KR20140062847A - Evaporator unit for water purifier integral vertical ellipse type - Google Patents

Abstract

The present invention relates to an integrated vertical ellipse evaporator unit for a water purifier, and, more specifically, to an integrated vertical ellipse evaporator unit for a water purifier, which comprises: an icing making body having a front side part and a rear side part to have a hollow part formed in both directions thereof, and having an ice making space part formed at the front side part and used to freeze ice making water; multiple partitions partitioning the hollow part of the ice making body into multiple parts with regular sizes, forming separated flow paths, and having an one or the other opened end part to make the separated flow paths communicate in zigzags; a first side part installed to close one end of the hollow part of the ice making body; a second side part installed to close the other end of the hollow part of the ice making body; an inlet part having a refrigerant pipe to feed a refrigerant to the flow path positioned at one edge among the flow paths; and an outlet part communicating with the flow path positioned at the other edge among the flow paths, and having a refrigerant pipe to make the refrigerant fed through the refrigerant pipe of the inlet pipe discharged through the flow paths, wherein the ice making water fed from the top part of the ice making space part, flowing along the front side part downwards, and in surface contact with the front side part is frozen into ice while the refrigerant is circulated along the flow paths of the ice making body.

Description

[0001] The present invention relates to an evaporator unit having an integral ellipsoidal evaporator for a water purifier,

[0001] The present invention relates to an evaporator unit, and more particularly, to an integral evaporator unit for a water purifier capable of improving productivity and improving ice making efficiency by improving the heat exchange rate between circulating refrigerant and deicing water, .

Generally, a water purifier is a device for purifying raw water by filters or membranes, storing the water in a storage tank, and allowing water stored in a storage tank to be collected.

Such a water purifier provides convenience by simply purifying water to supply cold water and hot water according to the user's needs, or recently supplying it to ice.

The water purifier capable of supplying ice includes an ice-making device, an ice storage box for storing ice de-iced in the ice-making device, and an ice transfer device for transferring ice so that the stored ice is discharged to the outside.

As described above, the ice water purifier according to the embodiment of the present invention includes an ice-making tray 1 provided with an ice-making space for generating ice, and ice-making water contained in the ice- And an evaporator in which the refrigerant is circulated for icing.

Here, the evaporator is a refrigerant tube 20 installed to circulate under the ice-making space of the ice-making tray 1, and as the refrigerant of low temperature and low pressure passes through the compressor, the condenser and the capillary tube and circulates below the ice- Ice is created.

However, as shown in FIG. 1, the refrigerant tube 20 is installed below the ice-making space of the ice-making tray 1 to be spaced apart from the ice-making space by a predetermined distance, and the rate of heat exchange with the ice- .

In particular, the ice-making tray 1 is formed of a nonmetal rather than a metal. The ice-making tray 1 is mainly made of a resin material having elasticity in order to easily freeze the frozen ice. This is because the heat- .

Accordingly, there is an urgent need to develop a technique for improving the heat exchange rate between the refrigerant and the ice making water to shorten the ice making time.

Accordingly, it is an object of the present invention to provide a refrigerator having an ice-making body having an ice-making space portion opened frontward, and a plurality of partition walls formed in a through-hole formed in the ice- And a refrigerant pipe is provided by the inlet and the outlet so that the ice-making water to be supplied is brought into direct contact with the ice making body, so that the contact between the ice- It is an object of the present invention to provide an integral type elliptic evaporator unit for a water purifier which can increase the area and improve the deicing efficiency.

According to an aspect of the present invention, there is provided an ice maker comprising: an ice-making body having a front portion and a rear portion, the front portion and the rear portion being bent rearward so as to form an ice- A partition wall having a plurality of openings for partitioning a plurality of inner through-holes of the ice making body into a predetermined size to form respective individual flow paths, the partition walls being open at one end or the other end so as to communicate with each other in a staggered manner, A second side part provided to close the other end of the through hole of the ice making body, an inflow part provided with a refrigerant pipe for supplying the refrigerant to a flow path located at one side edge of the flow path, And a plurality of refrigerant supplied through the refrigerant pipe communicated with the flow path located at the other side edge of the flow path and provided by the inflow portion The ice-making water supplied from the upper end of the ice-making space portion flows downward along the front portion of the ice-making body in a state where the refrigerant is purified along the flow path of the ice-making body, It is then frozen to produce ice.

Preferably, an ice-making tray provided in a front portion of the ice-making body for guiding ice-making water to the ice-making space portion and partitioning the ice-making space portion in a lateral direction to generate ice of a predetermined size, A supply nozzle for supplying de-iced water, and a de-icing pipe provided in the inlet together with the refrigerant pipe for supplying hot gas to the flow channel for ice-freezing the frozen ice.

The ice-making tray includes an upper guide portion located at the upper end of the front portion of the ice-making body and having the supply nozzle to guide the ice-making water to the ice-making space portion, And a partition formed integrally with the upper guide part and the lower guide part so as to partition the ice making space part in a plurality of directions in the lateral direction.

In addition, the ice making body is bent so that a central portion of the ice making body protrudes rearward, and a rear end of the partition of the ice-making tray is formed to be convexly protruded rearward so as to correspond to the ice-making body.

The flow path is formed in an odd number, and the inflow part is formed in any one of the first side surface part and the second side surface part, and the discharge part is formed in any one of the inflow parts.

Also, the flow path is formed in an even number, and the inflow part is formed in one of the first side surface part and the second side surface part, and the discharge part is formed in the other of the first side surface part and the second side surface part.

The partition wall is formed to be smaller than the through-hole length of the ice making body, and is provided in the through-hole. One end of one of the partition walls is installed to close the separate flow path together with the first side surface, and the other end is spaced apart from the second side surface And the other end of the adjacent other partition wall is provided together with the second side face portion so as to close the individual flow path, so that one end portion is separated from the first side portion to communicate the individual flow path.

The partition wall is formed to have the same length as the passage length of the ice making body and is provided so as to close the individual flow passage, and a communication hole is formed at one end of one of the partition walls to communicate the individual flow paths, A communication hole is formed to communicate the individual flow paths.

Further, a guide groove is formed in an inner surface of the ice-making space portion of the ice-making body for fitting the partition.

The partition wall is joined to the through hole of the ice-making body by a welding member, and the welding member is positioned along the contact portion between the partition and the ice-making body, and then they are bonded together by heating.

As described above, according to the integral type elliptical evaporator unit for a water purifier according to the present invention, it is possible to improve the heat exchange rate between the refrigerant and the deicing water to shorten the ice making time, thereby improving the productivity, Is an extremely useful and effective invention that makes it possible to improve the ice-making efficiency as it comes into surface contact with the ice-making part circulating directly inside.

1 is a view showing a conventional ice-making tray and a refrigerant pipe,
2 is a view showing an evaporator unit according to the present invention,
3 is an exploded perspective view of the evaporator unit according to the present invention,
4 is a plan view of an evaporator unit according to the present invention,
5 is a view showing another embodiment of the evaporator unit according to the present invention,
6 is a view showing another embodiment of the partition according to the present invention,
7 is a view showing an installation state of a partition according to the present invention,
8 is a view showing an installation state of an evaporator unit according to the present invention,
FIG. 9 is a side view of an installed evaporator unit according to the present invention,
FIG. 10 is a view showing a state of separation of the evaporator unit according to the present invention. FIG.

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

It should be noted that the present invention is not limited to the scope of the present invention but is only illustrative and various modifications are possible within the scope of the present invention.

FIG. 2 is a view showing an evaporator unit according to the present invention, FIG. 3 is an exploded perspective view of an evaporator unit according to the present invention, FIG. 4 is a plan view of an evaporator unit according to the present invention, FIG. 5 is a view showing another embodiment of the evaporator unit according to the present invention, FIG. 6 is a view showing another embodiment of the partition according to the present invention, FIG. 7 is a view showing the installation state of the partition wall according to the present invention FIG. 9 is a side view of the evaporator unit according to the present invention, and FIG. 10 is a side view of the evaporator unit according to the present invention. FIG. Fig.

As shown in the drawing, the integral type elliptical evaporator unit 200 for a water purifier has an ice making space portion 202 for producing ice by freezing ice-making water. The ice- Thereby freezing the iced water.

1 to 4, the ice making body 210 includes a partition 220, a flow path 230, a first side portion 240, a second side portion 250, An inflow section 260, and a discharge section 270.

The front and rear portions of the ice making body 210 are bent rearward so that the ice making body 210 has a front portion and a rear portion so that the inside of the ice making body 210 can be opened in both directions.

The partition wall 220 is provided with a plurality of partitioning portions to divide a plurality of inner holes of the ice-making body 210 into a predetermined size.

The plurality of partition walls 220 divide the inner through-holes of the ice making body 210 to form respective individual flow paths 230, and one end or the other end is opened so that the individual flow paths are communicated staggeredly.

The first side portion 240 is provided to close one end of the through hole of the ice making body 210 and the second side portion 250 is provided to close the other end of the through hole of the ice making body 210.

The inlet 260 is provided with a refrigerant pipe 20 for supplying the refrigerant to the flow path 232 located at one side edge of the flow path 230 and the outlet 270 is connected to the other side edge of the flow path 230 The refrigerant pipe 20 is provided so that the refrigerant supplied through the refrigerant pipe 20 communicated with the positioned flow path 234 and provided by the inlet 260 is discharged through a plurality of flow paths.

The circulation of the refrigerant in the ice making unit 200 causes the refrigerant to flow into the flow path 230 through the refrigerant pipe 20 connected by the inlet 260 and circulate to lower the temperature of the ice making body 210 Freezing water contained in the ice-making space portion 110 together with the ice-making tray 100 is frozen.

3 to 4, the flow path 230 is formed in an odd number, and the inflow portion 260 connects the refrigerant pipe 20 to either the first side portion 240 or the second side portion 250 And the discharge part 270 is formed in any one of the inflow parts 260.

In other words, the inflow portion 260 and the discharge portion 270 are formed on either the first side portion 240 or the second side portion 250, so that the refrigerant flows into one side of the freezing portion 200, 230, and then the refrigerant is discharged to one side of the ice-making unit 200.

5, the flow path 230 is formed in an even number, and the inflow portion 260 is formed in one of the first side portion 240 and the second side portion 250 And the discharge portion 270 is formed on the other of the first side portion 240 and the second side portion 250.

In other words, the inflow portion 260 and the discharge portion 270 are formed in the first side portion 240 and the second side portion 250, respectively, so that the coolant flows into one side of the ice making portion 200, And then the refrigerant is discharged to the other side of the ice-making unit 200.

It is a matter of course that the number of the flow paths 230 and the barrier ribs 220 is selected according to the case.

3 to 5, the partition 220 is formed to be smaller than the through-hole length of the ice-making body 210, and is installed in the through-hole.

In other words, one end of one of the partitions 220 is installed to close the individual flow path 230 together with the first side part 240, and the other end part is separated from the second side part 250 to communicate the individual flow path .

The other end of the other partition 220 is installed to close the separate flow path 230 together with the second side surface part 250 so that the one end part is separated from the first side part 240 to communicate the individual flow path 230.

6, the partition 220 is formed to have the same length as that of the ice making body 210, and a communication hole 222 is formed at one end or the other end.

In other words, a communication hole 222 is formed at one end of one of the partitions 220 to communicate the individual flow paths, and a communication hole 222 is formed at the other end of the adjacent other partitions 220, .

Accordingly, the individual flow path is formed with the flow path 230 through which the supplied refrigerant can be moved.

The partition wall 220 is joined to the through hole of the ice making body 210 by the welding member 500 and the welding member 500 is positioned along the contact portion between the partition wall 220 and the ice making body 210, It is preferable to mutually bond them.

7, a guide groove 600 is further formed in the inner surface of the through-hole of the ice making body 210, and the guide groove 400 is formed to fit the partition 220.

The partition wall 220 fitted in the guide groove 400 is preferably welded by the welding member 500.

8 to 9, the ice-making unit 200 is provided with an ice-making tray 100, a supply nozzle 300, and a de-icing tube 400.

First, the ice-making tray 100 is provided in a front portion of the ice-making body 210 to guide the ice-making water into the ice-making space portion 202, divide the ice- .

The supply nozzle 300 is provided in the ice-making tray 100 to supply de-iced water. A predetermined amount of de-iced water is jetted at a predetermined pressure to supply the front portion of the deicing body 210 downward do.

The de-icing tube 400 is provided in the inlet 260 together with the refrigerant tube 20 to supply hot gas to the flow path 230 of the ice-making unit 200 to de-iced ice, The ice that has been scooped falls to the bottom.

As shown in FIG. 10, the ice-making tray 100 includes an upper guide 110, a lower guide 120, and a partition 130.

The upper guide part 110 is located at the upper end of the front part of the ice making body 210 and is equipped with the supply nozzle 300. The upper guide part 110 guides the ice making water supplied from the supply nozzle 300 to the ice making space part 202 in the direction of the arrow.

The lower guide part 120 is positioned at the lower end of the front part of the ice making body 210 to guide the ice scooped from the ice making space part 202 downward.

A through hole 140 is formed between the upper guide part 110 and the lower guide part 120 so that the ice making space part 202 of the ice making unit 200 is opened to the front.

A plurality of partitioning walls 130 are formed at regular intervals so as to partition a plurality of the ice making space portions 202 laterally. The partitioning wall 130 is integrally formed with the upper guide portion 110 and the lower guide portion 120, .

As shown in FIG. 9, the ice making unit 200 can improve the ice making efficiency by increasing the contact area as well as directly contacting the ice making water supplied to the front portion.

Here, the refrigerant pipe 20 is provided for supplying the refrigerant to the freezing unit 200 through the compressor, the condenser, and the capillary, and the refrigerant passing through the freezing unit 200 continuously circulates along the refrigerant pipe 20 Again through the compressor, the condenser and the capillary.

To be more specific, the refrigerant traveling along the refrigerant tube is compressed to a high temperature and a high pressure by a compressor, is again heat-exchanged to a middle temperature and a high pressure by an expander, is continuously converted to a low temperature and a low pressure by a capillary, .

The refrigerant pipe 20 can be supplied with hot gas through a de-icing pipe 400 to de-iced ice in the ice-making space 110. The hot gas is a high-temperature, high-pressure refrigerant.

On the other hand, the ice can be scavenged by providing a separate heater.

Here, it is preferable that the ice-making part 200 is made of copper, stainless steel (SUS), aluminum or the like, and its surface is plated.

In one embodiment, it is plated with nickel and may be plated with other metals or non-metals as the case may be, and coating by powder coating is possible.

20: Refrigerant pipe 100: Ice-making tray
110: upper guide part 120: lower guide part
130: partition 200:
210: Deicing body 220:
230: channel 240: first side surface
250: second side portion 260: inlet portion
270: discharge part 300: supply nozzle
400: De-icing tube 500: Welding member
600: Guide groove

Claims (10)

An ice making body having front and rear parts folded rearward so as to form an ice making space for freezing ice making water in the front part,
A plurality of partition walls each having a plurality of openings for partitioning a plurality of inner through-holes of the ice making body into a predetermined size so as to form respective individual flow paths, the partition walls having one end or the other end opened so that the respective flow paths are staggered;
A first side portion provided to close one end of the through hole of the ice making body;
A second side portion provided to close the other end of the through hole of the ice making body;
An inflow portion in which a refrigerant pipe for supplying a refrigerant to a flow path located at one side edge of the flow path is installed; And
And a discharge portion in which a refrigerant pipe is installed so that the refrigerant supplied through the refrigerant pipe provided in the inflow portion and communicated with the flow path located at the other side edge of the flow path is discharged through the plurality of flow paths,
Wherein the freezing water supplied from the upper end of the ice making space portion flows downward along the front portion in a state in which the refrigerant is purified along the flow path of the ice making body to freeze the ice making water to generate ice, unit.
The method according to claim 1,
An ice-making tray provided in a front portion of the ice-making body for guiding ice-making water to the ice-making space portion and partitioning the ice-making space portion in a lateral direction to generate ice of a predetermined size;
A supply nozzle provided in the ice-making tray for supplying de-iced water;
Further comprising a de-icing tube provided in the inlet portion together with the refrigerant tube to supply hot gas to the ice making passage to freeze ice.
The ice maker according to claim 2,
An upper guide disposed at an upper end of a front portion of the ice making body to guide the ice making water to the ice making space;
A lower guide portion positioned at a lower end of a front portion of the ice making body to guide the ice removed from the ice making space portion downward; And
And a partition formed integrally with the upper guide part and the lower guide part so as to partition the ice making space part in a plurality of lateral directions.
The method of claim 3,
Wherein the ice making body is bent so that a central portion of the ice making body protrudes rearward and a rear end of the partition of the ice-making tray is convexly protruded rearward to correspond to the ice making body.
The method according to claim 1,
The flow path is formed in an odd number,
Wherein the inflow portion is formed in one of the first side surface portion and the second side surface portion, and the discharge portion is formed in any one of the inflow portion formed therein.
The method according to claim 1,
The flow path is formed in an even number,
Wherein the inflow portion is formed in one of the first side surface portion and the second side surface portion, and the discharge portion is formed in the other of the first side surface portion and the second side surface portion.
The plasma display apparatus according to claim 1,
And an opening formed in the through-hole so as to be smaller than a through-
One end of one of the partition walls is provided so as to close the individual flow path together with the first side surface portion so that the other end portion is spaced apart from the second side surface portion so that the individual flow path is communicated and the other end portion of the adjacent other partition wall And one end portion of the first and second side portions is spaced apart from the first side portion so as to communicate the individual flow paths.
The plasma display apparatus according to claim 1,
And a plurality of openings formed in the ice making body,
Characterized in that a communication hole is formed in one end of one of the partition walls so as to communicate the individual flow paths and a communication hole is formed in the other end of the adjacent other partition walls so as to communicate the individual flow paths.
The method according to claim 1,
Wherein a guide groove is formed in the inner surface of the ice making space of the ice making body to allow the partition to be fitted therein.
The plasma display apparatus according to claim 1,
Wherein the welding member is joined to the through-hole of the ice-making body by a welding member, and the welding member is positioned along a contacting portion between the partition and the ice-making body, and then they are bonded together by heating.

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