KR20230062075A - Evaporator for making ice - Google Patents

Abstract

An evaporator for making ice is provided. An evaporator for making ice according to an embodiment of the present invention includes a first evaporator body extending from one side to the other side; a first body space separating wall partitioning the inside of the first evaporator body into a first body space and a second body space formed side by side along an extending direction of the first evaporator body; a refrigerant inlet provided at one end of the first evaporator body to inject refrigerant into the first body space; a refrigerant outlet provided at one end of the first evaporator body and discharging the refrigerant flowing out from the second body space to the outside; a plurality of first protruding members extending from the first evaporator body to one side; a first protruding space dividing wall dividing the inside of the first protruding member into a first protruding space and a second protruding space; a first refrigerant passage formed so that the refrigerant moves from one end to the other end through the first body space and passes through the first protruding spaces of the plurality of first protruding members; And the other end of the first refrigerant passage is connected to the other end, and the refrigerant moves from the other end to one end through the second body space, but is formed to pass through the second protruding space of the plurality of first protruding members. a second refrigerant passage; can include

Description

Evaporator for ice making {EVAPORATOR FOR MAKING ICE}

The present invention relates to an ice-making evaporator, and more particularly, by forming a refrigerant flow path so that the refrigerant circulates inside the ice-making evaporator, not only can the size of a plurality of ices generated be uniform, but also the evaporator body can be extended to It relates to an ice-making evaporator capable of increasing the number of ices that can be created at one time.

An evaporator for making ice is used to make ice, and various methods have been developed to effectively produce ice. Recently, an evaporator body through which refrigerant flows, and a protruding member connected to the evaporator body are provided, and a refrigerant at a temperature lower than the freezing point is supplied to the inside of the protruding member in a state in which the protruding member is immersed in water contained in a drip tray or water is sprayed with the protruding member. A method in which ice is generated on the outer circumferential surface of the protruding member is used by flowing the ice.

In such a conventional ice-making evaporator, the refrigerant flows through the protruding member only once in one direction, and as a result, ice is not relatively quickly generated in the protruding member, and thus the ice-making efficiency is not high. In addition, there has been a problem that the size of ice generated on the protruding member varies depending on the position of the evaporator body to which the protruding member is connected. Looking at this in detail through the prior art, it is as follows.

Korean Patent Publication No. 10-2021-0003525 of Coway Co., Ltd. discloses a conventional ice-making evaporator and a manufacturing method of the ice-making evaporator. Such an evaporator for ice making discloses an evaporation tube extending in length through which refrigerant flows in the interior and an immersion member protruding from the evaporation tube. At this time, the invention disclosed in No. 10-2021-0003525 divides the inside of the immersion member into four spaces so that the refrigerant circulates through each space of the immersion member, thereby making the ice formed in a plurality of immersion members even in size. However, since the cross-sectional area of the space where the refrigerant moves is different, the flow speed of the refrigerant in each space is different, so there is a limit to evenly forming the size of ice. there is.

Korean Patent Registration No. 10-1092627 of this person discloses a conventional evaporator for an ice maker. The evaporator for an ice maker has a first refrigerant pipe and a second refrigerant pipe, so that ice production can be increased through a plurality of protruding cooling pipes formed in each refrigerant pipe. However, the invention disclosed in No. 10-1092627 not only reduces the cooling efficiency by interfering with the flow of the refrigerant by branching and recombining the flow paths inside the first refrigerant pipe and the second refrigerant pipe, but also in a plurality of protruding cooling pipes There is a problem in that the size of the ice formed is not uniformly formed.

Korea Patent Publication No. 10-2018-0009521 of Esso Co., Ltd. discloses a conventional ice generating evaporator. In the evaporator for making ice, the flow path formed inside the bent upper and lower control tubes does not diverge and circulates inside the ice-making protrusion, thereby increasing ice production efficiency. However, the invention disclosed in No. 10-2018-0009521 has a problem in that the flow path is formed only in one direction inside the ice-making protrusion, so ice is formed smaller in the direction of the flow path, and the cross-sectional area of the space where the refrigerant moves is different. There is a problem that the cooling efficiency is lowered due to the difference in the flow rate of the refrigerant in each space.

Publication No. 10-2021-0003525 Registered Patent Publication No. 10-1092627 Publication No. 10-2018-0009521

In order to solve the above problems, the present invention provides a first refrigerant passage sequentially passing through a plurality of first protruding members and a second refrigerant passage passing through a plurality of first protruding members in reverse order, so that each first An object of the present invention is to provide an evaporator for making ice capable of generating uniformly sized ice for each protruding member.

An object of the present invention is to provide an evaporator for ice making capable of minimizing the size of an evaporator body by forming a first refrigerant passage and a second refrigerant passage in parallel.

An object of the present invention is to provide an ice-making evaporator capable of minimizing the size of an evaporator body by arranging a plurality of first protruding members in a line at predetermined intervals.

An object of the present invention is to provide an evaporator for ice making that can minimize a change in flow speed when a refrigerant flows by optimizing the cross-sectional area of a passage through which a refrigerant flows.

An object of the present invention is to provide an ice-making evaporator capable of maintaining a flow rate of the refrigerant by matching a refrigerant injection direction and a refrigerant flow direction by arranging a refrigerant inlet in the longitudinal direction of the first body space.

An object of the present invention is to provide an evaporator for ice making capable of minimizing the size of the evaporator by injecting a hot gas into a passage through which a refrigerant flows through a hot gas inlet.

The present invention provides an ice-making evaporator in which a hot gas inlet is disposed on one side of the refrigerant inlet and a hot gas guide wall is provided so that the hot gas relatively unobstructed in the flow can smoothly move through the passage through which the refrigerant flows. There is a purpose.

The present invention provides an ice-making evaporator capable of forming a smooth flow of refrigerant by forming a first through hole connecting a first inflow space and a first outflow space inside a first protrusion member adjacent to the inside of the first protrusion member. has a purpose to

An object of the present invention is to provide an ice-making evaporator capable of forming a smooth flow of refrigerant by optimizing the size of a first refrigerant circulation hole connecting a first refrigerant passage and a second refrigerant passage.

An object of the present invention is to provide an ice-making evaporator capable of preventing lowering of cooling efficiency due to external heat flowing into the first evaporator body by providing an adiabatic space inside the first evaporator body.

An object of the present invention is to provide an ice-making evaporator capable of increasing the amount of ice produced at one time by including a second evaporator body and a second protruding member corresponding to the first evaporator body and the first protruding member.

An object of the present invention is to provide an ice-making evaporator capable of forming a smooth flow of refrigerant by optimizing the area of a passage formed inside a connecting member connecting a first evaporator body and a second evaporator body.

The tasks of the present invention are not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the description below.

In order to solve the above problems, an evaporator for making ice according to an aspect of the present invention includes a first evaporator body extending from one side to the other side; a first body space separating wall partitioning the inside of the first evaporator body into a first body space and a second body space formed side by side along an extension direction of the first evaporator body; a refrigerant inlet provided at one end of the first evaporator body to inject refrigerant into the first body space; a refrigerant outlet provided at one end of the first evaporator body and discharging the refrigerant flowing out from the second body space to the outside; a plurality of first protruding members extending from the first evaporator body to one side; a first protruding space dividing wall dividing the inside of the first protruding member into a first protruding space and a second protruding space; a first refrigerant passage formed so that the refrigerant moves from one end to the other end through the first body space and passes through the first protruding spaces of the plurality of first protruding members; And the other end of the first refrigerant passage is connected to the other end, and the refrigerant moves from the other end to one end through the second body space, but is formed to pass through the second protruding space of the plurality of first protruding members. a second refrigerant passage; can include

In this case, the first refrigerant passage and the second refrigerant passage may be formed side by side.

At this time, the first protruding member may be arranged in a line with a predetermined interval in the longitudinal direction of the first evaporator body.

In this case, the first body space and the second body space may have a length ratio of a width to a height of 3:1 to 1.5.

At this time, the ratio of the distance between the first protruding member adjacent to the other end surface of the first evaporator body and the other end surface and the length of the width of the first protruding member may be 1:0.9 to 1.1.

At this time, the first protruding member may be formed in a hemispherical shape having a circular cross section perpendicular to the longitudinal direction and having one end convex outward.

At this time, the refrigerant injection port may inject the refrigerant in the longitudinal direction of the first body space.

At this time, the refrigerant inlet may protrude toward the first protruding space of the first protruding member adjacent to one end of the first evaporator body.

At this time, a hot gas inlet formed on one side of the refrigerant inlet to inject hot gas into the first body space; Further, the hot gas inlet may inject the hot gas in a longitudinal direction of the first body space.

At this time, a hot gas guide wall formed at one end of the first body space to guide the hot gas injected through the hot gas inlet toward the first protruding space; may further include.

At this time, the first protruding space is divided into a first inflow space and a first outflow space formed in the longitudinal direction of the first protrusion member, and the first inflow space and the first outflow space have one end so that fluid communication is possible. The first refrigerant passage passes through the first inflow space and the first outflow space sequentially, and the second protrusion space is formed in the longitudinal direction of the first protrusion member and the second inflow space and the second Divided into an outflow space, the second inflow space and the second outflow space are connected so that one end is fluidly communicable, and the second refrigerant flow path may sequentially pass through the second inflow space and the second outflow space .

At this time, the areas of cross sections perpendicular to the longitudinal direction of the first body space, the second body space, the first inflow space, the first outflow space, the second inflow space, and the second outflow space are the same. can be formed

At this time, the first protruding space is provided with a first partition wall partitioning the first inflow space and the first outflow space such that cross sections perpendicular to the longitudinal direction of the first inflow space and the first outflow space are the same. A first through hole is formed at one end of the first partition wall with an area equal to the area of the cross section perpendicular to the longitudinal direction of the first inflow space and the first outflow space, and in the second protrusion space. A second partitioning wall partitioning the second inflow space and the second outflow space is provided so that cross sections perpendicular to the longitudinal direction of the second inflow space and the second outflow space are the same, and one end of the second partition wall is provided. A second through hole may be formed in an area equal to a cross section perpendicular to the longitudinal direction of the second inflow space and the second outflow space.

In this case, the first through hole and the second through hole may be formed adjacent to an inner end surface of the first protruding member.

At this time, a first refrigerant circulation hole such that the other end of the first body space separating wall is connected to the other end of the first refrigerant passage and the second refrigerant passage; can be formed.

At this time, the first refrigerant circulation hole may extend from the inner lower surface to the upper surface of the first evaporator body.

At this time, the ratio of the area of the first refrigerant circulation hole and the area of the cross section perpendicular to the longitudinal direction of the first outflow space may be 1.5 to 2:1.

At this time, the first refrigerant circulation hole may be formed adjacent to the other end surface of the evaporator body.

At this time, a first insulating wall partitioning the first evaporator body up and down so that a heat insulating space is formed on the inner upper portion of the first evaporator body; may further include.

At this time, a first insulating wall partitioning the first evaporator body up and down so that a heat insulating space is formed on the inner upper portion of the first evaporator body; a first guide wall extending upward from an upper end of the first partition wall so that the refrigerant moves from the first body space to the first inflow space; and a second guide wall extending upward from an upper end of the second partition wall so that the refrigerant moves from the second inlet space to the second body space. The first insulating wall may extend to the first guide wall and the second guide wall of the first protruding member adjacent to a rear end surface of the first evaporator body.

At this time, a discharge space formed to be fluidly communicated with the second body space is formed inside one end of the first evaporator body, and the refrigerant outlet is the first protruding member so that the discharge space can communicate with the outside. It may be formed through the first evaporator body in the extension direction of.

At this time, the second evaporator body extending from one side to the other side; a second body space dividing wall partitioning the inside of the second evaporator body into a third body space and a fourth body space formed side by side along an extending direction of the second evaporator body; a plurality of second protruding members extending from the second evaporator body to one side; a second protruding space dividing wall dividing the inside of the second protruding member into a third protruding space and a fourth protruding space; a third refrigerant passage formed so that the refrigerant moves from the other end to one end through the third body space and passes through the third protruding spaces of the plurality of second protruding members; and one end of the third refrigerant passage is connected to the other, and the refrigerant moves from one end to the other through the fourth body space, passing through the fourth protrusion space of the plurality of second protrusion members. a fourth refrigerant passage; The first refrigerant passage further includes, wherein the other end of the third refrigerant passage is connected to the other end of the first refrigerant passage, and the other end of the fourth refrigerant passage is connected to the other end of the second refrigerant passage. The other end of may be connected to the other end of the second refrigerant passage.

At this time, a hollow connection member extending from the other end of the first evaporator body to the other end of the second evaporator body; and a connecting member separating wall partitioning the inside of the connecting member into a first connecting space and a second connecting space formed in an extending direction of the connecting member. The other end of the third refrigerant passage is connected to the other end of the first refrigerant passage through the first connection space, and the other end of the fourth refrigerant passage passes through the second connection space. It may be connected to the other end of the second refrigerant passage.

At this time, the first body space, the first connection space, and the third body space have the same cross-sectional area, and the second body space, the second connection space, and the fourth body space have the same cross-sectional area. can

In this case, one end of the connecting member separating wall may be coupled to the other end of the first body space separating wall, and the other end of the connecting member separating wall may be coupled to the other end of the second body space separating wall.

At this time, the connecting member may be bent so that the first evaporator body and the second evaporator body are disposed side by side in a direction perpendicular to the extension direction.

At this time, a first connection member extending from one side of the other end of the first evaporator body to one side of the other end of the second evaporator body and having a first connection space formed therein; and a second connection member extending from the other side of the other end of the first evaporator body to the other side of the other end of the second evaporator body and having a second connection space formed therein. The other end of the third refrigerant passage is connected to the other end of the first refrigerant passage through the first connection space, and the other end of the fourth refrigerant passage passes through the second connection space. It may be connected to the other end of the second refrigerant passage.

An ice-making evaporator according to an embodiment of the present invention includes a first refrigerant passage sequentially passing through a plurality of first protruding members and a second refrigerant passage passing through a plurality of first protruding members in reverse order, so that each first refrigerant passage passes through the plurality of first protrusion members. Ice having a uniform size may be generated for each protruding member.

In the evaporator for ice making according to an embodiment of the present invention, the first refrigerant passage and the second refrigerant passage are formed in parallel, so that the size of the evaporator body can be minimized.

In the evaporator for ice making according to an embodiment of the present invention, the size of the evaporator body can be minimized by arranging a plurality of first protruding members in a row with a predetermined interval therebetween.

An ice-making evaporator according to an embodiment of the present invention can minimize a change in flow rate when a refrigerant flows by optimizing a cross-sectional area of a passage through which a refrigerant flows.

In the evaporator for ice making according to an embodiment of the present invention, the refrigerant inlet is disposed in the longitudinal direction of the first body space, thereby matching the refrigerant injection direction and the refrigerant flow direction to maintain the flow rate of the refrigerant.

In the evaporator for ice making according to an embodiment of the present invention, the size of the evaporator can be minimized by injecting the hot gas through the hot gas inlet into the passage through which the refrigerant flows.

The ice-making evaporator according to an embodiment of the present invention has a hot gas guide wall while arranging a hot gas inlet on one side of the refrigerant inlet, so that the hot gas relatively unobstructed in the flow flows smoothly through the passage through which the refrigerant flows. can be moved

An ice-making evaporator according to an embodiment of the present invention provides a smooth flow of refrigerant by forming a first through-hole connecting the first inflow space and the first outflow space inside the first protrusion member adjacent to the inside of the first protrusion member. can form

The evaporator for making ice according to an embodiment of the present invention can form a smooth flow of refrigerant by optimizing the size of the first refrigerant circulation hole connecting the first refrigerant passage and the second refrigerant passage.

An ice-making evaporator according to an embodiment of the present invention may prevent lowering of cooling efficiency due to external heat flowing into the first evaporator body by providing an adiabatic space inside the first evaporator body.

An ice-making evaporator according to an embodiment of the present invention includes a second evaporator body and a second protruding member corresponding to the first evaporator body and the first protruding member, thereby increasing the amount of ice produced at one time. .

An ice-making evaporator according to an embodiment of the present invention may form a smooth flow of refrigerant by optimizing the area of a passage formed inside a connecting member connecting the first evaporator body and the second evaporator body.

The effects of the present invention are not limited to the above effects, and should be understood to include all effects that can be inferred from the description of the present invention or the configuration of the invention described in the claims.

1 is a perspective view of an evaporator for ice making according to a first embodiment of the present invention.
2 is an exploded perspective view of an evaporator for ice making according to a first embodiment of the present invention.
3 is a cross-sectional view of an ice-making evaporator according to a first embodiment of the present invention viewed from above.
4 is a view showing the first refrigerant circulation hole of the evaporator for ice making according to the first embodiment of the present invention.
5 is a view showing a modified example of the first refrigerant circulation hole of the ice-making evaporator according to the first embodiment of the present invention.
6 is an enlarged cross-sectional view of a cross-section taken along line AA of FIG. 1 .
FIG. 7 is a cross-sectional view showing an enlarged cross-section taken along line BB of FIG. 1 .
8 is a view showing a first flow path of the evaporator for ice making according to the first embodiment of the present invention.
9 is a view showing a second flow path of the evaporator for ice making according to the first embodiment of the present invention.
10 is a perspective view of an evaporator for ice making according to a second embodiment of the present invention.
11 is a cross-sectional view of an ice-making evaporator according to a second embodiment of the present invention viewed from above.
12 is a perspective view of an evaporator for ice making according to a third embodiment of the present invention.
13 is a cross-sectional view of an ice-making evaporator according to a third embodiment of the present invention viewed from above.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily carry out the present invention. This invention may be embodied in many different forms and is not limited to the embodiments set forth herein. Terms used in the embodiments of the present invention may be interpreted as meanings commonly known to those skilled in the art unless otherwise defined.

In order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar components throughout the specification. In order to clearly express the characteristics of the configuration in the drawings, the thickness or size is exaggerated, and the thickness or size of the configuration shown in the drawings is not shown in reality.

Hereinafter, the direction in which the first protruding member 200 protrudes from the first evaporator body 100 in FIG. 1 is defined as the downward direction, and the side into which the refrigerant flows from the first evaporator body 100 is defined as the forward direction. However, this direction means a relative direction, and does not mean an absolute direction in which the ice-making evaporator is disposed.

The present invention relates to an ice-making evaporator, and more particularly, by forming a refrigerant flow path so that the refrigerant circulates inside the ice-making evaporator, not only can the size of a plurality of ices generated be uniform, but also the evaporator body can be extended to It relates to an ice-making evaporator capable of increasing the number of ices that can be created at one time.

In particular, the present invention may be installed inside an ice maker or a water purifier having an ice maker in a manner in which ice is formed outside the first protrusion member by immersing the first protruding member in a gutter containing purified water.

1 is a perspective view of an evaporator for ice making according to a first embodiment of the present invention. 2 is an exploded perspective view of an evaporator for ice making according to a first embodiment of the present invention. 3 is a cross-sectional view of an ice-making evaporator according to a first embodiment of the present invention viewed from above. 4 is a view showing the first refrigerant circulation hole of the evaporator for ice making according to the first embodiment of the present invention. 5 is a view showing a modified example of the first refrigerant circulation hole of the ice-making evaporator according to the first embodiment of the present invention. FIG. 6 is an enlarged cross-sectional view of a cross-section taken along the line A-A of FIG. 1; FIG. 7 is an enlarged cross-sectional view of a cross-section taken along line B-B of FIG. 1;

As shown in FIG. 1, the evaporator for making ice according to the first embodiment of the present invention includes a first evaporator body 100, a first body space partition wall 110, a refrigerant inlet 500, and a discharge hole 102. , a hot gas inlet 700, a hot gas guide wall 720, a first protruding member 200, a first protruding space separation wall 210, and a first insulating wall 140.

As shown in Figure 1, the first evaporator body 100 is formed extending from one side to the other side. A space is formed inside the first evaporator body 100, and as shown in FIG. 3, the inner space of the first evaporator body 100 is parallel to the left and right along the extension direction of the first evaporator body 100. It may be partitioned into a first body space 112 and a second body space 113 formed.

At this time, as shown in FIGS. 2 and 3, the first evaporator body 100 is inside the first evaporator body 100 to partition the first body space 112 and the second body space 113. A first body space separating wall 110 extending in the extension direction of the body space and disposed in the vertical direction is disposed.

The first body space 112 and the second body space 113 are each formed to have the same area and shape of a cross section perpendicular to the longitudinal direction. At this time, the refrigerant moves to the first body space 112 and the second body space 113, and the ratio of the width and height of the first body space 112 and the second body space 113 is 3 :1 to 1.5. That is, the width of the passage through which the refrigerant moves is greater than the height. Accordingly, a temperature difference between the upper and lower sides of the refrigerant is prevented from occurring due to heat introduced from the upper side of the first evaporator body 100, and the refrigerant smoothly flows into the first protruding member 200 to be described later without accumulation. It has the effect of making it possible.

3 and 4, the other end, that is, the rear end of the first body space separating wall 110 is such that the rear of the first body space 112 and the second body space 113 are in fluid communication with each other. A first refrigerant circulation hole 111 is formed. Thus, the refrigerant moving along the first body space 112 moves to the second body space 113 via the first refrigerant circulation hole 111 . At this time, the area of the first refrigerant circulation hole 111 may be formed equal to the area of the cross section perpendicular to the longitudinal direction of the first outflow space 224 . Accordingly, the cross-sectional area of the passage connecting the first body space 112, the first refrigerant circulation hole 111, and the second body space 113 is maintained constant, so that the refrigerant can move constantly.

Meanwhile, as shown in FIG. 5 , the first refrigerant circulation hole 111 ′ may be formed to extend from the inner lower surface to the upper surface of the first evaporator body 100 . Accordingly, there is an effect that the refrigerant can more smoothly move to the second body space 113 by preventing the refrigerant from accumulating on the upper side of the first body space dividing wall 110'.

At this time, the ratio of the area of the first refrigerant circulation hole 111' to the area of the cross section perpendicular to the longitudinal direction of the first outflow space 224 may be 1.5 to 2:1. That is, the area of the first refrigerant circulation hole 111' may be larger than the area of the cross section perpendicular to the longitudinal direction of the first outflow space 224. Accordingly, as the refrigerant collides with the other end surface 103 of the first evaporator body and the direction of movement is changed, the flow rate passing through the first refrigerant circulation hole 111' is prevented from being reduced.

At this time, as shown in FIG. 5, the first refrigerant circulation hole 111' may be formed as close to the other end surface 103 of the first evaporator body as possible. Accordingly, the first refrigerant circulation hole 111' is formed so that no part protrudes from the other end surface 103 of the first evaporator body, thereby changing the direction from the first body space 112 to the second body space 113. There is an effect of inducing a smooth flow of the refrigerant by preventing the flow of the refrigerant from being obstructed as much as possible. In addition, since the first refrigerant circulation hole 111' can be formed by adjusting only the extension length of the first body space separating wall 110', there is an effect of simplifying the manufacturing process and reducing manufacturing time.

As shown in FIGS. 1 and 2 , the refrigerant inlet 500 is disposed at one end of the first evaporator body 100, that is, at the front. The refrigerant inlet 500 injects refrigerant into the front of the first body space 112 . At this time, in order to facilitate the movement of the refrigerant, the refrigerant inlet 500 is disposed in the longitudinal direction of the first body space 112 to inject the refrigerant in the longitudinal direction of the first body space 112 .

At this time, as shown in FIG. 2 , the refrigerant inlet 500 may be formed to protrude from the first evaporator body end surface 101 toward the first body space 112 . More specifically, the refrigerant inlet 500 may be formed such that an end portion of the first protruding member 200 protrudes toward the first protruding space 222 to be described later. Accordingly, the refrigerant injected from the refrigerant inlet 500 directly flows into the first protruding member 200 to be described later, so that the refrigerant can be smoothly circulated.

3 and 6, in order for the refrigerant injected through the refrigerant inlet 500 to be discharged to the outside through the first body space 112 and the second body space 113, the first evaporator body ( 100), that is, a discharge hole 102 is formed at one end, that is, the front end. More specifically, it is formed on the first evaporator body end surface 101 so that the second body space 113 and the outside can communicate fluidly.

At this time, the refrigerant inlet 500 and the discharge hole 102 may be formed side by side, and the refrigerant inlet 500 is formed on the side of the first body space 112 to facilitate injection and discharge of the refrigerant, and the discharge hole (102) may be formed on the side of the second body space (113).

Meanwhile, referring to FIGS. 2 and 3 , the evaporator for ice making according to an embodiment of the present invention may further include a discharge space 620 and a refrigerant outlet 600 .

The first evaporator body 100 may further extend toward the front side, and a discharge space 620 may be formed inside the extended first evaporator body 100 . The discharge space 620 is fluidly connected to the second body space 113 through the discharge hole 102 . That is, the discharge space 620, the first body space 112, and the second body space 113 are partitioned by the first evaporator body end surface 101, and the refrigerant discharged through the discharge hole 102 is discharged into the discharge space. (620).

At this time, at the front end of the first evaporator body 100 where the discharge space 620 is formed, the refrigerant discharge port 600 is provided to allow fluid communication with the outside in the downward direction, that is, in the direction in which the first protruding member 200 to be described later extends. is formed through A refrigerant discharge pipe 610 may be connected to the refrigerant outlet 600 .

Meanwhile, referring to FIGS. 2 and 3 , a hot gas inlet 700 for injecting hot gas into the first body space 112 is formed at one side of the refrigerant inlet 500 . The hot gas injected through the hot gas inlet 700 moves along the first body space 112 and the second body space 113 where the refrigerant moves. After being formed, heat is applied to the first protruding member 200 to separate the ice adhering to the first protruding member 200 from the first protruding member 200 . In this way, since the refrigerant and the hot gas share a moving path, an effect of minimizing the first evaporator body 100 can be obtained.

At this time, since the flow of the hot gas relative to the refrigerant is not affected by the structure, it may be formed above the refrigerant inlet 500 as shown in FIGS. 2 and 6 .

However, as shown in FIG. 8, the hot gas guide wall 720 is provided inside the first evaporator body 100 so that the hot gas can be smoothly injected into the first body space 112 during the process of injecting the hot gas. can be formed. The hot gas guide wall 720 protrudes downward from the inner upper surface of the first evaporator body 100 and extends. At this time, it may be formed to guide the hot gas injected through the hot gas inlet 700 toward the first protruding space 222 . In addition, the hot gas guide wall 720 may be inclined to prevent hot gas from being stagnant.

As shown in FIG. 8 , the hot gas guide wall 720 may be formed to extend from the first insulating wall 140 to be described later. Accordingly, the hot gas guide wall 720 has an effect of preventing the hot gas and the refrigerant from moving into the first heat insulating space 141 formed by the first heat insulating wall 140 to be described later, and the hot gas There is an effect of making it easy to manufacture the guide wall 720.

Meanwhile, referring to FIGS. 1 and 2 , the first protruding member 200 extends downward from the first evaporator body 100 . At this time, the first protruding member 200 is formed in plurality and may be arranged in a line with a predetermined interval in the longitudinal direction of the first evaporator body 100.

The first protruding member 200 is formed in a tubular shape, and as shown in FIG. 2 , it may be formed in a cylindrical shape such that a cross section perpendicular to the longitudinal direction is formed in a circular shape.

In addition, the lower end of the first protruding member 200 may be formed in a hemispherical shape convex outward. In this way, since the lower end is formed in a hemispherical shape, the fluid is stagnant in the corner space in the process of changing the direction of the refrigerant or hot gas flowing into the first protruding member 200 to flow out of the first protruding member 200. It is possible to reduce the phenomenon in which the flow is smooth.

At this time, the distance between the other end surface 103 of the first evaporator body and the first protruding member 200 disposed most adjacently is the length of the width of the first protruding member 200, for example, the cylindrical first protruding member ( 200) can be formed similar to the length of the diameter. More specifically, the length of the distance between the other end surface 103 of the first evaporator body and the first protruding member 200 disposed most adjacent to the width of the first protruding member 200 may be 1:0.9 to 1.1. . Accordingly, the refrigerant can more smoothly move from the first body space 112 to the second body space 113 through the first refrigerant circulation hole 111 .

3 and 7, a space is formed inside the first protruding member 200, and the first protruding space separating wall 210 divides the inner space of the first protruding member 200 into the first protruding space ( 222) and the second protruding space 232 are formed inside the first protruding member 200. In this case, as shown in FIG. 7 , the first protruding space separating wall 210 may be integrally formed with the first body space separating wall 110 and extend into the first protruding member 200 . Accordingly, the first protrusion space 222 is connected to the first body space 112 and the second protrusion space 232 is connected to the second body space 113 .

Referring to FIGS. 3 and 7 , the first protruding space 222 is divided into a front first inflow space 223 and a rear first outflow space 224 . To this end, the first partition wall 220 protrudes from the first protruding space partition wall 210 . The first partition wall 220 extends along the extension direction of the first protruding member 200 and has a first through hole 221 at a lower end so that the first inflow space 223 and the first outflow space 224 can communicate with each other. ) is formed.

As shown in FIG. 7 , the first through hole 221 may be formed adjacent to an inner end surface of the first protruding member 200 . Accordingly, while the refrigerant moves from the first inflow space 223 to the first outflow space 224 through the first through hole 221, the refrigerant moves smoothly along the inner end surface of the first protruding member 200. There is an effect that can be done.

At this time, the first partition wall 220 is formed such that cross sections perpendicular to the longitudinal direction of the first inflow space 223 and the first outflow space 224 are identical to each other. Accordingly, the refrigerant flows from the first body space 112 into the first inflow space 223 and moves to the first outflow space 224 through the first through hole 221, and again in the first outflow space 224. While flowing out into the first body space 112, the moving speed of the refrigerant is maintained constant. In particular, the area of the first through hole 221 is formed equal to the area of the cross section perpendicular to the longitudinal direction of the first inflow space 223 and the first outflow space 224 .

Meanwhile, a first guide wall 120 is formed at an upper end of the first partition wall 220 . The first guide wall 120 guides the refrigerant moving along the first body space 112 so that it passes through both the first inflow space 223 and the first outflow space 224 without branching. To this end, the first guide wall 120 extends upward from the upper end of the first partition wall 220 to the inner surface of the first evaporator body 100, or extends upward to the first insulating wall 140 described later. can

Accordingly, the flow of the refrigerant can be smoothed by allowing the refrigerant to pass through the inside of the first protruding member 200 without being separated into the refrigerant passing through the inside of each first protruding member 200 and the refrigerant not passing through the inside of each first protruding member 200. In addition, there is an effect of making the cooling efficiency of each first protruding member 200 constant by clarifying the temperature distribution of the refrigerant.

Referring to FIGS. 3 and 7 , the second protruding space 232 is divided into a second inflow space 233 at the rear and a second outflow space 234 at the front. To this end, a second partition wall 230 protrudes from the first protruding space partition wall 210 on the opposite side of the first partition wall 220 . The second partition wall 230 extends along the extension direction of the first protruding member 200 and has a second through hole 231 at the lower end so that the second inflow space 233 and the second outflow space 234 can communicate with each other. ) is formed.

At this time, the second partition wall 230 is formed such that cross sections perpendicular to the longitudinal direction of the second inflow space 233 and the second outflow space 234 are the same. Accordingly, the refrigerant flows from the second body space 113 into the second inflow space 233 and moves to the second outflow space 234 through the second through hole 231, and again in the second outflow space 234. While flowing out into the second body space 113, the moving speed of the refrigerant is maintained constant. In particular, the area of the second through hole 231 is formed equal to the area of the cross section perpendicular to the longitudinal direction of the second inflow space 233 and the second outflow space 234 .

Meanwhile, a second guide wall 130 is formed at an upper end of the second partition wall 230 . The second guide wall 130 guides the refrigerant moving along the second body space 113 so that the refrigerant passes through both the second inlet space 233 and the second outlet space 234 without branching. To this end, the second guide wall 130 extends upward from the upper end of the second partition wall 230 to the inner surface of the first evaporator body 100, or extends upward to the first insulating wall 140 described later. can

Accordingly, the refrigerant is not separated into refrigerant passing through the inside of each second protruding member 400 and refrigerant not passing through the inside of each second protruding member 400, and all of them pass through the inside of the second protruding member 400, so that the flow of the refrigerant can be smoothed. In addition, there is an effect of making the cooling efficiency of each second protruding member 400 constant by clarifying the temperature distribution of the refrigerant.

As shown in FIG. 7 , the second through hole 231 may be formed adjacent to an inner end surface of the first protruding member 200 . Accordingly, while the refrigerant moves from the second inflow space 233 to the second outflow space 234 through the second through hole 231, the refrigerant moves smoothly along the inner end surface of the first protruding member 200. There is an effect that can be done.

Meanwhile, as shown in FIG. 7 , the first insulating wall 140 partitions the first body space 112 vertically. As shown in FIG. 4, since the first insulating wall 140 is provided, as the inner upper portion of the first evaporator body 100, the upper side of the first body space 112 and the second body space 113 has a first heat insulation. A space 141 is formed. The first insulation space 141 serves to prevent external heat from entering into the refrigerant passing through the first body space 112 and the second body space 113 . Accordingly, the ice-making efficiency can be increased.

When the first insulating wall 140 is formed, the first guide wall 120 extending from the first partition wall 220 extends to the first insulating wall 140 and extends from the second partition wall 230. The second guide wall 130 is extended to the first insulating wall 140. In addition, the hot gas guide wall 720 may be integrally formed with the first insulating wall 140 . Accordingly, it is possible to prevent hot gas or refrigerant from flowing into the first heat insulating space 141 .

8 is a view showing a first flow path of the evaporator for ice making according to the first embodiment of the present invention. 9 is a view showing a second flow path of the evaporator for ice making according to the first embodiment of the present invention.

In the evaporator for ice making according to the first embodiment of the present invention, a first refrigerant passage 114 and a second refrigerant passage 115 are formed via the first evaporator body 100 and the plurality of first protruding members 200. do.

As shown in FIG. 8, the first refrigerant passage 114 is a path along which the refrigerant injected through the refrigerant inlet 500 moves, and includes a first body space 112, a first inflow space 223, a first It is formed to pass through the outflow space 224 and the first body space 112 sequentially. At this time, since the first protruding member 200 is formed in plurality, both the first inflow space 223 and the first outflow space 224 formed in each of the first protruding member 200 pass through.

The first refrigerant passage 114 is not branched as a single path, and the first inflow space 223 along the front surface of the first guide wall 120 and the first partition wall 220 in the first body space 112 The direction is changed to the first through hole 221, the direction is changed to the first outflow space 224, and the first partition wall 220 and the first guide wall 120 are again along the rear surface. 1 leads to body space 112.

At this time, the area of the cross section perpendicular to the longitudinal direction of the first body space 112, the first inflow space 223, and the first outflow space 224 through which the first refrigerant passage 114 passes is formed to be the same. can Accordingly, there is an effect of allowing the refrigerant to smoothly move along the first refrigerant passage 114 by preventing the flow velocity of the refrigerant moving along the first refrigerant passage 114 from being changed by the cross-sectional area.

The first refrigerant passage 114 extends to the rear end of the first body space 112 of the first evaporator body 100, and the rear end of the first refrigerant passage 114 is a second refrigerant passage 115 to be described later. Is connected through the first refrigerant circulation hole (111).

As shown in FIG. 9, the second refrigerant passage 115 is a path through which the refrigerant introduced through the first refrigerant circulation hole 111 moves, and includes a second body space 113 and a second inlet space 233. , It is formed to pass through the second outflow space 234 and the second body space 113 sequentially. At this time, since the first protruding member 200 is formed in plurality, both the second inlet space 233 and the second outflow space 234 formed in each of the first protruding member 200 pass through.

The second refrigerant passage 115 is not branched as a single path, and the second inlet space 233 along the rear surface of the second guide wall 130 and the second partition wall 230 in the second body space 113 The direction is changed to the second through hole 231, the direction is changed to the second outflow space 234, and the direction is changed to the second partition wall 230 and the second guide wall 130 along the front surface. It leads to the second body space (113).

At this time, the area of the cross section perpendicular to the longitudinal direction of the second body space 113, the second inflow space 233, and the second outflow space 234 through which the second refrigerant passage 115 passes is formed to be the same. can Accordingly, there is an effect of allowing the refrigerant to smoothly move along the second refrigerant passage 115 by preventing the flow velocity of the refrigerant moving along the second refrigerant passage 115 from being changed by the cross-sectional area.

The second refrigerant passage 115 extending forward of the second body space 113 leads to the discharge hole 102, and the refrigerant moved along the second refrigerant passage 115 is discharged through the discharge hole 102. 1 is discharged from the evaporator body 100 to the outside.

The refrigerant absorbs heat while passing through the plurality of first protruding members 200 so that the temperature thereof gradually increases. At this time, as the first refrigerant passage 114 and the second refrigerant passage 115 are formed as described above, the first inlet space 223 has the lowest level based on the first protruding member 200 disposed in the front. The refrigerant at the second temperature passes through, and the refrigerant at the second lowest temperature passes through the first outflow space 224 . Conversely, the second highest temperature refrigerant passes through the second inflow space 233 and the highest temperature refrigerant passes through the second outflow space 234 .

In the same way, the average temperature of the refrigerant passing through each of the first protruding members 200 is maintained the same. Accordingly, the size of ice generated in each of the first protruding members 200 is the same.

10 is a perspective view of an evaporator for ice making according to a second embodiment of the present invention. 11 is a cross-sectional view of an ice-making evaporator according to a second embodiment of the present invention viewed from above.

10 and 11, the ice-making evaporator according to the second embodiment of the present invention includes a first evaporator body 100, a first body space partition wall 110, a refrigerant inlet 500, and a discharge hole. 102, a hot gas inlet 700, a hot gas guide wall 720, a first protruding member 200, a first protruding space separation wall 210, and a first insulating wall 140, The second evaporator body 300, the second body space separating wall 310, the second protruding member 400, and the second protruding space separating wall 410 can increase the number of ices generated at one time compared to the embodiment. ), a second insulating wall 340, a third partitioning wall 420 and a fourth partitioning wall 430 are further provided. At this time, the description of the configuration overlapping with the first embodiment of the present invention will be omitted, and the differences from the first embodiment will be mainly described.

The second evaporator body 300, the second body space partition wall 310, the second protruding member 400, the second protruding space partition wall 410, the second insulating wall 340, the third partition wall 420 ) and the fourth partition wall 430 are the above-described first evaporator body 100, the first body space partition wall 110, the first protruding member 200, the first protruding space partition wall 210, It corresponds to the first insulating wall 140, the first partition wall 220, and the second partition wall 230, and has the same shape and function.

In addition, the third body space 312 and the fourth body space 313 formed by the second body space separating wall 310 correspond to the first body space 112 and the second body space 113, respectively. , The second protruding member ( The fourth inflow space 433 and the fourth outflow space 434 formed in the 400 are the first inflow space 223 and the first outflow space 224, the second inflow space 233 and the second outflow space, respectively. Corresponds to (234). As shown in FIG. 11, each corresponding component has a difference only in an arrangement position and has the same shape or function.

At this time, in the second embodiment of the present invention, the first refrigerant circulation hole 111 is not formed in the first body space partition wall 110, and the first refrigerant circulates in front of the second body space partition wall 310. A second refrigerant circulation hole 311 corresponding to the hole 111 is formed. Accordingly, the second refrigerant circulation hole 311 connects the front ends of the third body space 312 and the fourth body space 313 .

In the evaporator for ice making according to the second embodiment of the present invention, a third refrigerant passage 314 and a fourth refrigerant passage 315 passing through the second evaporator body 300 and the plurality of second protruding members 400 are formed. do.

In the evaporator for ice making according to the second embodiment of the present invention, the third refrigerant passage 314 is a path through which the refrigerant moves, and includes a third body space 312, a third inflow space 423, and a third outflow space 424. ) and the third body space 312 sequentially. At this time, since the second protruding member 400 is formed in plurality, both the third inflow space 423 and the third outflow space 424 formed in each second protruding member 400 pass through.

At this time, the rear end of the third refrigerant passage 314 is connected to the rear end of the first refrigerant passage 114, and the refrigerant moving along the first refrigerant passage 114 moves to the rear along the third refrigerant passage 314. will move forward from

In the ice-making evaporator according to the second embodiment of the present invention, the fourth refrigerant passage 315 is a path through which the refrigerant moves, and includes a fourth body space 313, a fourth inflow space 433, and a fourth outflow space 434. ) and the fourth body space 313 sequentially. At this time, since the second protruding member 400 is formed in plurality, both the fourth inflow space 433 and the fourth outflow space 434 formed in each second protruding member 400 pass through.

At this time, the front end of the fourth refrigerant passage 315 is connected to the third refrigerant passage 314 through the second refrigerant circulation hole 311, and the rear end of the fourth refrigerant passage 315 is connected to the second refrigerant passage. It is connected with the rear end of (115). Therefore, the refrigerant introduced into the fourth refrigerant passage 315 through the second refrigerant circulation hole 311 moves from front to rear along the fourth refrigerant passage 315 and then again along the second refrigerant passage 115. It moves forward and is discharged through the refrigerant outlet (600).

At this time, the ice making evaporator according to the second embodiment of the present invention connects the rear end of the first refrigerant passage 114 and the rear end of the third refrigerant passage 314, and the rear end of the second refrigerant passage 115 A connecting member 800 is further provided to connect the end and the rear end of the fourth refrigerant passage 315 .

As shown in FIGS. 10 and 11 , the connecting member 800 is formed in a hollow conduit shape. The shape of the cross section of the connecting member 800 is not limited, and as shown in FIG. 10, it may be formed in a circular shape.

One end of the connecting member 800 is coupled to the other end surface 103 of the first evaporator body, and the other end of the connecting member 800 is coupled to the other end surface 303 of the second evaporator body.

At this time, as shown in FIG. 10 , a connecting member separating wall 810 is formed inside the connecting member 800 . Accordingly, the inner space of the connecting member 800 is partitioned into a first connecting space 811 and a second connecting space 812 by the connecting member separating wall 810 .

At this time, one end of the connecting member separating wall 810 is connected to the first body space separating wall 110 and the other end of the connecting member separating wall 810 is connected to the second body space separating wall 310 . The other end of the first refrigerant passage 114 and the other end of the third refrigerant passage 314 are connected through the first connection space 811 .

In this case, the first body space 112, the first connection space 811, and the third body space 312 may have the same cross-sectional area. Accordingly, the refrigerant can smoothly move through the first body space 112 , the first connection space 811 , and the third body space 312 .

The other end of the second refrigerant passage 115 and the other end of the fourth refrigerant passage 315 are connected through the second connection space 812 . The second body space 113, the second connection space 812, and the fourth body space 313 may also have the same cross-sectional area.

Meanwhile, the first evaporator body 100 and the second evaporator body 300 may be arranged side by side in a direction perpendicular to the extension direction, as shown in FIGS. 10 and 11 . Accordingly, the connecting member 800 may be formed by bending.

12 is a perspective view of an evaporator for ice making according to a third embodiment of the present invention. 13 is a cross-sectional view of an ice-making evaporator according to a third embodiment of the present invention viewed from above. In the third embodiment of the present invention, the description is centered on the first connecting member 820 and the second connecting member 830, which are different from the second embodiment, and contents overlapping with the second embodiment are omitted. do.

12 and 13, the ice-making evaporator according to the third embodiment of the present invention includes a first connection member 820 and a second connection instead of the connection member 800 in the second embodiment. A member 830 may be provided.

The first connection member 820 is formed in a hollow conduit shape extending from the rear end, which is the other end of the first evaporator body 100, to the rear end, which is the other end, of the second evaporator body 300. The first connecting member 820 may have a circular cross section, but is not limited thereto.

As shown in FIG. 12 , the first connection member 820 may have one end coupled to the other end surface 103 of the first evaporator body and the other end coupled to the other end surface 303 of the second evaporator body.

A first connection space 821 is formed inside the first connection member 820 . The other end of the first refrigerant passage 114 and the other end of the third refrigerant passage 314 are connected through the first connection space 821 .

In this case, the first body space 112, the first connection space 821, and the third body space 312 may have the same cross-sectional area. Accordingly, the refrigerant can smoothly move through the first body space 112 , the first connection space 821 and the third body space 312 .

The second connection member 830 is also formed in a hollow conduit shape extending from the rear end, which is the other end of the first evaporator body 100, to the rear end, which is the other end of the second evaporator body 300, and is formed in the shape of a first connection. Like the cross section of the member 820, it may be formed in a circular shape.

At this time, there is no limitation on the position at which both ends of the second connecting member 830 are coupled. For example, as shown in FIG. 12, one end of the second connection member 830 is coupled to the side surface of the second body space 113 of the first evaporator body 100, and the other end of the second connection member 830 The end may be coupled to a side surface of the fourth body space 313 of the second evaporator body 300 . In this case, there is an advantage in that the material cost can be reduced by minimizing the length of the second connecting member 830 .

At this time, a second connection space 822 is formed inside the second connection member 830 . The other end of the second refrigerant passage 115 and the other end of the fourth refrigerant passage 315 are connected through the second connection space 822 .

In this case, the second body space 113, the second connection space 822, and the fourth body space 313 may have the same cross-sectional area. Accordingly, the refrigerant can smoothly move through the second body space 113 , the second connection space 822 and the fourth body space 313 .

Although the ice-making evaporator according to various embodiments of the present invention has been described above, the ice-making evaporator according to the present embodiment may not be installed only inside the ice maker, but may also be installed in a refrigerator that needs to be installed to make ice. It can be clearly understood by those skilled in the art to which the present invention belongs.

As described above, the preferred embodiments according to the present invention have been reviewed, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope in addition to the above-described embodiments is a matter of ordinary knowledge in the art. It is self-evident to them. Therefore, the foregoing embodiments are to be regarded as illustrative rather than restrictive, and thus the present invention is not limited to the foregoing description, but may be modified within the scope of the appended claims and their equivalents.

100 First evaporator body 314 Third refrigerant flow path
101 first evaporator body end surface 315 fourth refrigerant passage
102 discharge hole 320 third guide wall
103 other end surface of the first evaporator body 330 fourth guide wall
110 first body space dividing wall 340 second insulating wall
111 First refrigerant circulation hole 341 Second insulation space
112 first body space 400 second protruding member
113 second body space 410 second projecting space dividing wall
114 first refrigerant passage 420 third partition wall
115 second refrigerant flow path 421 third through hole
120 first guide wall 422 third protrusion space
130 second guide wall 423 third inlet space
140 first insulating wall 424 third outflow space
141 First insulation space 430 Fourth partition wall
200 first protruding member 431 fourth through hole
210 First protrusion space separating wall 432 Fourth protrusion space
220 first partition wall 433 fourth inlet space
221 first through hole 434 fourth outflow space
222 first protruding space 440 second protruding member lower end
223 first inlet space 500 refrigerant inlet
224 First outflow space 510 Refrigerant injection pipe
230 second partition wall 600 refrigerant outlet
231 second through hole 610 refrigerant discharge pipe
232 Second protrusion space 620 Discharge space
233 Second inlet space 700 Hot gas inlet
234 Second outflow space 710 Hot gas injection pipe
240 lower part of the first protruding member 720 hot gas guide wall
300 second evaporator body 800 connecting member
301 second evaporator body end surface 810 connecting member partition wall
303 second evaporator body other end surface 811 first connection space
310 second body space dividing wall 812 second connection space
311 second refrigerant circulation hole 820 first connecting member
312 third body space 830 second connecting member
313 fourth body space

Claims (27)

A first evaporator body extending from one side to the other side;
a first body space separating wall partitioning the inside of the first evaporator body into a first body space and a second body space formed side by side along an extending direction of the first evaporator body;
a refrigerant inlet provided at one end of the first evaporator body to inject refrigerant into the first body space;
a refrigerant outlet provided at one end of the first evaporator body and discharging the refrigerant flowing out from the second body space to the outside;
a plurality of first protruding members extending from the first evaporator body to one side;
a first protruding space dividing wall dividing the inside of the first protruding member into a first protruding space and a second protruding space;
a first refrigerant passage formed so that the refrigerant moves from one end to the other end through the first body space and passes through the first protruding spaces of the plurality of first protruding members; and
The other end and the other end of the first refrigerant passage are connected and the refrigerant moves from the other end to one end through the second body space, but is formed to pass through the second protruding space of the plurality of first protruding members a second refrigerant passage; Including, an evaporator for ice making. According to claim 1,
The first refrigerant passage and the second refrigerant passage are formed side by side in a lateral direction. According to claim 1,
The first protruding members are disposed in a row with a predetermined interval in the longitudinal direction of the first evaporator body. According to claim 1,
The first body space and the second body space have a width-to-height ratio of 3:1 to 1.5. According to claim 1,
The ratio of the length of the distance between the first protruding member adjacent to the other end surface of the first evaporator body and the width of the first protruding member to the other end surface is 1:0.9 to 1.1. According to claim 1,
The first protruding member is formed in a circular cross section perpendicular to the longitudinal direction and formed in a hemispherical shape with one end convex outward. According to claim 1,
The refrigerant inlet injects the refrigerant in a longitudinal direction of the first body space. According to claim 7,
The refrigerant inlet protrudes toward the first protruding space of the first protruding member adjacent to one end of the first evaporator body. According to claim 1,
a hot gas inlet formed on one side of the refrigerant inlet to inject hot gas into the first body space; Including more,
The hot gas inlet injects the hot gas in a longitudinal direction of the first body space. According to claim 9,
a hot gas guide wall formed at one end of the first body space to guide the hot gas injected through the hot gas inlet toward the first protrusion space; Further comprising an evaporator for ice making. According to claim 1,
The first protruding space is divided into a first inlet space and a first outlet space formed in the longitudinal direction of the first protruding member, the first inlet space and the first outlet space having one end connected so that fluid communication is possible,
The first refrigerant passage sequentially passes through the first inflow space and the first outflow space,
The second protruding space is divided into a second inlet space and a second outlet space formed in the longitudinal direction of the first protruding member, the second inlet space and the second outlet space having one end connected so that fluid communication is possible,
The second refrigerant passage sequentially passes through the second inlet space and the second outlet space. According to claim 11,
Areas of cross sections perpendicular to the longitudinal direction of the first body space, the second body space, the first inlet space, the first outlet space, the second inlet space, and the second outlet space are formed to be the same, Evaporator for ice making. According to claim 11,
The first protruding space is provided with a first dividing wall partitioning the first inflow space and the first outflow space so that cross sections perpendicular to the longitudinal direction of the first inflow space and the first outflow space are the same,
At one end of the first partition wall, a first through hole is formed with an area equal to the area of the cross section perpendicular to the longitudinal direction of the first inflow space and the first outflow space,
The second protruding space is provided with a second partition wall partitioning the second inflow space and the second outflow space such that cross sections perpendicular to the longitudinal direction of the second inflow space and the second outflow space are the same,
An ice-making evaporator, wherein a second through-hole is formed at one end of the second partition wall with the same area as cross sections of the second inflow space and the second outflow space perpendicular to the longitudinal direction. According to claim 13,
The first through hole and the second through hole are formed adjacent to an inner end surface of the first protruding member. According to claim 11,
a first refrigerant circulation hole such that the other end of the first body space separating wall is connected to the other end of the first refrigerant passage and the second refrigerant passage; is formed, the evaporator for ice making. According to claim 15,
The first refrigerant circulation hole extends from an inner lower surface to an upper surface of the first evaporator body. According to claim 15,
Wherein the ratio of the area of the first refrigerant circulation hole to the area of the cross section perpendicular to the longitudinal direction of the first outflow space is 1.5 to 2:1. According to claim 15,
The first refrigerant circulation hole is formed adjacent to the other end surface of the evaporator body. According to claim 1,
a first insulating wall partitioning the first evaporator body up and down such that an adiabatic space is formed at an inner upper portion of the first evaporator body; Further comprising an evaporator for ice making. According to claim 13,
a first insulating wall partitioning the first evaporator body up and down such that an adiabatic space is formed at an inner upper portion of the first evaporator body;
a first guide wall extending upward from an upper end of the first partition wall so that the refrigerant moves from the first body space to the first inflow space; and
a second guide wall extending upward from an upper end of the second partition wall so that the refrigerant moves from the second inlet space to the second body space; Including more,
The first insulating wall extends to the first guide wall and the second guide wall of the first protruding member adjacent to the rear end surface of the first evaporator body. According to claim 1,
A discharge space formed in fluid communication with the second body space is formed inside one end of the first evaporator body,
The refrigerant outlet is formed through the first evaporator body in an extension direction of the first protruding member so that the discharge space can communicate with the outside. According to claim 1,
A second evaporator body extending from one side to the other side;
a second body space dividing wall partitioning the inside of the second evaporator body into a third body space and a fourth body space formed side by side along an extending direction of the second evaporator body;
a plurality of second protruding members extending from the second evaporator body to one side;
a second protruding space dividing wall dividing the inside of the second protruding member into a third protruding space and a fourth protruding space;
a third refrigerant passage formed so that the refrigerant moves from the other end to one end through the third body space and passes through the third protruding spaces of the plurality of second protruding members; and
One end and one end of the third refrigerant passage are connected, and the refrigerant moves from one end to the other end through the fourth body space, but is formed to pass through the fourth protrusion space of the plurality of second protrusion members. a fourth refrigerant passage; Including more,
The other end of the third refrigerant passage is connected to the other end of the first refrigerant passage, and the other end of the fourth refrigerant passage is connected to the other end of the second refrigerant passage, so that the other end of the first refrigerant passage is An evaporator for ice making connected to the other end of the second refrigerant passage. 23. The method of claim 22,
a hollow connection member extending from the other end of the first evaporator body to the other end of the second evaporator body; and
a connecting member separating wall partitioning the inside of the connecting member into a first connecting space and a second connecting space formed in an extending direction of the connecting member; Including more,
The other end of the third refrigerant passage is connected to the other end of the first refrigerant passage through the first connection space;
The other end of the fourth refrigerant passage is connected to the other end of the second refrigerant passage through the second connection space. According to claim 23,
The first body space, the first connection space, and the third body space have the same cross-sectional area,
The second body space, the second connection space, and the fourth body space have the same cross-sectional area. According to claim 23,
One end of the connecting member partition wall is coupled to the other end of the first body space partition wall, and the other end of the connecting member partition wall is coupled to the other end of the second body space partition wall. According to claim 25,
The connecting member is bent so that the first evaporator body and the second evaporator body are disposed parallel to each other in a direction perpendicular to an extension direction. 23. The method of claim 22,
a first connection member extending from one side of the other end of the first evaporator body to one side of the other end of the second evaporator body and having a first connection space formed therein; and
a second connecting member extending from the other side of the other end of the first evaporator body to the other side of the other end of the second evaporator body and having a second connection space formed therein; Including more,
The other end of the third refrigerant passage is connected to the other end of the first refrigerant passage through the first connection space;
The other end of the fourth refrigerant passage is connected to the other end of the second refrigerant passage through the second connection space.

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