice making system connected to the ice making unit (300). delete The ice making system of claim 1, wherein at least a portion of the circulation pipe (610) is connected to the water storage tank (200) through the cold water tank (400). The ice making system according to claim 1, wherein the cooling water cooled in the ice making unit is supplied to the cold water tank. 5. The method of claim 4, wherein the water including the cooling water supplied to the cold water tank 400 is supplied to the circulation region S1 of the water storage tank 200 through the circulation part 600. Ice making system. The ice making system according to claim 5, wherein one side of the circulation pipe (610) included in the circulation part (600) is connected to the cold water tank (400) on the side to which the cooling water is supplied. delete delete The ice making system according to claim 1, wherein the other side of the circulation pipe (610) and one side of the ice making water supply pipe (260) are connected to a lower portion of the water storage tank (200). The water supply pipe for ice making according to claim 1, wherein the ice-making water supply pipe is formed at the same time as the supply of water containing the cooling water from the cold water tank 400 to the water storage tank 200 through the circulation pipe 610, or after a predetermined time. A control unit configured to supply water including the cooling water from the water storage tank 200 to the ice making unit 300 through 260; Ice making system further comprises. The method of claim 10, wherein the control unit is connected to the pump 620 provided in the circulation pipe 610 and the on-off valve 270 provided in the ice-making water supply pipe 260,
The control unit drives the pump (620) and at the same time open the on-off valve (270) or drive the pump (620) after the predetermined time, the ice making system, characterized in that for opening the on-off valve (270). delete The water storage tank 200 of claim 1, wherein the division member 210 is provided in the water storage tank 200 so that water flows between the circulation area S1 and the storage area S2 of the water storage tank 200. Ice making system. 14. The ice making system according to claim 13, wherein an upper end of the dividing member (210) is positioned lower than the middle water level and higher than the low water level of the water storage tank (200). 15. The ice making system of claim 13, wherein one or more flow holes (211) are formed in the dividing member (210). delete The method of claim 1, wherein the separating member 410 is provided in the cold water tank 400 so that water flows between the circulation area (S1) and the storage area (S2) of the cold water tank (400). Ice making system. 18. The ice making system according to claim 17, wherein the lower end of the dividing member (410) is spaced apart from the bottom of the cold water tank (400) by a predetermined distance. 18. The ice making system according to claim 17, wherein at least one flow hole (411) is formed in the dividing member (410). The ice making system according to claim 1, wherein the ice making unit comprises an evaporator 330 through which a refrigerant flows. The ice making system of claim 1, wherein the ice making unit comprises a thermoelectric module. The ice making system according to claim 1, wherein the water supply pipe (240) is provided with an open / close valve (250) for supplying water from the water storage tank (200) to the cold water tank (400). The ice making system according to claim 22, wherein the cold water tank (400) is provided with a full water level sensor (460). The water level of the cold water tank 400 is detected by the control unit connected to the high water level sensor 460 is lower than the high water level.
The control unit opens the open / close valve 250 to supply water from the water storage tank 200 to the cold water tank 400 through the water supply pipe 240 to maintain the water level of the cold water tank 400. Ice making system characterized in that. According to claim 1, Ice storage 500 is supplied and stored in the ice (I) manufactured in the ice making unit 300; Ice making system further comprises. The method of claim 25, wherein the cold water tank 400 is provided with a first guide member 420 for guiding the ice (I) produced in the ice making unit 300 to the cold water tank 400,
Between the cold water tank 400 and the ice storage 500, the second guide member 430 for guiding the ice I to the ice storage 500 in association with the first guide member 420 is rotatable. Ice making system, characterized in that provided. According to claim 25, Between the cold water tank 400 and the ice storage 500, the ice (I) produced in the ice making unit 300 is supplied to the cold water tank 400 or the ice (I) Ice making system characterized in that the second guide member 430 rotatably provided to the reservoir 500. The ice making system of claim 1, wherein the water storage tank (200) receives water from a filtration unit including at least one purified water filter for filtering the introduced water. The ice making unit 300 configured to manufacture ice I from water supplied from the water storage tank 200, and the ice I or the cooled cooling water manufactured in the ice making unit 300 are supplied to cool the stored water. In the control method of the ice making system comprising a cold water tank 400,
Determining whether the water level of the cold water tank 400 corresponds to a predetermined water level;
When the water level of the cold water tank 400 is above a certain level water supply step of the water storage tank for supplying the water contained in the cold water tank 400 to the water storage tank 200: And
Supplying water to an ice making unit supplying the water contained in the water storage tank 200 to the ice making unit 300;
Including;
The water storage tank 200 is provided with a separating member 210 for dividing the circulation area (S1) is supplied with the water cooled in the cold water tank 400 and the storage area (S2) partitioned therefrom,
The cold water tank 400 is provided with a partition member 410 for distinguishing the circulation area (S1) in which the water containing the cooling water exists and the storage area (S2) partitioned therefrom,
The water of the water storage tank 200 is supplied to the storage area (S2) of the cold water tank 400 through the water supply pipe 240,
The water supply step of the water storage tank is configured to supply the water contained in the circulation region (S1) of the cold water tank 400 to the circulation region (S1) of the water storage tank 200,
The water supply step to the ice making unit control method of the ice making system configured to supply the cooled water contained in the circulation area (S1) of the water storage tank 200 to the ice making unit (300). The method of claim 29,
The water supply step of the water storage tank is a control method of the ice making system, characterized in that is performed when the water level of the cold water tank 400 is a full water level. The method of claim 29,
The water supply step of the water storage tank is a control method of the ice making system, characterized in that performed by driving the pump (620) provided in the flow path between the cold water tank (400) and the water storage tank (200). The method of any one of claims 29 to 31,
The water supplying step to the ice making unit is performed at the same time as the water supplying step to the water storage tank or after a predetermined time elapses after the water supplying step to the water storage tank is performed. Control method of the system. 33. The method of claim 32,
The water supply step to the ice making unit control method of the ice making system, characterized in that performed by opening and closing the valve 270 provided in the flow path between the water storage tank 200 and the ice making unit (300).

Images