KR101795424B1 - Ice and cold water maker - Google Patents

Abstract

An object of the present invention is to solve the problem of hygiene of a cold water tank while raising the utilization efficiency of the cooling means and raising the energy efficiency by using the energy conventionally wasted by heat exchange with the surroundings to generate cold water, And an ice and cold water generating unit for generating ice and cold water by cooling the inflow fluid to achieve the ice and cold water generating unit, wherein ice generation and cold water generation in the ice and cold water generating unit are performed by the same cooling means, Wherein the ice and cold water generating unit is configured to cool the fluid as it flows from the water inlet to the water outlet.

Description

[0001] ICE AND COLD WATER MAKER [0002]

The present invention relates to a device for generating ice and cold water together, and more particularly, to a cold water and ice producing device which can generate cold water and ice with the same cooling means, but also can easily perform energy saving and cleaning and internal placement.

Generally, an ice water purifier is a device for purifying raw water such as tap water to supply purified water, cold water and / or hot water and ice to the user. The ice water purifier generally has a filter unit for purifying the raw water, a purified water tank for storing the purified water, a cold water tank for storing and cooling the purified water, and an ice making unit for making ice, and a hot water tank As shown in FIG.

In this case, it is necessary to cool the cold water tank and the ice making unit to generate cold water and generate ice. To this end, a method of cooling the cold water tank and the ice making unit through an independent cooling unit has been proposed. However, in such a case, there is a problem that the number of components increases, the price of the ice water purifier becomes high, and the power consumption increases.

In order to solve such a problem, an ice water purifier capable of cooling a cold water tank and producing ice using a single cooling unit has been proposed. However, when one cooling unit is used, it is necessary to share an evaporator, There was a problem that it was impossible.

In order to solve such a problem of the conventional ice water purifier, Japanese Patent No. 1001297 discloses a method of selectively injecting ice into an ice reservoir and a cold water tank.

As shown in Figs. 1A and 1B, the ice water purifier 1 disclosed in Japanese Patent No. 1001297 immerses the dipping portion 12 of the ice making unit 11 in the raw water for ice making contained in the ice making water receptacle 10, .

The ice making water reservoir 10 is rotatable by a motor (not shown) around the hinge 13 and generates ice when it is immersed in the ice making water receptacle 10 so that the ice making water receptacle 10 has escaped The ice scraped from the dipping section 12 is supplied to the cold water tank 30 or the ice storage section 20 by the swash plate 15 and the guide member 17.

However, since the conventional ice water purifier 1 uses ice to cool the cold water tank, a cold water tank must necessarily be disposed below the ice producing portion. That is, since the ice-producing section is disposed on the upper part of the cold water tank, it is difficult for the hand to enter the cold water tank and it is difficult to clean the cold water tank.

Especially, in the case of cold water tank, drinking water is stagnant for a long time, and if it can not be cleaned, it may become a sanitary problem.

In addition, as shown in FIG. 1B, the ice making unit 11 for generating ice is not used anywhere else except for the dipping portion 12, where cold water or ice is produced, resulting in a waste of energy.

In addition, since cold water is generated through ice after it is generated, not only the cold water generation response is not immediately available, but also there is a problem that energy is wasted because it is necessary to prepare cold water unnecessarily.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to increase energy efficiency by increasing the usability of the cooling means by using energy that is conventionally wasted by heat exchange with the surroundings to generate cold water.

In addition, by eliminating the cold water tank or freezing the position of the cold water tank, cleaning of the cold water tank is unnecessary or easy to clean, and sanitation of the drinking water is ensured.

In order to achieve the above object, the present invention provides an ice and cold water generating apparatus as described below.

The present invention relates to an ice and cold water generating apparatus including an ice and cold water generating unit for cooling an inflow fluid to generate ice and cold water, wherein ice generation and cold water generation in the ice and cold water generating unit are performed by the same cooling means, There is provided an ice and cold water generating apparatus in which the ice and cold water generating unit is configured to cool the fluid as it flows from the inlet portion to the outlet portion.

In the present invention, the introduced fluid is cooled by the ice formed in the space portion or the dipping portion disposed in the space portion, and the ice and cold water generating portion is connected to the water inlet portion, the water outlet portion, And a plurality of space portions in which ice is generated, wherein the space portion is configured to fill one space portion with the fluid introduced through the intake portion, and then to fill another space portion, and the cooling means is immersed in the fluid filled in the space portion And a connecting portion connecting the dipping portion and the dipping portion.

In this case, the plurality of space portions may have height differences and may be disposed in one or more rows, and may include a guide groove for guiding a flow of fluid between the space portions and between the space portion and the water inlet portion or the water outlet portion.

And a cold water passage communicating the outflow portion between the uppermost space portion of the ice and cold water generating portion and the fluid receiving portion, wherein a part of the fluid introduced into the cold water passage is divided into the space It can be configured to pass through the bottom of the part.

Alternatively, in the present invention, the ice and cold water generating unit may include an ice-making water tray; And a cooling unit including an immersion unit immersed in the ice-making water receiver to generate ice, and a connection unit connecting the immersion unit, wherein the connection unit of the cooling unit cools the inflow fluid to generate cold water, And a cold water passage of a heat exchangeable structure.

The ice and cold water generating unit may include a case surrounding the connection portion, a heat transfer medium filled in the case, and a cold water passage passing through the heat transfer medium.

Also, the ice and cold water generating unit may include a cold water pipe for generating cold water, and the cold water pipe may be surrounded by the connection pipe inside the connection pipe of the cooling unit or surrounding the connection pipe from the outside. Further, the cold water pipe may extend along the connection pipe of the cooling means.

Alternatively, the present invention is characterized in that the ice and cold water generating unit includes a space including a space where ice is generated; A heat transfer medium filled in the case; And cooling means for passing through the heat transfer medium, wherein the cooling means can be configured to generate the ice filled with the fluid filled in the space portion through the heat transfer medium.

At this time, the ice and cold water generating unit may include a cold water pipe passing through the heat transfer medium. The space unit is formed by coupling the upper case and the lower case, and the cooling means and the heat transfer medium are disposed inside the upper case .

The present invention can increase the usability of the cooling means and increase the energy efficiency through the above-described structure.

Further, by excluding the cold water tank or freezing the position of the cold water tank, cleaning of the cold water tank is unnecessarily or easily performed, and sanitation of the drinking water can be ensured.

FIG. 1A is a schematic view of a conventional ice and cold water producing apparatus, and FIG. 1B is a sectional view of an ice producing unit of a conventional ice and cold water producing apparatus.
2 is a cross-sectional perspective view of a first embodiment of the present invention.
3 is a plan view of the first embodiment of the present invention.
4 is a cross-sectional perspective view of a modification of the first embodiment of the present invention.
5 is an ice and cold water pipe view of the first embodiment of the present invention.
FIG. 6A is a perspective view of a second embodiment of the present invention, and FIG. 6B is an ice and cold water pipe diagram of a second embodiment of the present invention.
FIG. 7A is a perspective view of a third embodiment of the present invention, and FIG. 7B is an ice and cold water pipe diagram of a third embodiment of the present invention.
8A and 8B are sectional views of a modification of the third embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments which fall within the scope of the inventive concept may be easily suggested, but are also included within the scope of the present invention.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 2 is a cross-sectional perspective view of a first embodiment of the ice and cold water generating apparatus of the present invention, and FIG. 3 is a plan view of a first embodiment of the ice and cold water generating apparatus of the present invention.

As shown in FIGS. 2 and 3, in the first embodiment, the ice and cold water generating unit 100 shares the cooling means 110. FIG. That is, through one cooling means, ice and cold water are generated.

The main body 120 constituting the ice and cold water generating portion 100 includes a plurality of space portions 121 for storing the fluid so that the dipping portion 112 of the cooling means 110 is immersed to generate ice, The portions 121 are arranged in two rows in a stepped fashion.

In other words, the main body 120 has a stepped shape in which the horizontal part 122 and the vertical part 125 are alternately arranged on the upper surface, and the space part 121 is provided on the horizontal part 122. The vertical part 125 disposed between the horizontal part 122 and the horizontal part 122 forms a step and the horizontal part 122 and the vertical part 125 are formed with horizontal A guide groove 123 is formed to guide the fluid to the space 121 of the adjacent vertical part 125 and the next horizontal part 122 without overflowing the part 122.

The inflow pipe 130 through which the fluid flows is connected to an inflow part 126 provided to allow the fluid to flow into the guide groove 123 of the uppermost space part 121. The inflow part 126 is connected to the uppermost part 121, The fluid flowing into the inlet portion 126 flows into the space portion 121 along the guide groove 123. [

The inflow portion 126 also has a wall 127 surrounding the inflow portion 126 to prevent the inflow of the inflow water into the inflow portion 126.

The outflow portion 128 is provided at a position lower than the guide groove 123 of the lowermost space portion 121 similarly to the inflow portion 126 and the outflow pipe 140 is connected to the outflow portion 128, The remaining fluid or cold water filling the tube 121 flows out through the outlet tube 140. The outflow pipe 140 may be disposed on the bottom surface to facilitate the inflow of the fluid from the outflow unit 128 and the outflow unit 128 may be configured to have an inclined surface as a connection part of the outflow pipe 140.

The cooling means 110 is disposed in an oblique direction so as to correspond to the inclination of the step body 120 and has a connecting portion 111 for connecting the immersion portion 112 and the immersion portion 112 to be immersed in the respective space portions 121, . Generally, the evaporator of the refrigerant cycle is used as the cooling means 110, but it is needless to say that other cooling means 110 such as a thermoelectric device can be used.

A hinge 150 is formed on one side of the main body 120 and connected to a driving unit not shown to cool the main body 120 so that ice formed in the space 121 can be removed after ice is generated. From the means (110).

The ice generation process of the first embodiment will be described. The fluid introduced into the inflow portion 126 through the inflow pipe 130 fills the plurality of space portions 121 while flowing along the guide grooves 123. The remaining fluid is discharged through the outlet 128, which is drained or stored in a purified water tank for recycling.

The fluid filled in the space portion 121 is cooled by the dipping portion 112 of the cooling means 110 to generate ice. When a predetermined time has elapsed until the generation of ice, the main body 120 rotates, and supplies hot gas to ice to perform a rubbing operation. It is preferable that the inlet pipe 130 and the outlet pipe 140 are formed of a flexible material so that the residual water of the space portion 121 and the inflow portion 126 and the outflow portion 128 of the inflow pipe 130, It is also possible to mount an auxiliary water receptacle (not shown) for receiving the remaining water.

Next, the cold water generating process of the first embodiment will be described. The inflow fluid flows continuously from the inflow section 126 to the outflow section 128 while passing through the respective space sections 121 along the guide grooves 123. At this time, And is cooled by the ice formed by the dipping section 112 or the dipping section 112 disposed in each of the space sections 121.

Accordingly, in the first embodiment, the cooling effect of the cooling means 110 can be immediately influenced, and since the cooling is performed while the fluid flows, a direct water system is possible, and at least a cold water tank There is no need to be. In addition, in a state where ice is generated in advance, it is not necessary to drive the cooling means to generate cold water, so energy saving is possible.

Fig. 4 shows a modification of the first embodiment. The modification of FIG. 4 is similar to the first embodiment of FIG. 2 except that it has a cold water passage 160 that is configured to pass from the inlet 126 to the outlet 128 and to pass under the space 121 .

4, the space portion 121 is formed so as to be able to effectively exchange heat with the fluid cooled by the cooling means 110 in the ice or space portion 121 of the space portion 121 That is, in a manner that directly exchanges heat with the space portion 121 at the upper portion, and heat exchange through the space portion 121 and the body at the lower portion.

At this time, the cold water passage 160 has a narrow width, and only a part of the inflowed flow flows through the cold water passage 160 to the lower portion of the space portion 121, And passes through the upper portion of the portion 121.

Figure 5 shows an ice and cold water generating piping of the present invention.

5, the raw water portion 101 is connected to the filter portion 102, and the raw water of the raw water portion 101 becomes constant while passing through the filter portion 102. As shown in FIG. The filter unit 102 is constructed by connecting one or more conventional filters of various types.

The purified water passing through the filter unit 102 is discharged directly to the discharge unit 106 by the flow path switching valve 103 and the solenoid valve 104 or is discharged to the ice discharge unit 106 through the ice and cold water generating unit 100, (108), or may be discharged through the discharge portion (106) with cold water. At this time, the flow path switching valve 103 may be constituted by a branching portion and a solenoid valve.

The purified water flowing into the ice and cold water generating section 100 through the flow path switching valve 103 is generated as cold water or ice by the operation of the cold water and the ice producing section and is generated by the ice storing section 109 and the ice Is discharged to the ice discharge unit 108 through the transfer unit 107 and can be discharged to the discharge unit 106 through the solenoid valve 105 when generated by the cold water.

The overall configuration of the piping diagram such as the ice and cold water generating unit 100, the solenoid valves 104 and 105 and the discharging unit 106 is connected to a control unit (not shown) and can be customized according to the request of the user.

Although not shown in the drawings, the purified water tank or the cold water tank can be disposed in the water tank or the cold water tank and supplied.

6A and 6B show a second embodiment of the present invention.

6A, the ice and cold water generating unit 200 includes an upper case 210, a lower case 220, and a space 221 formed in a hemispherical shape in each case 210 and 220, 221 form a spherical space when the cases 210, 220 are engaged. The upper case 210 and the lower case 220 are connected to each other through a hinge 250 and the lower case 220 is connected to driving means (not shown) to rotate about the hinge 250.

The space portion 221 is provided with an inflow portion 226 for introducing fluid into the space portion 221 and a guide groove 223 connecting the space portion 221. An air outlet 221).

The upper case 210 is filled with a heat transfer medium 215 and passes through the heat transfer medium 215 to pass the cooling means 230 and the cold water pipe 240.

In the present invention, the cooling means 230 cools the heat transfer medium 215, and the cooled heat transfer medium 215 forms ice when the space portion 221 is filled with fluid. The cooled heat transfer medium 215 also cools the fluid in the cold water pipe 240 passing through the heat transfer medium 215 to generate cold water.

In this embodiment, the cooling means 230 cools the heat transfer medium 215. When cold water is required, the cold water pipe 240 supplies the fluid to heat exchange with the heat transfer medium 215 to generate cold water. After the cold water is generated, the fluid in the cold water pipe 240 is removed from the cold water pipe 240 through a residual water removing means such as an air pump (not shown) to prevent the cold water pipe 240 from freezing due to the cooling means 230 .

When the ice is required, the upper and lower cases 210 and 220 are closely contacted to seal the space 221, and the fluid from the inflow portion 226 below the space 221 to the space 221 And the air in the space 221 is discharged to an air outlet (not shown), and the space 221 is filled with the fluid.

The fluid in the space portion 221 is heat-exchanged with the cooling means 230 through the heat transfer medium 215 to generate ice. After the ice is generated, that is, after a predetermined time has elapsed, the lower case 220 rotates , The lower half of the ice is exposed, the hot gas is supplied to the exposed ice, or the air is blown through an air outlet (not shown) and dropped into an ice storage (not shown).

6B shows an ice and cold water piping diagram of a second embodiment of the present invention.

The raw water portion 201 is connected to the filter portion 202 so that the raw water of the raw water portion 201 becomes constant while passing through the filter portion 202. The filter unit 202 is constructed by connecting one or more conventional filters of various types.

The purified water that has passed through the filter unit 202 is discharged directly to the discharge unit 206 by the flow path switching valves 203 and 204 and the solenoid valve 205 or is discharged to the discharge unit 206 through the ice and cold water generating unit 200, When the ice is required, the cold water passing through the ice and cold water generating unit 200 is returned to the discharge portion 206 through the switching valve 204 and the solenoid valve 205, And then flows into the cold water generating section 200, that is, into the inflow section 226. Thus, by using cold water to make ice, cooling efficiency can be increased.

In the case where ice is generated in the ice and cold water generating unit 200, the ice is discharged to the ice discharge unit 208 through the ice storage unit 209 and the ice transfer unit 207, The solenoid valve 204, and the solenoid valve 205, as shown in FIG.

The overall configuration of the piping diagram such as the ice and cold water generating section 200, the flow path switching valves 203 and 204, the solenoid valve 205 and the discharging section 206 is connected to a control section (not shown) Can be provided.

Although not shown in the drawings, it is also possible to arrange the purified water tank and / or the cold water tank in purified water or cold water.

Next, a schematic view of a third embodiment of the present invention is shown in Figs. 7A and 7B.

As shown in FIG. 7A, in the third embodiment, an ice-making water receptacle 330 is disposed below the cooling means 310, and when the ice-making water receptacle 330 is filled with fluid, The dipping portion 312 of the means 310 is immersed in the fluid to form ice. The ice-making water receiver 330 is connected to the driving unit 331 and rotated, and the ice formed in the dipping unit 312 drops to the ice storage unit 340.

The ice storage unit 340 includes a screw 341 as ice transfer means and a drive means 349 connected to the screw 341 to rotate the screw 341.

The cooling means 310 includes a connecting portion 311 for connecting the dipping portion 312 and the dipping portion 312 and the connecting portion 311 is disposed inside the case 314. The inside of the case 314 is filled with the heat transfer medium 315 and the cold water pipe 320 is disposed through the heat transfer medium 315 similarly to the second embodiment.

Therefore, when the ice is generated, the connection portion 311 of the cooling means 310, which conventionally exchanges heat with the atmosphere, is connected to the heat transfer medium 315 inside the case 314 of the ice and cold water generating portion 300, The heat transfer medium stores the transferred cold air and then cools the fluid when the fluid flows into the cold water pipe 320.

In the present embodiment, the fluid having passed through the cold water pipe 320 can be stored in the cold water tank 350 through the water pipe 323, or alternatively, discharged through the discharge part 106 .

As in the second embodiment, after the cold water is generated, the fluid in the cold water pipe 320 is removed from the cold water pipe 320 through the residual water removing means such as an air pump (not shown). Therefore, the fluid of the cold water pipe 320 can be frozen and the cold water pipe 320 can be prevented from being clogged.

7B shows an ice and cold water piping diagram of a third embodiment of the present invention.

The raw water portion 301 is connected to the filter portion 302 so that the raw water of the raw water portion 301 becomes constant while passing through the filter portion 302. The filter unit 302 is constructed by connecting one or more conventional filters of various types.

The purified water that has passed through the filter unit 302 is discharged directly to the discharge unit 306 by the flow path switching valves 303 and 304 and the solenoid valve 305 or through the ice and cold water generating unit 300, The switching valve 304, the solenoid valve 305, and the like. At this time, a cold water tank 350 (see FIG. 7) may be disposed between the ice and cold water generating unit 300 and the flow path switching valve 304.

When ice is required, the cold water or cold water tank 350 (see FIG. 7) passing through the ice and cold water generating unit 300 is returned to the ice and cold water generating unit 300 by the flow path switching valve 304, And then flows into the ice-making water receiver 330. Thus, by using cold water to make ice, cooling efficiency can be increased.

Alternatively, non-cold water may flow into the ice-making water receiver 330 through the flow-path switching valve 303. [

In the case where ice is generated in the ice and cold water generating unit 300, the ice is discharged to the ice discharge unit 308 through the ice storage unit 340 and the screw 341, 304, and the solenoid valve 305 to the discharge portion 306.

The overall configuration of the piping diagram such as the ice and cold water generating section 300, the flow path switching valves 303 and 304, the solenoid valve 305 and the discharging section 306 is connected to a controller (not shown) Can be provided.

Although not shown in the drawings, it is also possible to arrange the purified water tank and / or the cold water tank in purified water or cold water.

In the third embodiment, the connection portion 311 not used in the conventional heat exchange is used for heat exchange to increase the energy efficiency, and the cold water can be supplied to the desired position through the water pipe 323, , It is possible to arrange the cold water tank in a place where cleaning is easy.

8A and 8B show a modification of the third embodiment. In FIG. 8A, a cold water pipe 320 is disposed inside the connection part 311. The connection portion 311 and the cold water pipe 320 are arranged in a double pipe shape so that the heat exchange between the cold water pipe 320 and the connection portion 311 of the cooling means 310 can be generated without the heat transfer medium 315 Do.

In addition, it is also possible to attach the cold water pipe 320 to the connecting portion 311 of the cooling means 310 through welding or the like, as shown in FIG. In the case of constructing the cooling means 310 and the cold water pipe 320 as described above, the heat exchange area is reduced but can be facilitated in terms of production.

It is needless to say that the connection portion 311 may be disposed adjacent to the cold water pipe 320 so that the cold water pipe 320 and the connection portion 311 exchange heat. For example, contrary to FIG. 8A, it is possible to design the connection pipe 311 inside the cold water pipe 320.

100, 200, 300: ice and cold water generating section
110, 230, 310: cooling means
111, 311: connection part 112, 312:
120: main body 121, 221:
122: horizontal part 123: guide groove
125: vertical part 126: inlet part
128: outlet portion 130: inlet pipe
140: Outflow pipe 150: Hinge
160: cold water 210: upper case
215, 315: heat transfer medium 220: lower case
226: inlet portion 240, 320: cold water pipe
314: Case 340: Ice storage

Claims (14)

An ice and cold water producing apparatus comprising an ice and cold water generating unit for cooling an inflow fluid to generate ice and cold water,
The ice and cold water generation in the ice and cold water generator are performed by the same cooling means,
Wherein the ice and cold water generating unit is configured to cool the inflowing fluid from the inlet unit to the outlet unit in order to generate cold water,
The ice and cold water generating unit includes a fluid inlet portion, an outlet water outlet portion, and a plurality of space portions connected to the inlet portion and the outlet portion and generating ice, so that the introduced fluid is cooled by the formed ice or cooling means, Wherein the space part is configured to fill a space part with the fluid introduced through the intake part and then fill another space part,
Wherein the cooling means includes a dipping portion immersed in the fluid filled in the space portion and a connecting portion connecting the dipping portion,
The plurality of the space portions have a height difference and are arranged in one or more rows,
And a cold water channel connected between the uppermost space portion of the ice and cold water generating portion and the fluid intake portion to the outflow portion,
Wherein a part of the fluid introduced into the cold water passes through a lower end of the space so that the fluid passing through the cold water path is cooled. delete delete The method according to claim 1,
And a guide groove for guiding the flow of the fluid between the space portion and the space portion and the water inlet portion or the water outlet portion. delete delete delete delete delete delete delete delete delete delete

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