KR20190026405A - Evaporator for ice maker - Google Patents

Abstract

An evaporator for an ice maker is disclosed. According to an embodiment of the present invention, the evaporator for an ice maker comprises: an evaporator body in which a refrigerant flow path is formed; an ice forming unit connected to the evaporator body, wherein water is in contact with at least a portion to form ice in a state in which refrigerant less than a freezing point flows in the refrigerant flow path; and an ice removing unit provided for at least a portion thereof to be inserted into the refrigerant flow path, wherein an ice removing fluid more than the freezing point flows for ice to be separated from an ice forming unit.

Description

{EVAPORATOR FOR ICE MAKER}

The present invention relates to an evaporator used in an ice maker for making ice.

The ice maker is making ice. To this end, the ice maker includes an evaporator through which refrigerant flows.

When water contacts at least a part of a member connected to the evaporator or the evaporator in a state where a refrigerant having a freezing point or lower flows into the evaporator, ice is formed in the member connected to the evaporator or the evaporator.

If ice cubes of a predetermined size are formed in a member connected to the evaporator or the evaporator, the ice should be separated from the evaporator or the member connected to the evaporator.

For this purpose, conventionally, the evaporator is heated by causing a refrigerant above the freezing point to flow to the evaporator or by providing a heater outside the evaporator.

However, when the refrigerant above the freezing point causes the refrigerant to flow to the evaporator, noises are generated in the flow path switching valve used for this purpose, and when the evaporator is provided with a heater outside the evaporator, the evaporator is heated to a high temperature and resistance to corrosion is lowered.

The present invention is realized by recognizing at least any one of the above-mentioned conventional needs or problems.

One aspect of the present invention is to minimize the occurrence of noise during the separation of ice formed by the evaporator and to prevent the deterioration of the resistance to corrosion of the evaporator by separating the ice formed by the evaporator.

Another aspect of the present invention is that a driving unit for separating ice formed by an evaporator is inserted at least partially into a refrigerant passage formed in an evaporator so that refrigerant flows, and a deicing fluid flowing above a freezing point flows inside.

An evaporator for an ice maker according to an embodiment for realizing at least one of the above problems may include the following features.

An evaporator for an ice maker according to an embodiment of the present invention includes an evaporator body having a refrigerant passage formed therein; An ice forming unit connected to the evaporator body and having ice formed by contacting water at least in a state where a coolant having a temperature equal to or lower than a freezing point flows in the coolant channel; And at least a part of which is inserted into the refrigerant passage, and an ice-making fluid exceeding a freezing point flows into the ice-making unit, so that ice is separated from the ice-forming unit. . ≪ / RTI >

In this case, the ice-breaking unit may include at least a part of the ice-making fluid flow tube inserted into the refrigerant flow path and through which the ice-breaking fluid flows.

The deicing fluid flow pipe may have a shape corresponding to a shape of at least a part of the evaporator body.

The deicing fluid flow tube may be made of a thermally conductive material.

The deicing unit may further include a deicing fluid supply source connected to the deicing fluid flow pipe to supply the deicing fluid to the deicing fluid flow pipe.

The deicing fluid may be air, and the deicing fluid supply source may include a blowing fan connected to the deicing fluid flow tube.

The deicing fluid may be an antifreeze, the deicing fluid supply source may be connected to the deicing fluid flow tube, and may include an antifreeze tank storing an antifreeze fluid, and a pump connected to the antifreeze fluid flow pipe.

The deicing fluid may be hot water, and the deicing fluid supply source may include a hot water generating unit connected to the deicing fluid flow pipe and a heater provided in the hot water generating unit.

The deicing fluid supply source may further include a pump connected to the hot water generating unit and the deicing fluid flow pipe.

The deicing fluid supply source may further include a heater provided in an antifreeze tank included in the deicing fluid flow source or the deicing fluid supply source.

In addition, the evaporator body may be formed with an insertion hole through which the ice removing unit passes to be inserted into the refrigerant passage.

The ice forming unit may include an immersion member connected to the evaporator body and at least a part of which is submerged in water to form ice.

In addition, the evaporator main body may be formed with a connection hole to which the immersion member is connected.

The immersion member may have a connection space connected to the refrigerant channel so that the refrigerant flowing through the refrigerant channel may flow.

The immersion member may be provided with a partitioning member for partitioning the connection space into a refrigerant inflow path from which the refrigerant flows from the refrigerant flow path and a refrigerant outflow path through which the refrigerant flows out from the refrigerant flow path.

The partition member may be formed with a communication hole communicating the refrigerant inflow passage and the refrigerant outflow passage so that the refrigerant of the refrigerant inflow passage flows to the refrigerant outflow passage.

Further, the partition member may extend through the refrigerant passage to the evaporator body.

The partition member may contact the immersion member and the evaporator body.

Further, a passage portion through which the ice-breaking unit passes may be formed in the partitioning member.

Further, the ice removing unit can contact the passing portion.

As described above, according to the embodiment of the present invention, at least a part of the ice-making unit separating the ice formed by the evaporator is inserted into the refrigerant passage formed in the evaporator so that the ice-breaking fluid above the freezing point can flow therein.

In addition, according to the embodiment of the present invention, the occurrence of noise during the separation of ice formed by the evaporator is minimized and the resistance to corrosion of the evaporator may not be deteriorated by separating the ice formed by the evaporator.

1 is a perspective view of a first embodiment of an evaporator for an ice maker according to the present invention.
2 is an exploded perspective view of a first embodiment of an evaporator for an ice maker according to the present invention.
3 is a cross-sectional view taken along a line I-I 'in Fig.
4 is a cross-sectional view taken along the line II-II 'in FIG.
5 is a cross-sectional view showing the operation of the first embodiment of the evaporator for an ice maker according to the present invention, illustrating the ice making process.
FIG. 6 is a cross-sectional view showing the operation of the first embodiment of the evaporator for an ice maker according to the present invention, illustrating deicing.
7 is a perspective view of a second embodiment of an evaporator for an ice maker according to the present invention.
8 is a perspective view of a third embodiment of an evaporator for an ice maker according to the present invention.

Hereinafter, an evaporator for an ice maker according to an embodiment of the present invention will be described in detail in order to facilitate understanding of the features of the present invention.

Hereinafter, the embodiments will be described on the basis of embodiments best suited for understanding technical features of the present invention, and the technical features of the present invention are not limited by the illustrated embodiments, It is to be understood that the invention can be practiced with embodiments. Therefore, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents. In order to facilitate the understanding of the embodiments described below, in the reference numerals shown in the accompanying drawings, among the constituent elements that perform the same function in the respective embodiments, the related constituent elements are indicated by the same or an extension line number.

First Embodiment of an Evaporator for an Ice Maker

Hereinafter, a first embodiment of an evaporator for an ice maker according to the present invention will be described with reference to FIGS. 1 to 6. FIG.

FIG. 1 is a perspective view of a first embodiment of an evaporator for an ice maker according to the present invention, FIG. 2 is an exploded perspective view of a first embodiment of an evaporator for an ice maker according to the present invention, and FIG. 3 is a sectional view taken along the line I- And Fig. 4 is a cross-sectional view taken along the line II-II 'in Fig.

6 is a cross-sectional view showing the operation of the first embodiment of the evaporator for an ice maker according to the present invention, and FIG. 6 is a cross-sectional view showing the operation of the first embodiment of the evaporator for an ice maker according to the present invention, Respectively.

A first embodiment of an evaporator 100 for an ice maker according to the present invention may include an evaporator body 200, an ice forming unit 300, and a driving unit 400.

3, the refrigerant passage R is formed in the evaporator main body 200 to allow the refrigerant to flow as shown in FIG.

A connection pipe T communicating with the refrigerant flow path R may be connected to one side and the other side of the evaporator main body 200, respectively. For this purpose, for example, as shown in FIG. 2, one side and the other side of the evaporator main body 200 are closed by a blocking member CL having a tube connecting hole HI to which the connecting tube T is connected have.

A connection pipe T connected to one side of the evaporator main body 200 is connected to an expansion valve or a capillary pipe (not shown) of the refrigeration cycle and a connection pipe T connected to the other side is connected to a compressor . Accordingly, the refrigerant flows from the expansion valve or the capillary of the refrigeration cycle to the evaporator body 200, and can flow into the refrigerant flow path R of the evaporator body 200. The refrigerant flowing into the refrigerant passage R of the evaporator main body 200 may flow into the compressor of the refrigeration cycle after flowing through the refrigerant passage R as shown in FIG.

The evaporator main body 200 may have a U-shaped tubular shape as shown in FIGS. However, the shape of the evaporator body 200 is not particularly limited, and any shape can be used as long as the refrigerant flow path R through which the refrigerant flows can be formed.

An insertion hole H may be formed in the evaporator main body 200. For example, as shown in FIG. 2, not only the above-mentioned pipe connection hole HT but also an insertion hole H are formed in the above-described blocking member CL which blocks the opened one side and the other side of the evaporator body 200 . At least a part of the ice-breaking unit 400 can be inserted into the refrigerant passage R of the evaporator body 200 through the insertion hole H.

The evaporator main body 200 may be formed with a member connection hole HC as shown in Figs. 3 and 4. The immersion member 310 to be described later included in the ice forming unit 300 can be connected to the evaporator body 200 through the member connecting hole HC.

The evaporator body 200 may be made of a thermally conductive material. For example, the evaporator main body 200 may be made of a metal such as stainless steel. However, the material forming the evaporator main body 200 is not particularly limited, and any material can be used as long as it is a material from which the refrigerant flow path R can be formed.

The ice forming part 300 may be connected to the evaporator body 200. In the ice forming part 300, water may contact at least a part of the refrigerant flowing in the refrigerant passage R of the evaporator main body 200 in the state where the refrigerant below the freezing point flows, and the ice I may be formed.

The ice forming part 300 may include, for example, an immersion member 310. [ The immersion member 310 may be connected to the evaporator body 200. The immersion member 310 may be welded to the evaporator body 200 and connected to the evaporator body 200 in a state where one end of the immersion member 310 is inserted into the member connection hole HC formed in the evaporator body 200. However, the structure in which the immersion member 310 is connected to the evaporator body 200 is not particularly limited, and any well-known construction such as fitting or connecting with an adhesive is possible.

The immersion member 310 may be at least partially submerged. For example, as shown in FIG. 5, the immersion member 310 may be at least partially submerged in the water contained in the tray member TR. In this state, ice (I) may be formed in the immersion member 310 when a coolant of a freezing point or lower flows into the refrigerant flow path R of the evaporator main body 200.

The immersion member 310 may have a connection space SC connected to the refrigerant passage R of the evaporator body 200 as shown in FIGS. 5, the refrigerant flowing through the refrigerant flow path R of the evaporator body 200 can flow through the connection space SC of the immersion member 310, i.e., the immersion member 310. As shown in FIG. Thereby, the immersion member 310 is cooled more quickly by the coolant below the freezing point, and the ice I can be formed on the immersion member 310 more quickly and easily.

The immersion member 310 may be provided with a partitioning member 311. The connecting space SC of the immersion member 310 can be partitioned into the refrigerant inflow path RI and the refrigerant outflow path RO by the partitioning member 311 as shown in FIG. A communication hole 311a is formed in the partition member 311 so that the refrigerant inflow passage RI and the refrigerant outflow passage RO partitioned by the immersion member 310 can communicate with each other.

The refrigerant flowing through the refrigerant flow path R of the evaporator main body 200 may be introduced into the refrigerant inflow path RI of the connection space SC of the immersion member 310 as shown in FIG. The refrigerant in the refrigerant inflow passage RI may flow to the refrigerant outflow passage RO in the connection space SC of the immersion member 310 through the communication hole 311a of the immersion member 310. [ The refrigerant can flow into the refrigerant flow path R of the evaporator body 200 through the refrigerant outflow path RO of the connection space SC of the immersion member 310 and flow through the refrigerant flow path R. [

3 and 4, the partition member 311 may extend to the evaporator body 200 through the refrigerant passage R of the evaporator body 200. [ The refrigerant flowing through the refrigerant passage R of the evaporator main body 200 can flow through the connection space SC of the immersion member 310. [

In this configuration, the partition member 311 can contact the immersion member 310 and the evaporator body 200. In addition, a passage portion 311b may be formed in the partition member 311. [ A part of the ice-removing unit 400 inserted into the refrigerant passage R of the evaporator body 200 can pass through the passage portion 311b of the partition member 311. [ Then, the driving unit 400 can contact the passing portion 311b of the partition member 311. [

6, when heat is transferred from the ice-breaking unit 400 inserted into the refrigerant passage R of the evaporator body 200 through the partition member 311 to the immersion member 310 So that the separation of the ice I from the immersion member 310 can be made easier.

The immersion member 310 and the partition member 311 may be made of a thermally conductive material. For example, the immersion member 310 and the partition member 311 may be made of a metal such as stainless steel. The material forming the submerging member 310 and the partitioning member 311 is not particularly limited and may be any material that can be connected to the evaporator main body 200 or provided with the immersion member 310 .

The structure of the ice-making unit 300 is not particularly limited, and any known structure such as an ice-making frame (not shown) connected to the evaporator body 200 and spraying or flowing water may be used.

At least a part of the driving unit 400 may be inserted into the refrigerant passage R of the evaporator body 200. For example, the ice-breaking unit 400 may be inserted into the refrigerant passage R of the evaporator body 200 through the insertion hole H of the evaporator body 200 described above.

Then, the ice-breaking fluid above the freezing point can flow into the ice-breaking unit 400. Thus, heat is transferred from the ice-breaking fluid flowing through the ice-breaking unit 400 to the ice I so that the ice I formed in the ice-making unit 300 can be separated from the ice-making unit 300.

6, when the ice-breaking fluid flows into the ice-breaking unit 400 in a state in which the tray member TR is rotated so as not to interfere with the separation of the ice I, The ice I formed on the immersion member 310 of the ice forming unit 300 can be separated from the immersion member 310.

Since the ice I is separated from the ice forming part 300 by the heat transferred from the ice-breaking fluid flowing in the ice-breaking unit 400, the refrigerant over the freezing point is discharged to the refrigerant flow path R A flow path switching valve (not shown) or the like for making the flow of the refrigerant gas to the refrigerant circuit (not shown). Therefore, noise can be minimized during the separation of ice (I).

At least a part of the ice-breaking unit 400 is inserted into the refrigerant passage R of the evaporator main body 200 and contacts the refrigerant present in the refrigerant passage R. Therefore, the evaporator body 200 and the ice- The immersion member 310 or the like of the ice making unit 300 is not heated to a high temperature by the heat transferred from the ice-breaking fluid flowing inside the ice-making unit 400, and the ice I formed in the ice- Lt; / RTI >

Accordingly, the resistance to corrosion of the evaporator 100 for the ice maker may not be lowered.

The defrosting unit 400 may include a defrosting fluid flow pipe 410 through which the defrosting fluid flows. Any known means may be used as long as the deicing fluid flow pipe 410 is not particularly limited, and the deicing fluid can flow.

At least a portion of the deicing fluid flow pipe 410 may be inserted into the refrigerant passage R of the evaporator body 200. For example, the deicing fluid flow pipe 410 may be inserted into the refrigerant passage R of the evaporator body 200 through the insertion hole H of the evaporator body 200.

The deicing fluid flow pipe 410 may have a shape corresponding to at least a part of the evaporator body 200. Accordingly, at least a part of the ice-making fluid flow pipe 410 can be easily inserted into the refrigerant flow path R of the evaporator body 200. For example, the deicing fluid flow pipe 410 may be U-shaped as shown in FIG. In this case, a straight-type deicing fluid flow pipe 410 is inserted into the evaporator body 200 through the insertion hole H of the blocking member CL, 410 can be bent together into a U-shape.

However, the shape of the deicing fluid flow pipe 410 is not particularly limited and may be any shape as long as it corresponds to at least a part of the evaporator body 200.

The deicing fluid flow pipe 410 may be made of a thermally conductive material. For example, the deicing fluid flow pipe 410 may be made of a metal such as stainless steel. However, the material forming the deicing fluid flow pipe 410 is not particularly limited, and any material can be used as long as at least a part thereof is inserted into the refrigerant passage R of the evaporator body 200 and the deicing fluid can flow. .

The defrosting unit 400 may further include a defrosting fluid supply source 420. The deicing fluid source 420 may be connected to the deicing fluid flow tube 410. Then, the deicing fluid can be supplied to the deicing fluid flow pipe 410 from the deicing fluid supply source 420.

The defrosting fluid may be air, for example. In this case, the deicing fluid supply source 420 may include a blowing fan 421 connected to the deicing fluid flow pipe 410. By driving the blowing fan 421, air can be supplied as the deicing fluid to the deicing fluid flow pipe 410.

The defrosting fluid source 420 may further include a heater 422. The heater 422 may be provided in the blowing fan 421 or the deicing fluid flow pipe 410. The air supplied from the blowing fan 421 to the defrosting fluid flow pipe 410 or the air flowing through the defrosting fluid flow pipe 410 can be heated by the heater 422 to a predetermined temperature suitable for defrosting.

Second Embodiment of an Evaporator for an Ice Maker

Hereinafter, a second embodiment of an evaporator for an ice maker according to the present invention will be described with reference to FIG.

7 is a perspective view of a second embodiment of an evaporator for an ice maker according to the present invention.

Here, the second embodiment of the evaporator for an ice maker according to the present invention includes the first embodiment of the evaporator for an ice maker according to the present invention described with reference to FIGS. 1 to 6, There is a difference in configuration.

Therefore, different configurations will be mainly described below, and the remaining configurations can be replaced with those described with reference to FIGS. 1 to 6 above.

In the second embodiment of the evaporator for an ice maker according to the present invention, the ice-breaking fluid may be an antifreeze.

In this case, the deicing fluid supply source 420 may include an antifreeze tank 423 and a pump 424. The antifreeze tank 423 may be connected to the deicing fluid flow pipe 410. Further, the antifreeze liquid tank 423 may store antifreeze liquid. The pump 424 may be connected to the antifreeze tank 423 and the deicing fluid flow pipe 410. Accordingly, when the pump 424 is driven, the antifreeze fluid stored in the antifreeze tank 423 can be supplied to the deicing fluid flow pipe 410.

The antifreeze tank 423 may be provided with a heater 422. Accordingly, the antifreeze stored in the antifreeze tank 423 can be heated by the heater 422 to a predetermined temperature suitable for de-icing.

Third Embodiment of an Evaporator for an Ice Maker

Hereinafter, a third embodiment of an evaporator for an ice maker according to the present invention will be described with reference to FIG.

8 is a perspective view of a third embodiment of an evaporator for an ice maker according to the present invention.

Herein, the third embodiment of the evaporator for an ice maker according to the present invention is different from the first embodiment of the evaporator for an ice maker according to the present invention described with reference to FIGS. 1 to 6, There is a difference in configuration.

Therefore, different configurations will be mainly described below, and the remaining configurations can be replaced with those described with reference to FIGS. 1 to 6 above.

In a third embodiment of the evaporator for an ice maker according to the present invention, the defrosting fluid may be hot water.

In this case, the deicing fluid supply source 420 may include a hot water generating unit 425 and a heater 422. The hot water generating unit 425 may be connected to the deicing fluid flow pipe 410. Further, the heater 422 may be provided in the hot water generating unit 425.

Accordingly, the water supplied or stored in the hot water generating unit 425 can be heated by the heater 422 to become hot water. When the hot water generating unit 425 is instantaneous and the water is supplied at a sufficient pressure, the hot water generated in the hot water generating unit 425 can be supplied to the ice-making fluid flow pipe 410.

The defrosting fluid source 420 may further include a pump 424. The pump 424 may be connected to the hot water generating unit 425 and the deicing fluid flow pipe 410. For example, when the hot water generating unit 425 is a hot water tank and the water is not supplied at a sufficient pressure, hot water generated in the hot water generating unit 425 is supplied to the ice-making fluid flow pipe 410 by driving the pump 424 .

The hot water generating unit 425 may be connected to a supply pipe P connected to a water supply source (not shown) such as water as shown in FIG. Accordingly, the water of the water supply source can be supplied to the hot water generating unit 425.

Further, a drain pipe D may be connected to the deicing fluid flow pipe 410. Accordingly, hot water supplied from the hot water generating unit 425 and flowing through the ice-making fluid flow pipe 410 can be drained to the outside through the drain pipe D. After dehydration, no hot water is left in the deicing fluid flow pipe 410, and the hot water remaining in the deicing fluid flow pipe 410 at the time of deicing is frozen, and the deicing fluid flow pipe 410 is not blocked. Accordingly, dehiding can be continued by supplying hot water from the hot water generating unit 425 to the deicing fluid flow pipe 410.

As described above, when the evaporator for an ice maker according to the present invention is used, at least a part of the ice-making unit for separating ice formed by the evaporator is inserted into the refrigerant passage formed in the evaporator so that the ice- So that the occurrence of noise during the separation of the ice formed by the evaporator is minimized and the resistance to corrosion of the evaporator may not be deteriorated by separating the ice formed by the evaporator.

The above-described embodiments of the evaporator for an ice-maker may not be limited to the above-described embodiments, but all or a part of the embodiments may be selectively combined so that various modifications may be made to the embodiments .

100: evaporator for ice-maker 200: evaporator main body
300: ice forming part 310: immersion member
311: partition member 311a:
311b: passing portion 400: driving unit
410: Deicing fluid flow tube 420: Deicing fluid supply source
421: blower fan 422: heater
423: antifreeze tank 424: pump
425: hot water generating unit R: refrigerant flow path
I: Ice H: Insertion hole
HT: pipe connection hole CL: blocking member
HC: member connection hole SC: connection space
RI: Refrigerant inlet RO: Refrigerant outlet
T: connector TR: tray member
P: Supply pipe D: Water pipe

Claims (20)

An evaporator body having a refrigerant passage formed therein;
An ice forming unit connected to the evaporator body and having ice formed by contacting water at least in a state where a coolant having a temperature equal to or lower than a freezing point flows in the coolant channel; And
At least a part of which is inserted into the refrigerant channel, and a deicing fluid flowing above a freezing point flows into the ice making unit to separate ice from the ice forming unit;
And an evaporator. The evaporator for an ice-maker according to claim 1, wherein the ice-breaking unit includes an ice-making fluid flow tube in which at least a portion of the ice-making unit is inserted into the refrigerant channel and the ice-making fluid flows. The evaporator for an ice-maker according to claim 2, wherein the ice-making fluid flow pipe has a shape corresponding to a shape of at least a part of the evaporator body. The evaporator for an ice-maker according to claim 2, wherein the deicing fluid flow tube is made of a thermally conductive material. The evaporator for an ice maker according to claim 2, wherein the ice-breaking unit further comprises a de-icing fluid supply source connected to the de-icing fluid flow pipe for supplying de-icing fluid to the de-icing fluid flow tube. 6. The method of claim 5, wherein the defrosting fluid is air,
Wherein the deicing fluid supply source includes a blowing fan connected to the deicing fluid flow tube. 6. The method of claim 5, wherein the deicing fluid is an antifreeze,
The deicing fluid supply source includes an antifreeze tank connected to the deicing fluid flow tube and storing an antifreeze liquid, and a pump connected to the antifreeze tank and the deicing fluid flow tube. 6. The method of claim 5, wherein the defrosting fluid is hot water,
The deicing fluid supply source includes a hot water generating unit connected to the deicing fluid flow pipe and a heater provided in the hot water generating unit. The evaporator for an ice maker according to claim 8, wherein the deicing fluid supply source further comprises a pump connected to the hot water generating unit and the deicing fluid flow pipe. [7] The apparatus according to claim 6 or 7, wherein the deicing fluid supply source further comprises a heater provided in an antifreeze tank included in the deicing fluid flow pipe or the deicing fluid flow source or a blowing fan included in the deicing fluid supply source, . The evaporator for an ice-maker according to claim 1, wherein the evaporator body is formed with an insertion hole through which the ice-breaking unit is inserted so as to be inserted into the refrigerant channel. The evaporator for an ice-maker according to claim 1, wherein the ice-making part includes an immersion member connected to the evaporator body and at least a part of which is immersed in water to form ice. The evaporator for an ice-maker according to claim 12, wherein a connection hole through which the immersion member is connected is formed in the evaporator body. The evaporator of claim 12, wherein the immersion member is formed with a connection space connected to the refrigerant channel, and the refrigerant flowing through the refrigerant channel flows. 15. The evaporator according to claim 14, wherein the immersion member is provided with a partitioning member for partitioning the connection space into a refrigerant inflow path through which the refrigerant flows from the refrigerant flow path and a refrigerant outflow path through which the refrigerant flows out through the refrigerant flow path. 16. The evaporator for an ice-maker according to claim 15, wherein the partition member has a communication hole communicating the refrigerant inflow passage and the refrigerant outflow passage so that the refrigerant in the refrigerant inflow passage flows into the refrigerant outflow passage. The evaporator for an ice-maker according to claim 15, wherein the partition member extends through the refrigerant passage to the evaporator body. 18. The evaporator for an ice-maker according to claim 17, wherein the partition member is in contact with the immersion member and the evaporator body. The evaporator for an ice-maker according to claim 17, wherein a passage portion through which the ice-breaking unit passes is formed in the partition member. 20. The evaporator for an ice-maker according to claim 19, wherein the ice-breaking unit contacts the passing portion.

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