KR101001297B1 - Water purifier having ice-maker - Google Patents

Abstract

An ice purifier is disclosed that can reduce wastewater discharged from a cold water tank.

The ice purifier is a purified water tank for storing purified water; A cold water tank receiving water from the purified water tank and cooling using ice generated through an ice making unit; An ice-making drip tray for receiving raw water for ice-making supplied from the purified water tank or the cold water tank so as to generate ice through the ice-making unit; And a pump for returning the coolant contained in the cold water tank to the purified water tank when the water level of the cold water tank is higher than a predetermined level. The cold water tank when the water level of the cold water tank is increased due to the ice supplied to the cold water tank. By returning the coolant accommodated in the purified water tank through the pump, it is characterized in that the waste of the coolant can be prevented.

According to such an ice water purifier, it is possible to prevent the waste of water by supplying the purified water tank through the pump without discarding the cooling water that is unnecessary in the cold water tank.

Pump, cold water tank, water purification tank, ice maker, ice tray, guide member

Description

Ice Water Purifier {WATER PURIFIER HAVING ICE-MAKER}

The present invention relates to an ice water purifier provided with an ice making unit for a cold water tank using ice, and more particularly, to an ice water purifier that can reduce wastewater by supplying water discharged from a cold water tank to a purified water tank using a pump. It is about.

In general, ice water purifier is a device for supplying purified water, cold water and / or hot water and ice to the user by purifying raw water, such as tap water. An ice water purifier typically includes a filter unit for purifying raw water, a purified water tank for storing purified water, a cold water tank for cooling purified water, and an ice making unit for making ice, and a hot water tank for heating and storing purified water. It can be provided as.

In this case, there is a need to cool the cold water tank and the ice making unit for cold water generation and ice generation. For this purpose, a method of cooling the cold water tank and the ice making unit through an independent cooling unit has been proposed. However, in this case, there is a problem that the number of parts is increased, the ice water purifier price is expensive and the power consumption is increased.

In order to solve this problem, an ice water purifier capable of cooling a cold water tank and producing ice by using a single cooling unit has been proposed. However, when using one cooling unit, it is necessary to share an evaporator, so that ice making and cold water production are performed simultaneously. There was a problem that was impossible.

In order to solve the problems of the conventional ice water purifier, Patent No. 814613 proposes a method of cooling a cold water tank using ice.

As shown in FIG. 1, the ice water purifier 10 disclosed in Patent No. 814613 is immersed in the raw water for deicing water contained in the ice receiving tray 21 to immerse the evaporator 23 of the ice making unit 20 in ice 1. Then, the motor 22 is driven to rotate the ice tray 21 for deicing to drop the remaining water into the cold water tank and at the same time, a defrosting process is performed.

The defrosted ice may be loaded on the ice grill 30 installed on the upper portion of the cold water tank or may be moved to the ice storage by the ice grill 30.

Accordingly, cooling of the purified water supplied to the cold water tank through the solenoid valve 41 is performed in the purified water tank, and the cold water drain pipe 43 is melted to prevent the loaded ice 1 from melting and the cold water flowing over the cold water tank. ) Is installed.

However, the conventional ice water purifier 10 has a problem that waste of water is severe because the ice melts in the process of cooling the cold water tank using ice and drains the water overflowing the cold water tank through the cold water drain pipe 43.

In particular, as the ice continues to melt over time to increase the water level in the cold water tank, there is a problem in that the amount of waste water is very large when the extraction of cold water is small.

In addition, the conventional ice water purifier 10 shown in FIG. 1 has a problem in that ice is loaded on the upper portion of the ice grill 30 so that the amount of ice contacting the cold water tank is small, so that the cooling effect of the cold water tank is not sufficiently expected. .

In addition, since the conventional ice water purifier 10 directly drops the ice on the ice grill 30, the movement of the ice from the ice grill 30 to the ice storage becomes very difficult. That is, since the ice has a polygonal shape, there is a problem that the ice continues to accumulate in the ice grill 30 without being pushed into the ice storage.

The present invention has been made to solve at least some of the above problems, and an object of the present invention is to provide an ice water purifier that can prevent waste of water by not discarding the cooling water that is unnecessary in the cold water tank.

In addition, an object of the present invention is to provide an ice water purifier capable of stably supplying ice to the ice storage and the cold water tank while having a simple structure for supplying ice to the ice storage and the cold water tank.

The present invention to achieve the above object, the purified water tank for storing purified water; A cold water tank receiving water from the purified water tank and cooling using ice generated through an ice making unit; An ice-making drip tray for receiving raw water for ice-making supplied from the purified water tank or the cold water tank so as to generate ice through the ice-making unit; An ice reservoir for storing the ice generated by the ice making unit; A guide member for guiding the ice generated by the ice making unit to only one side of the ice reservoir and the cold water tank; And a pump that returns the cooling water contained in the cold water tank to the purified water tank when the level of the cold water tank is higher than a predetermined level. It includes, wherein the ice supplied to the cold water tank when the water level of the cold water tank is increased by returning the cooling water contained in the cold water tank to the purified water tank through the pump to prevent waste of the cooling water, characterized in that Provide a water purifier.

Preferably, the pump may be driven when the water level of the cold water tank reaches a full water level.

Also preferably, the pump may be driven when the water level of the cold water tank reaches a discharge set level lower than the full water level.

In addition, the pump is the water temperature of the cold water tank is lower than the set water temperature when the inflow of ice in the cold water tank when the water in the cold water tank by the volume corresponding to the volume of the ice supplied from the ice making unit the purified water tank It can have a configuration to return to.

Meanwhile, the ice purifier according to the present invention may be selectively rotated by the drip tray rotation driving means, and the ice making unit may include an evaporator installed to be immersed in the ice making water contained in the ice tray.

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The guide member is rotated between a first position for guiding the ice generated in the ice making unit to be supplied to the ice reservoir and a second position for guiding the cold water tank to be supplied, so that the ice generated in the ice making unit is the ice. It can be guided to only one side of the reservoir and the cold water tank.

As described above, according to one embodiment of the present invention, it is possible to obtain the effect of preventing waste of water by supplying the purified water tank through the pump without discarding the cooling water that is unnecessary in the cold water tank.

In addition, according to an embodiment of the present invention, since the ice produced in the ice making unit is completely accommodated by falling into the cold water tank, the contact area between the ice and the cold water is high, and when the ice falls, cold water is mixed to quickly lower the temperature of the cold water tank. It can be effective.

In addition, according to an embodiment of the present invention, since the ice is selectively supplied to the ice reservoir and the cold water tank through the rotation of the guide member, the supply structure of the ice is not only simple, but the supply of the ice to the corresponding position is stable. Can be.

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

Figure 2 is a partially cutaway perspective view of the ice water purifier according to the present invention, Figure 3 is a schematic diagram showing the internal structure of the ice water purifier shown in Figure 2, Figure 4 is a perspective view of the drip tray member provided in the ice purifier according to the present invention 5 is a cross-sectional view sequentially showing the operating state of the drip tray member according to the present invention. 6A is a schematic diagram of a state in which ice is supplied to an ice reservoir at a defrosting position of the drip member, and FIG. 6B is a schematic diagram of a state in which the drip member is returned to an ice making position, and FIG. 7 is an ice in the cold water tank according to the present invention. It is a schematic diagram which shows the state supplied.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS. 2 to 7.

As shown in Figure 2 and 3, the ice water purifier 100 according to an embodiment of the present invention is a purified water tank 110 for storing the purified water, and a cold water tank 130 for cooling the water contained therein And a pump 170 returning the coolant contained in the cold water tank 130 to the purified water tank 110 when the water level of the cold water tank 130 is greater than or equal to a predetermined water level.

The purified water tank 110 is to accommodate the water filtered through the filter unit (not shown), and has a configuration similar to that used in a conventional water purifier, detailed description thereof will be omitted.

The cold water tank 130 receives water from the purified water tank 110 and cools the water contained therein by using the ice generated through the ice making unit. At this time, the inside of the cold water tank 130, the water level sensor 131a for detecting the full water level of the cold water tank 130, the water level lower than the water level is a level that is required to discharge the water in the cold water tank 130, the cold water discharge set water level Various water level sensors, such as a low water level sensor 131c for additionally replenishing water in the discharge water level sensor 131b and the cold water tank 130, may be installed.

The water level sensor may be added or subtracted according to the water level to be controlled, and the installation height of the water level sensor or the water level detection method is not particularly limited.

In addition, a temperature sensor 132 for detecting the water temperature inside the cold water tank 130 may be installed.

Ice water purifier 100 according to the present invention is to adjust the water temperature of the cold water tank 130 by supplying the ice generated in the ice making unit to the cold water tank 130, so that the ice is additionally supplied or melted of the cold water tank 130 Since the water level can exceed the appropriate level, there is a need to discharge the water contained in the cold water tank 130.

To this end, when the water level sensor detects that the water level of the cold water tank 130 is above a predetermined level, the pump 170 is driven to transfer the cold water contained in the cold water tank 130 to the purified water tank 110 through the recovery pipe 160. Will be supplied.

Therefore, since the water discharged from the cold water tank 130 is moved to the purified water tank 110 without discarding the waste water, it is possible to prevent waste of water.

At this time, when it is detected by the high water level sensor 131a that the water level of the cold water tank 130 reaches the high water level, the pump 170 is driven to discharge the cooling water contained in the cold water tank 130 to the purified water tank 110. You can do that.

However, if the pump 170 is driven after the water level of the cold water tank 130 becomes full, the water may overflow when the pump 170 is delayed or an error occurs in the detection of the full water level sensor 131a. The pump 170 may be driven when the discharge set water level lower than the full water level of the cold water tank 130 is reached. For example, when the discharge level is detected by the discharge level sensor 131b located at a lower position than the full water level sensor 131a, the pump 170 is driven to cool the inside of the cold water tank 130 to purify the cold water. Can be recovered.

The discharge set water level may be appropriately set in consideration of the capacity of the cold water tank 130 or the full water level. However, in consideration of the fact that ice is introduced into the cold water tank 130, the discharge water level is set to a volume of ice supplied from the ice making unit rather than the full water level. The level may be set as low as the corresponding volume.

On the contrary, when the water temperature of the cold water tank 130 is lower than the set water temperature, when the inflow of ice is required in the cold water tank 130, the water corresponding to the volume of the ice supplied from the ice making unit is purified water tank 110. It is also possible to discharge in advance. That is, before the ice is introduced, water corresponding to the volume of the ice may be discharged to the purified water tank 110 in advance through the pump 170.

As described above, the ice water purifier 100 according to the present invention prevents waste of water by supplying the purified water tank 110 by the pump 170 without discharging the water that is unnecessary in the cold water tank 130 to the outside. It becomes possible.

On the other hand, the ice making unit does not show the overall structure, but forms a cooling cycle similar to that provided in a conventional cooling device. Referring to Figure 5 (a), the ice making unit applied to the present invention, the immersion tube 121 provided in the evaporator 120 of the cooling cycle to be immersed in the raw water for ice making accommodated in the ice tray drip 210, According to the operation of the ice making unit, raw water for ice making may be immersed in an ice making method so that ice is formed around the immersion pipe 121, but the present invention is not limited thereto, and various known ice making and de-icing methods can be applied. have.

In addition, various configurations may also be adopted for the ice making drip tray 210 in which the immersion tube 121 of the evaporator 120 is immersed for ice formation. For example, although the ice tray drip 210 shown in FIGS. 2 to 7 may be used, the present invention is not limited thereto, and various known types of ice tray drips 210 may be used.

An example of an ice tray 210 for ice making will be described with reference to FIGS. 2 to 7.

The ice tray drip 210 shown in the drawing constitutes the drip tray member 200 together with the auxiliary drip tray 220.

The drip member 200 is an ice making drip tray 210 for receiving raw water for making ice through ice making unit (not shown), and after cooling the raw water for ice making by the ice making unit, the drip tray for ice making ( In the process of emptying the 210 is provided with an auxiliary drip tray 220 for receiving raw water for ice remaining in the drip tray 210 for deicing.

The ice tray 210 has an accommodation space of a predetermined size to accommodate the raw water for ice making at the ice making position shown in FIG. At this time, the deicing water supplied to the ice tray 210 may be supplied from the purified water tank 110, but when the raw water at a low temperature is supplied, the deicing efficiency is increased, so it is more preferably supplied from the cold water tank 130. Do. In addition, the immersion tube 121 of the evaporator 120 is immersed in the ice-making raw water accommodated in the ice tray 210 for ice making is made.

In addition, the auxiliary drip tray 220 is connected to one side of the ice tray drip 210 to cool the raw water for deicing and then to the ice tray remaining in the drip tray 210 during the de-icing process emptying the ice tray drip 210 The enemy is configured to move and receive.

At this time, the rotation of the ice-making drip tray 210 is the drip member 200 by the drip tray rotating means such as a rotary motor (see 180 of FIG. 3) is an intermediate step in the ice making position shown in FIG. As it rotates about the drip tray rotation shaft 211 to the defrosting position of FIG. 5 (d) and FIG. 5 (e) via b) and FIG. 5 (c), it moves to the auxiliary drip tray 220 and is accommodated, and a deicing operation After this is completed, the drip member 200 is moved by the drip tray rotating means 180 to the auxiliary drip tray 220 as the drip member 200 returns to the ice making position illustrated in FIG. 5 (a) from the defrosting position illustrated in FIG. 5 (e). One remaining raw water is returned to the ice tray 210 for ice making. At this time, additional water is supplied from the cold water tank 130 or the purified water tank 110 in order to supply insufficient ice water.

Meanwhile, the drip member 200 may further include a guide grill 230 mounted on the auxiliary drip tray 220. At this time, the guide grill 230 allows the raw water for ice remaining in the ice tray 210 to be introduced into the auxiliary water tray 220 during the de-icing process of emptying the ice tray 210 for ice. A water inlet 231 having a smaller size than ice may be formed to fall toward the ice reservoir 140 or the cold water tank 130.

In addition, the ice purifier 100 according to the present invention may be provided with an ice storage 140 for storing the ice generated through the ice making unit, as shown in FIG. The ice reservoir 140 is installed at a lower position than the ice making unit so as to accommodate the ice that has been removed from the ice making unit and dropped.

At this time, the ice reservoir 140 may be provided with an ice discharge water stage 141 such as a screw for taking out the ice, ice is discharged when the ice discharge means 141 rotates around the rotating shaft 141a. . Since the internal structure of the ice reservoir 140 is a structure widely adopted in the conventional ice water purifier, detailed description thereof will be omitted.

In addition, the ice water purifier 100 according to the present invention may further include a guide member 150 for guiding the ice generated in the ice making unit to be selectively supplied to the ice reservoir 140 or the cold water tank 130. have.

The guide member 150 has a first position (see FIG. 6A) for guiding the ice generated in the ice making unit to be supplied to the ice reservoir 140 and a second position for guiding the cold water tank 130 to be supplied. 7 may rotate about the rotation shaft 152 through a rotation driving means not shown.

Since the ice is selectively supplied to the ice reservoir 140 and the cold water tank 130 through the rotation of the guide member 150, the supply structure of the ice is simple, and the ice reservoir 140 and the cold water tank 130 are stable. To supply ice. That is, the ice generated in the ice making unit may be configured to be guided to only one side of the ice reservoir 140 and the cold water tank 130 through the rotation of the guide member 150.

Next, the operation of supplying ice to the ice storage 140 or the cold water tank 130 will be described with reference to FIGS. 6A, 6B, and 7.

In order to supply ice to the ice reservoir 140, it is necessary that the guide member 150 is rotated to a position for guiding the ice to the ice reservoir 140 as shown in FIG. 6A when the ice is removed.

At this time, the ice desorbed from the immersion pipe 121 is dropped along the inclined surface of the guide grill 230 which is inclined downward from the defrosting position and guided by the guide member 150 and the ice reservoir through the ice inlet 142 ( 140 is accommodated.

Thereafter, as shown in FIG. 6B, the auxiliary drip tray 220 is rotated to the ice making position to perform an additional ice making operation.

On the other hand, when the water temperature of the cold water tank 130 is increased and cooling of the cold water tank 130 is required, ice is supplied to the cold water tank 130. That is, the guide member 150 is rotated to a position for guiding the ice to the cold water tank 130 as shown in FIG. 7, to supply only the cold water tank 130 with the ice generated and defrosted in the ice making unit.

As such, the ice purifier 100 according to an embodiment of the present invention cools the water contained in the cold water tank 130 through the ice generated by the ice making unit, so that a separate evaporator for cooling the cold water tank 130 is provided. Since it is not necessary, the configuration of the cooling cycle is simple, and since the cooling of the cold water tank 130 is performed using ice, the temperature of the cold water tank 130 can be quickly lowered.

In particular, since the ice produced in the ice making unit falls completely into the cold water tank and is completely accommodated, the contact area between the ice and the cold water is high, and thus the cooling efficiency is high. It can be made uniform and the temperature can be lowered quickly.

While the invention has been shown and described with respect to particular embodiments, it will be apparent to those skilled in the art that the present invention may be modified and modified in various ways without departing from the spirit and scope of the invention as set forth in the claims below. I want to make it clear.

In particular, the detailed description and drawings show and describe specific embodiments of an ice making unit, an ice tray, an ice reservoir, and the like used to generate ice, but the structure and form thereof are not limited to those described.

1 is a schematic view of an ice water purifier according to the prior art.

2 is a partial cutaway perspective view of an ice water purifier according to the present invention;

3 is a schematic view showing the internal structure of the ice water purifier shown in FIG.

Figure 4 is a perspective view of the drip member provided in the ice purifier according to the present invention.

5 is a cross-sectional view sequentially showing the operating state of the drip tray member according to the present invention.

6 illustrates a state in which ice is supplied to an ice storage by the present invention.

6A is a schematic diagram of a state in which ice is supplied to an ice reservoir at a freezing position of the drip member;

6B is a schematic view of the state in which the drip member is returned to the ice making position.

Figure 7 is a schematic diagram showing a state in which ice is supplied to the cold water tank by the present invention.

Explanation of symbols on the main parts of the drawings

100 ... ice water purifier 110 ... water purification tank

120 ... Defrosting evaporator 130 ... Cold water tank

131 ... high level sensor 132 ... temperature sensor

140 ... Ice storage 141 ... Ice drainage

142 ... ice slot 150 ... guide member

160 ... recovery line 170 ... pump

180 ... Drip rotation means 200 ... Drip member

210 ... Ice tray drip tray 211 ... Drip tray axis

220 ... Auxiliary drip tray 230 ... Guide grille

231 ... water inlet

Claims (8)

Purification tank for storing purified water; A cold water tank receiving water from the purified water tank and cooling using ice generated through an ice making unit; An ice-making drip tray for receiving raw water for ice-making supplied from the purified water tank or the cold water tank so as to generate ice through the ice-making unit; An ice reservoir for storing the ice generated by the ice making unit; A guide member for guiding the ice generated by the ice making unit to only one side of the ice reservoir and the cold water tank; And A pump for returning the coolant contained in the cold water tank to the purified water tank when the level of the cold water tank is higher than a predetermined level; Including; Ice water purifier, characterized in that to prevent the waste of cooling water by returning the cooling water contained in the cold water tank to the purified water tank through the pump when the water level of the cold water tank is increased due to the ice supplied to the cold water tank. The method of claim 1, And the pump is driven when the water level of the cold water tank reaches a full water level. The method of claim 1, And the pump is operated when the water level of the cold water tank reaches a discharge set level lower than the full water level. The method of claim 1, When the water temperature of the cold water tank is lower than the set water temperature, the pump is supplied to the purified water tank by a volume corresponding to the volume of ice supplied from the ice making unit when water is required to flow into the cold water tank. Ice water purifier, characterized in that to run. The method according to any one of claims 1 to 4, The ice tray drip is selectively rotated by the drip tray rotation driving means, The ice making unit comprises an evaporator is installed so as to be immersed in the raw water for ice making accommodated in the ice tray drip. delete delete The method of claim 1, The guide member is rotated between a first position for guiding the ice generated in the ice making unit to be supplied to the ice reservoir and a second position for guiding the cold water tank to be supplied to the ice reservoir, whereby the ice generated in the ice making unit is the ice. Ice water purifier, characterized in that guided to only one side of the reservoir and the cold water tank.

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