KR101316961B1 - Thermal conductivity improving structure of electric heater for ice removing of water purifier whit ice maker and installation method thereof - Google Patents

Abstract

PURPOSE: A thermal conductivity increasing structure of a deicing electric heater for an ice making purifier includes a deicing unit to be in contact with an ice-making pipe. The contact part is formed to be flat so that the surfaces are in contact with each other. The surface of the ice-making pipe and the surface of the deicing unit are stably in contact with each other by a connection unit so that the thermal conductivity increasing structure can improve thermal conductivity. CONSTITUTION: A thermal conductivity increasing structure of a deicing electric heater for an ice making purifier includes an ice-making pipe (100), a deicing unit (300), and a connection unit (300) connecting the ice-making pipe and the deicing unit. A first plane is formed on the part touching the deicing unit in the ice-making pipe, and a second plane is formed on the deicing unit so that the surface of the deicing unit is in contact with the surface of the first plane. The first plane of the ice-making pipe is connected with the second plane of the deicing unit after being in contact with the same. Heat of the deicing unit passes through the ice-making pipe and is easily transferred to a soakage pipe (200) due to the surface contact of the first plane and the second plane. A compressor is operated and deiced for each soakage pipe while an ice-making refrigerant is circulated. The connecting unit welds the first plane and the second plane touching each other and increases a mutual contact area by attaching the ice-making pipe and the deicing unit.

Description

Thermal conductivity improving structure of electric heater for ice removing of water purifier whit ice maker and installation method

The present invention relates to a thermal conductivity improving structure, and more particularly, to improve the thermal conductivity in defrosting ice produced by supplying a coolant with a low temperature and low pressure to facilitate easy defrosting, shortening an ice making cycle, and shortening a production cost. The present invention relates to an electric heater thermal conductivity improving structure for defrosting an ice water purifier, and a method of installing the same.

In general, an ice making water purifier provides convenience to users by supplying ice by purifying raw water such as tap water and freezing purified water (or cold water) as well as purified water and cold water and hot water.

Here, in the ice making unit of the water purifier, the icing water is sprayed or immersed in iced ice water to generate ice, and in recent years, an immersion system having good ice-making efficiency has been mainly used.

The immersion type ice making unit circulates a low temperature low pressure refrigerant through a compressor, a condenser, and a capillary to freeze iced water.

Then, the ice cubes are defrosted by a defrosting unit, which uses an electric heater or hot gas.

First, a defrosting unit for deicing ice using an electric heater is provided to be in contact with an ice making tube (evaporator), so that ice is defrosted by applying power when ice is generated.

However, there is a problem that the electric heater and the ice-making pipe are in contact with each other and are in contact with each other due to the contact with each other, and the thermal conductivity of the electric heater is low. To solve this problem, the compressor is stopped to stop the circulation of the refrigerant .

If the compressor is stopped once due to its characteristics, the compressor must be restarted after at least 5 minutes, and there is a problem in that an unused waiting time exists even though a defrosting time is required for about 1 to 2 minutes.

To solve this problem, dehiding using hot gas is used, as disclosed in Japanese Patent Laid-Open No. 10-2001-0035808.

1 is a view showing a schematic diagram of a conventional ice making unit, Figure 2 is a view showing a conventional ice removing structure.

As shown in the figure, the refrigerant is circulated through the compressor 4, the condenser 5, and the capillary tube 6 to the ice making tube 1 (evaporator) at a low temperature and low pressure, and the circulated refrigerant is transferred to the immersion tube 2. By passing cold air, ice-making water contained in the drip member 3 is iced to produce ice.

Here, a defrosting line (7) is formed between the compressor (4) and the condenser (5) for defrosting. The defrosting line (7) is opened by the solenoid valve (8) after the ice is produced and the compressor (4) The ice is defrosted by supplying the refrigerant (hot gas) compressed at a high temperature and high pressure to the ice making pipe (1).

This defrosting method has an advantage of shortening the ice making cycle as it can be defrosted while the compressor 4 is continuously operated.

However, when the refrigerant circulation path is changed by the solenoid valve 8, the refrigerant circulating to the ice-making line 7 is circulated to generate noises and the refrigerant collides with the solenoid valve 8, Is generated.

In addition, the defrosting method using the hot gas has a problem that the production cost is increased compared to the defrosting method using an electric heater.

Accordingly, there is an urgent need to develop a deicing method capable of shortening an ice making cycle, preventing noise and vibration, and lowering production costs to improve product competitiveness.

Therefore, the present invention has been devised to solve the above problems, provided with a defrosting means for contacting the ice making tube to generate heat by applying power, the contact portion is formed flat to contact each other, the coupling By making the surface contact with the ice-making pipe and the ice-breaking means by means, the thermal conductivity can be improved, so that the generated ice can be defrosted even while the refrigerant for ice-making is circulated, thereby shortening the ice-making cycle time. It is an object of the present invention to provide an electric heater thermal conductivity improving structure for deicing ice water purifiers and a method of installing the same, which can reduce production costs and improve product competitiveness.

The present invention for achieving the above object, the refrigerant supplied through the compressor, the condenser and the capillary for the ice is supplied along the inner flow path, the ice making pipe having a plurality of installation holes on one surface, provided in each installation hole of the ice making pipe And an ice making space portion open to one side to be in communication with the inner flow path, and has a flow path partition to block the ice making space portion and the inner flow path formed with the installation hole so that only the other side of the ice making space portion is not opened. Immersion pipe immersed in ice-making water for the generation, by the power applied to the defrosting means for defrosting the ice in the periphery of the immersion pipe as the heat is transferred to the ice-making pipe, and the ice-making pipe And a decoupling means for coupling the deicing means to be in contact with each other, wherein the ice making pipe has a first plane at a portion in contact with the deicing means. Is formed, and a second plane portion is formed in the ice removing means so as to be in surface contact with the first plane portion, and the first plane portion of the ice making pipe and the second plane portion of the ice removing means are mounted to be in surface contact with each other. And coupled to the coupling means, and the compressor is operated as the heat of the defrosting means is easily transferred to each of the immersion pipes through the ice making pipe by the surface contact of the first and second flat parts. In the state where the refrigerant is circulated, the ice in each dip tube may be defrosted.

Preferably, the coupling means, by welding the first plane portion and the second plane portion in contact with each other to join the ice making pipe and the defrosting means to increase the mutual contact area.

The coupling means may include a first bracket provided to surround an upper end of the ice removing means, a second bracket provided to enclose a lower end of an ice making tube in which the immersion tube is not installed, and a first flat portion of the ice making tube. And a fixing member for fixing the first bracket and the second bracket to each other such that the second flat portion of the ice removing means is in surface contact.

In addition, the ice-making pipe and the ice-breaking means may be bent at a central portion such that both ends thereof are positioned in the same direction, and the first bracket may have a first seating groove formed along an edge to surround the upper end of the ice-breaking means, It is formed to protrude downward to be located inside the bent deicing means, the second bracket is formed with a second seating groove along the edge to surround the lower end of the ice making pipe, the central portion of the inside of the bent ice pipe It is formed to protrude upwards to be located in.

In addition, the position where the central portion of the first bracket and the central portion of the second bracket are in contact with each other is the same as the position at which the ice-making pipe and the ice-breaking means are in surface contact.

In addition, the fixing member is any one or more selected from bolts and nuts or rivets or welding.

In addition, the refrigerant supplied through the compressor, the condenser and the capillary for ice making is supplied along the inner flow path, and is provided in each of the installation holes of the ice making pipe and the ice making pipe having a plurality of installation holes on one surface to communicate with the internal flow path. An ice making space part is formed at one side, and has a flow path partition that blocks an inner flow path in which the ice making space part and the installation hole are formed so that only the other side of the ice making space part is not opened, and is immersed in ice making water for ice making. Defrosting means for generating heat by the branch pipe and the applied power is provided, the defrosting means for defrosting the ice ice in the periphery of the immersion tube as the heat is transferred to the ice making tube, the ice making tube in contact with the ice removing means Forming a first flat portion to form a portion of the flat portion, and flattening a portion of the ice-removing means so as to be in surface contact with the first flat portion. Forming a second flat portion, the first flat portion of the ice making pipe and the second flat portion of the ice-breaking means are mounted so as to be in contact with each other, and then a coupling step of coupling by coupling means, and the refrigerant is heated by the compressor. A refrigerant compression step of compressing the high pressure, a refrigerant condensation step of condensing the high temperature and high pressure refrigerant to a medium temperature high pressure by a condenser, a refrigerant changing step of changing the medium temperature high pressure refrigerant to a low temperature low pressure by a capillary tube, and a low temperature low pressure An ice making step in which the refrigerant circulates along the inner flow path of the ice making pipe and the ice making space portion of each immersion pipe to make ice making water ice to the lateral side of each immersion pipe, and to generate ice; The defrosting step of defrosting ice in each immersion tube as heat generated by applying power is transferred to each immersion tube through the ice making tube. Is done by also, the talbing step is done in the process that the refrigerant compression step and a refrigerant condensation step, the refrigerant changes phase continuously repeated, if blocking the applied power to the de-icing, however, that the ice-making step is repeated.

In addition, the joining step may increase the mutual contact area by welding the first plane portion and the second plane portion which are in surface contact with each other to bond the ice making pipe and the ice removing means.

The coupling means may include a first bracket, a second bracket, and a fixing member, and the coupling step includes: a first bracket mounting step of wrapping the upper end of the detaching means using the first bracket and the second bracket; The second bracket mounting step of wrapping the lower end of the ice-making pipe is not installed using the immersion pipe, and using the fixing member so that the first flat portion of the ice-making pipe and the second flat portion of the ice removing means surface contact And a fixing step of fixing the first bracket and the second bracket to each other.

As described above, according to the structure of the electric heater thermal conductivity improving structure for ice removal of ice water purifier according to the present invention and its installation method, the thermal conductivity can be improved by conventional surface contact between the ice making pipe and the ice removing means. As a result of the improvement, ice can be defrosted even in the state in which the refrigerant for ice making is supplied to the ice making pipe, and thus, the conventional compressor stopping process can be omitted, and the ice making cycle time can be reduced by eliminating the compressor stopping process. It is a very useful and effective invention that makes it easy to defrost ice.

1 is a view showing a schematic diagram of a conventional ice making unit,
2 is a view showing a conventional ice making structure,
3 is a view showing a structure for improving the thermal conductivity of the electric heater for defrosting according to the present invention,
4 is a view showing a side view of the thermal conductivity improving structure according to the present invention,
5 is a view showing another embodiment of the thermal conductivity improving structure according to the present invention;
6 is a view showing a side view of the thermal conductivity improving structure according to another embodiment;
7 is a view showing a coupling means according to another embodiment,
8 is a view showing a method of installing an electric heater thermal conductivity improving structure for ice-water purifier according to the present invention.

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.

Figure 3 is a view showing a thermal conductivity improving structure of the electric heater for defrosting according to the present invention, Figure 4 is a view showing a side view of the thermal conductivity improving structure according to the present invention, Figure 5 is another of the thermal conductivity improving structure according to the present invention 6 is a view showing a side view of a thermal conductivity improving structure according to another embodiment, FIG. 7 is a view showing a coupling means according to another embodiment, and FIG. 8 is according to the present invention. FIG. 1 is a view illustrating a method of installing an electric heater thermal conductivity improving structure for ice removal of an ice water purifier. FIG.

As shown in the figure, the thermal conductivity improving structure of the ice maker 10 for water purifier is composed of an ice making tube 100 and an immersion tube 200, a deicing means 300 and a coupling means 400.

The ice making pipe 100 is a refrigerant supplied through an compressor, a condenser and a capillary tube 6 for ice making along an internal flow path, and a refrigerant for ice making ice is circulated.

Here, the coolant circulation process of the purifier for ice making is described as follows. A coolant pipe for supplying coolant to the ice making pipe 100 is provided to supply the coolant. The coolant is connected to the coolant pipe to compress the coolant to high temperature and high pressure Thereby circulating the refrigerant.

The capillary is heat-exchanged in the condenser to convert the circulating refrigerant into a low-temperature and low-pressure, and supplies the refrigerant to the ice-making tube 100.

At this time, the capillary tube is formed into a coil shape, and its inner diameter is smaller than that of the refrigerant tube.

The ice making tube 100 is formed with a plurality of installation holes on one surface, the installation hole is preferably formed on the lower side or the upper side of the ice making tube 100 according to the position where the immersion tube 200 is to be installed.

In an embodiment of the present invention, a plurality of installation holes are formed in the lower side of the ice making pipe 100.

In addition, the immersion pipe 200 is immersed in ice making water for ice making, and is provided in each installation hole of the ice making pipe 100 to have an ice making space part open to one side to communicate with an internal flow path.

At this time, a flow path partition is provided to block the inner flow path in which the ice making space and the installation hole are formed so that only the other side of the ice making space is not opened, thereby circulating the refrigerant through the other side of the immersion pipe 200.

Accordingly, each of the immersion tubes 200 can freeze the iced water outside, thereby easily generating ice.

The ice-breaking means 300 generates heat by the applied power and conducts the heat to the upper side of the ice-making pipe 100 so as to de-ice ice iced around the immersion pipe 200.

The coupling means 400 couples the ice making tube 100 and the de-iced water stage 300 so that they are in contact with each other.

At this time, the contact portion of the ice making tube 100 and the ice-breaking means 300 is formed flat to be in contact with each other, it is coupled to each other by the coupling means (400).

In other words, the ice making tube 100 has a first flat portion 110 formed at a portion in contact with the ice removing means 300, and the ice making tube 100 is formed at the ice removing means 300 so as to be in surface contact with the first flat portion 110. The two plane portion 300 is formed.

Here, the first plane portion 110 and the second plane portion 300 is preferably formed by rolling by a press device (not shown).

The first flat portion 110 of the ice making tube 100 and the second flat portion 310 of the defrosting means 300 are mounted to be in contact with each other, and then coupled by the coupling means 400.

As a result, the surface contact ratio between the ice making tube 100 and the de-iced water end 300 is improved, so that the heat of the de-iced water end 300 is easily conducted to the ice making tube 100, As the heat is easily conducted to each of the immersion tubes 200, the ice can be easily rinsed.

In addition, as the thermal conductivity is improved to the ice making pipe 100 which is in surface contact with the ice removing means 300, the compressor is operated so that heat is transferred to each of the immersion pipes 200 even when the refrigerant for ice making is circulated to defrost ice generated. You can.

Thus, the process of stopping the compressor for the conventional defrosting can be omitted, thereby shortening the ice making cycle and improving the ice production rate.

In addition, by omitting the process of selectively changing the flow of the conventional refrigerant, it is possible to prevent the collision noise or vibration in the valve to move to each pipe.

Here, the coupling means 400, as shown in Figures 3 and 4, as well as firmly contacting by welding the ice making pipe 100 and the defrosting means 300 in mutual contact with each other, as well as ice making by the welding site The surface contact portion of the pipe 100 and the ice-breaking means 300 is also increased to transfer the heat of the ice-breaking means 300 to each immersion pipe 200 through the ice-making pipe 100.

5 and 6, a coupling means 400 'of another embodiment may be provided to fix the ice making tube 100 and the de-iced water end 300 so as to be in contact with each other.

Here, the ice-making pipe 100 and the ice-breaking means 300 are bent at a central portion so that both ends thereof are positioned in the same direction, and the coupling means 400 ′ mutually connects the ice-making pipe 100 and the ice-breaking means 300 to each other. To be brought into surface contact.

As shown in FIG. 7, the coupling means 400 ′ includes a first bracket 410 ′, a second bracket 420 ′, and a fixing member 430 ′.

The first bracket 410 'is provided to surround the upper end of the ice-breaking means 300, and the second bracket 420' is provided to surround the lower end of the ice-making pipe 100 in which the immersion pipe 200 is not installed. do.

Here, the first bracket 410 ′ is formed with a first seating groove 410 a ′ along an edge of the first bracket 410 ′ so as to surround the upper end of the ice breaking means 300, and the center portion 410 b ′ is bent with the ice breaking means 300. It is formed to protrude downward so as to be located inside of.

The second bracket 420 'is formed with a second seating groove 420a' along the edge of the second bracket 420 'to surround the lower end of the ice making tube 100, and the center portion 420b' is formed inside the bent ice making tube 100. Protrude upwards to be positioned.

The center portion 410b 'of the first bracket 410' and the center portion 420b 'of the second bracket 420' are in contact with each other at a position where the ice making tube 100 and the de-iced water end 300 are in surface contact with each other And are preferably located at the same height.

Of course, a position where the central portion 410b 'of the first bracket 410' and the central portion 420b 'of the second bracket 420' are in contact with each other may be located inside the ice making tube 100 or the ice removing means ( 300 may be located inside.

The fixing member 430 ′ fixes the first bracket 410 ′ and the second bracket 420 ′. As the fixing member 430 ′ firmly fixes the first bracket 410 ′ and the second bracket 420 ′, The detaching means 300 and the immersion pipe 200 can be firmly in contact with the surface.

The fixing member 430 'is any one or more selected from bolts and nuts or rivets or welding, and it is preferable to select firmly to fix the first bracket 410' and the second bracket 420 '. .

Referring to the method of installing the thermal conductivity improving structure of the icemaker 10 for water purifier, as shown in FIG. 8, the first planar part forming step S10 and the second planar part forming step S20 are combined. It consists of a step (S30), a refrigerant compression step (S40), a refrigerant condensation step (S50), a refrigerant change step (S60), an ice making step (S70) and a defrosting step (S80).

First, referring to the thermal conductivity improving structure of the ice maker 10 of the water purifier, the refrigerant supplied through the compressor, the condenser, and the capillary tube 6 for ice making is supplied along an internal flow path, and has an ice making tube having a plurality of installation holes on one surface thereof. 100 is provided.

An ice making space is provided in each of the installation holes of the ice-making pipe 100 so as to communicate with the internal flow passage. The ice making space is opened to one side of the ice- And a plurality of immersion tubes 200 are immersed in ice-making water for ice-making.

In addition, a heat generating means 300 generates heat by an applied power source, and as the heat is transferred to the ice making pipe 100, a defrosting means 300 is provided to defrost ice that has been iced around the immersion pipe 200.

In the forming of the first plane portion (S10), the first plane portion 110 is formed in the ice making tube 100 by forming a flat portion of the ice making tube 100 in contact with the ice removing means 300.

In the forming of the second flat portion S20, the portion of the ice removing means 300 is formed flat so as to be in surface contact with the first flat portion 110 so that the second flat portion 310 is formed on the ice removing means 300. Is formed.

Joining step (S30) is mounted so that the first plane portion 110 of the ice making tube 100 and the second plane portion 310 of the defrosting means 300 are in contact with each other, by the coupling means 400 They are joined together.

In addition, the refrigerant compression step (S40) is a refrigerant is compressed to a high temperature and high pressure by the compressor, the refrigerant condensation step (S50) is a high temperature and high pressure refrigerant condensed to a medium temperature high pressure by the condenser, the refrigerant change step (S60) of the medium temperature high pressure The refrigerant is changed characteristics at low temperature and low pressure by the capillary tube 6.

The refrigerant changed to low temperature and low pressure is circulated along the inner flow path of the ice making pipe 100 and the ice making space of each immersion pipe 200 in the ice making step S70 to make ice making ice out of each immersion pipe 200 to ice the ice. Will be generated.

In the defrosting step S80, after the ice is generated for a predetermined time, the heat generated by applying power to the de-icing water stage 300 is conducted to the respective irrigation tubes 200 through the ice making tube 100, So that it dries in the branch pipe 200.

 At this time, the defrosting step (S80) is made in the process of repeating the refrigerant compression step (S40), the refrigerant condensation step (S50), the refrigerant change step (S60) continuously, to cut off the power applied to the defrosting means (300) In this case, the ice making step S70 is repeated.

Thus, ice can be produced at regular time intervals without stopping the compressor.

Here, the coupling means 400 of the coupling step (S30) is welded to the ice making pipe 100 and the ice removal means 300 by welding the first plane portion 110 and the second plane portion 310 in contact with each other. By doing so, the area of contact is increased by the welded area.

Thus, the heat conductivity of the de-icing water stage 300 can be improved, and the ice of each of the intestinal tracts 200 can be easily rinsed.

Meanwhile, the coupling means 400 'of another embodiment is composed of the first bracket 410', the second bracket 420 'and the fixing member 430'.

The engaging step S30 using the engaging means 400 'comprises a first bracket mounting step S31, a second bracket mounting step S32 and a fixing step S33.

The first bracket mounting step S31 surrounds the upper end of the defrosting means 300 by using the first bracket 410 ', and the second bracket mounting step S32 stitches by using the second bracket 420'. Branch pipe 200 is wrapped around the lower end of the ice making tube 100 is not installed.

In the fixing step S33, the first flat portion 110 of the ice-making tube 100 and the second flat portion 310 of the de-iced water end 300 are brought into surface contact with each other using the fixing member 430 ' So that the bracket 410 'and the second bracket 420' are fixed to each other.

Accordingly, as the ice making tube 100 and the ice making means 300 are firmly in contact with each other, the heat of the ice making means 300 is easily conducted to the ice making tube 100 so that the ice of each immersion tube 200 is maintained. Can be easily defrosted.

10: Deicing device 100:
110: first plane portion 200: immersion pipe
300: defrosting means 310: second plane portion
400, 400 ': coupling means 410': first bracket
410a ': first seating groove 410b': center part
420 ': second bracket 420a': second seat groove
420b ': center portion 430': holding member

Claims (9)

An ice making tube having a plurality of installation holes on one surface of the refrigerant supplied through the compressor, the condenser, and the capillary to be deiced along the inner flow path;
An ice making space is formed in each of the installation holes of the ice making tube so as to communicate with the internal flow passage and is opened to one side of the ice making space, And an immersion tube immersed in ice-making water for ice-making;
Defrosting means for generating heat by an applied power source and deicing ice iced around the immersion tube as the heat is transferred to the ice making tube; And
And an engaging means for engaging the ice making tube and the de-icing water end so as to be in contact with each other,
The ice making tube is formed with a first flat portion in contact with the ice removing means,
A second plane portion is formed in the ice removing means so as to be in surface contact with the first plane portion,
After the first flat portion of the ice making pipe and the second flat portion of the ice removing means are mounted so as to be in contact with each other, and is coupled by the coupling means,
As the heat of the ice-breaking means is easily transferred to each of the immersion pipes by the surface contact of the first and second plane parts, the compressor is operated so that each immersion pipe is in a state where the refrigerant for ice-making is circulated. Ice can be thawed
Wherein the coupling means comprises:
An electric heater thermal conductivity improving structure for ice-water purifiers, characterized in that the mutual contact area is increased by welding the first flat part and the second flat part which are in contact with each other.
delete An ice making tube having a plurality of installation holes on one surface of the refrigerant supplied through the compressor, the condenser, and the capillary to be deiced along the inner flow path;
An ice making space is formed in each of the installation holes of the ice making tube so as to communicate with the internal flow passage and is opened to one side of the ice making space, And an immersion tube immersed in ice-making water for ice-making;
Defrosting means for generating heat by an applied power source and deicing ice iced around the immersion tube as the heat is transferred to the ice making tube; And
And an engaging means for engaging the ice making tube and the de-icing water end so as to be in contact with each other,
The ice making tube is formed with a first flat portion in contact with the ice removing means,
A second plane portion is formed in the ice removing means so as to be in surface contact with the first plane portion,
After the first flat portion of the ice making pipe and the second flat portion of the ice removing means are mounted so as to be in contact with each other, and is coupled by the coupling means,
As the heat of the ice-breaking means is easily transferred to each of the immersion pipes by the surface contact of the first and second plane parts, the compressor is operated so that each immersion pipe is in a state where the refrigerant for ice-making is circulated. Ice can be thawed
Wherein the coupling means comprises:
A first bracket provided to surround an upper end of the de-iced water end;
A second bracket disposed to surround a lower end portion of the ice making tube without the immersion tube; And
And a fixing member for fixing the first bracket and the second bracket to each other such that the first flat portion of the ice making pipe and the second flat portion of the ice removing means are in surface contact with each other.
The method of claim 3,
A central portion of the ice making pipe and the ice removing means are bent to form both ends in the same direction.
The first bracket has a first seating groove is formed along the edge to surround the upper end of the detaching means, the central portion is formed to protrude downward to be located inside the bent detaching means,
The second bracket has a second seating groove is formed along the edge to surround the lower end of the ice-making pipe, the center portion is for ice removal of the ice water purifier, characterized in that protruding upwards to be located inside the bent ice-making pipe. Electric heater thermal conductivity improvement structure.
5. The method of claim 4,
The position at which the central portion of the first bracket and the central portion of the second bracket are in contact with each other is the same as the position at which the ice making pipe and the ice removing means are in surface contact with each other.
The method of claim 3, wherein the fixing member,
An electric heater thermal conductivity improving structure for deicing ice water purifier, characterized in that at least one selected from bolts and nuts or rivets or welding.
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