KR101266445B1 - Soak protrusion of ice making unit - Google Patents

Abstract

The present invention relates to an immersion protrusion of an ice making unit, and more particularly, to an immersion protrusion of an improved ice making unit for preventing corrosion occurring on the surface of a immersion protrusion or a welding portion of a immersion protrusion, and a joint. The upper part has a coupling blade 21a formed at both sides, and a coupling member 21 having a male coupling portion 21b formed at the lower end thereof, and a female coupling portion on the inner circumferential surface of the upper edge portion so as to be coupled to the lower end of the coupling member 21 ( 22a) includes an immersion protrusion 20, and the coupling member 21 forms a coupling blade 21a on both sides and a cylindrical male engagement portion 21b downward, and the immersion protrusion 20 ) Is the immersion members 22 and 23 having the female engagement portions 22a and 23a, and may include an ice making cap 30 on the outer circumferential surface of the immersion protrusion 20.

Description

Soak protrusion of ice making unit

The present invention is referred to as immersion protrusions (ice making protrusions, dipping means, cooling protrusions, etc.) of an ice making unit (製氷 unit, forming an immersion protrusion in the evaporation pipe, a unit formed with a drip tray, hereinafter referred to as an ice making unit), in the following In particular, the present invention relates to an immersion protrusion of an improved ice making unit for preventing corrosion occurring on the surface of the immersion protrusion or the welded or joined portion of the immersion protrusion.

Generally known conventional ice makers are known as ice makers (icemakers) for making ice, as shown in FIGS. 1A and 1B.

Conventional ice makers comprise an ice maker body with a cooling system (freezing cycle) and an ice maker unit. The cooling system (refrigeration cycle) includes a compressor, a condenser and an evaporator tube, which, when driven, cools the periphery of the evaporator tube so that ice is produced in the immersion protrusions coupled to the evaporator tube. An ice making plate (also referred to as an ice making substrate) shown in FIG. 1B is formed on an upper surface of the plate to form an evaporating tube connected to the ice making system cooling system, and below the evaporating tube, an immersion protrusion is formed which is immersed in the supplied water.

The ice making unit forms an immersion protrusion under the evaporation tube formed in the ice making plate, and the immersion protrusion is composed of drip trays which are immersed in water, and the water plate is periodically filled with water, and the lower part of the ice making plate is immersed in water. The immersion protrusions form a immersion state of a suitable height. One side of the drip tray is provided with pivoting means for discharging the ice-making water which is not frozen in the drip tray by tilting the drip tray. On the other hand, as a coupling structure of the ice maker and the evaporator tube as shown in Figure 1c, Figure 1d, the ice making plate known in the Patent Publication No. 10-2004-0085605 is composed of an ice making plate body and an ice making projection. It is known that the structure is coupled to the evaporator tube and cooled when the evaporator tube is cooled. The ice making plate body is formed of a metal material having good thermal conductivity such as copper (Cu) so as to easily absorb cold air from the evaporation tube, and the ice making protrusions are formed integrally when forming the ice making plate body to reduce the thermal conductivity efficiency of the ice making plate. The evaporation tube is press-pressed to the mounting groove formed on the upper surface of the ice-making plate body, and the conventional methods used for the combination of the ice-making plate body and the evaporation tube improve heat loss, and In the coupling method of the immersion protrusions, the contact area between the outer circumferential surface of the evaporator tube and the ice-making plate body is increased, but the cooling efficiency of the immersion protrusion is increased, but the corrosion in the immersion protrusion is not fundamentally prevented, and the coupling structure is complicated.

In addition, the ice making plate of the ice making unit shown in FIGS. 1E and 1F is disclosed in Korean Patent Laid-Open Publication No. 10-2006-0036986, and includes a plurality of immersion protrusions, but the method of manufacturing the conventional ice making plate described in this figure is When the ice sheet is made of aluminum (Al), an evaporation tube made of copper (Cu) alloy is used, which is more thermally efficient than this material. However, since the ice making plate and the evaporation tube are fixed by solder, If the material of the ice plate and the evaporation tube is different, the coupling is not good and the freezing and swelling phenomenon of the evaporation tube may occur, and thus the cooling efficiency may decrease when used for a long time.

Figure 1g, 1h of the accompanying drawings relates to an ice maker and an ice making plate applied to the ice maker known in the Patent Publication No. 10-2005-0022967, the ice making plate is formed in a semi-circular shape, the submerged protrusions formed below each cooling fin (immersion protrusion) As an example showing that it can be made in various forms without being formed in a flat plate shape, it was formed to form a plurality of polygonal pillars or a plurality of circular pillars in order to increase the heat transfer area.

The above-mentioned immersion protrusion structures of all the previously known ice making plates are in the form of being directly immersed in water. Therefore, the immersion protrusion is integrally coupled to the ice making tube. The ice making tube and the immersion protrusion are made of copper and aluminum having high conductivity and good bending properties, and are sterilized to solve the growth problem of bacteria in the immersion protrusion of the ice making unit. Is processed.

In addition, in the corner portion of the ice-making tube filled with the refrigerant, surface corrosion is likely to occur, and bacteria are often proliferated, so that the sterilization treatment is repeated.

On the other hand, stainless steel has been used recently because there is little growth of bacteria, but has a weak bending property, the high occurrence rate of cracks due to defects when the coupling method of the ice-making tube and the immersion protrusion is filled with the refrigerant. In addition, the ice-making tube filled with the refrigerant is copper and aluminum, which is corroded when the internal pressure is increased, and when it is corroded, it is contained in ice and eventually becomes harmful to the human body. Therefore, plating is repeatedly performed. In addition, the loss due to the repeated plating is also increased, so even if there is a lot of heat loss immersion means harmless to the human body and a method of manufacturing the immersion means is required.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems in the prior art, and an object thereof is to provide an immersion means for reducing the surface corrosion of the immersion protrusion as much as possible.

The present invention, although weak in bending properties and disadvantages in terms of heat loss, the object of the present invention is to provide a immersion means of stainless (sus) material that is harmless to the human body because there is little growth of bacteria.

The present invention ultimately uses the existing refrigerant circulation line as it is, harmless to the human body as a means of harmless plating, sterilization, etc. of the entire ice-making pipe including the immersion protrusion, cost is reduced, to provide a immersion cap that can be manufactured separately Has its purpose.

Immersion protrusion of the present invention ice making unit for achieving the above object,

It is coupled to the ice making unit, the upper part of the rectangular front and rear is opened in a semi-cylindrical shape, the bottom surface formed the wing-shaped coupling blades on both sides to the left, right side, and the bottom of the bottom surface to form a round joint A coupling member; It is achieved as an immersion protrusion of the ice making unit comprising an immersion member formed on the inner circumferential surface of the female engaging portion to be fastened to the lower end of the coupling member.

Immersion protrusion of the present invention ice making unit for achieving the above object,

Wing-shaped coupling blades are formed on both sides to be coupled to the evaporator tube, and a female coupling portion is formed to be fastened to correspond to the male coupling portion of the coupling member downward, and the inclined middle portion and the bottom portion are extended and blocked. A hollow immersion member consisting of portions is preferable.
The immersion protrusion of the ice making unit of the present invention for achieving the above object is preferably an immersion protrusion of the ice making unit further comprises an ice making cap.

The present invention has an effect of providing an ice making unit having a stainless steel immersion protrusion that is hardly multiplied by bacteria in the ice making apparatus.

The present invention is ultimately applied to the existing ice making unit as it is, the plating, sterilization treatment, etc. of the entire ice making tube is unnecessary, the cost is reduced, and to provide a immersion cap for immersion protrusions that can be manufactured separately and harmless to humans There is this.

1A-1H show a generally known ice maker,
2 is a perspective view of an evaporation tube integrated with the present invention immersion protrusion,
3 is an exploded perspective view of the evaporation tube to which the present invention immersion protrusion is applied,
Figure 4 is an excerpt perspective view of the immersion protrusion of the present invention,
Figure 5a is an exploded view of an embodiment showing the inside of the immersion protrusion of the present invention ice making unit,
Figure 5b is an exploded view of another embodiment showing the inside of the immersion protrusion of the ice making unit of the present invention,
Figure 6a is a cross-sectional view of an embodiment showing the inside of the immersion protrusion of the ice making unit of the present invention,
Figure 6b is a cross-sectional view of another embodiment showing the inside of the immersion protrusion of the ice making unit of the present invention,
7 is an exploded perspective view of the evaporation tube to which the present invention immersion protrusion is applied,
8 is a view showing an example of a method of coupling the immersion protrusion and the evaporation tube.

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

Figure 2 of the accompanying drawings is a perspective view of the evaporation tube integrated with the present invention immersion protrusion, Figure 3 is an exploded perspective view of the evaporation tube applied with the present invention immersion projection, Figure 4 is an exploded perspective view of the immersion projection of the present invention.

The ice making unit to which the present invention immersion protrusion shown in the drawing is largely divided into an evaporation tube 40 and an immersion protrusion 20.

Immersion protrusion 20 is composed of a coupling member 21 and the immersion members 22, 23.

The immersion members 22 and 23 are divided into a immersion member 22 filled with a hollow and a immersion member 23 hollowed out as described below.

Coupling member 21 is inserted into (40) to be coupled, the upper portion to form a coupling blade (21a) on both sides.

Figure 5a is an exploded view of one embodiment showing the inside of the immersion protrusion of the ice making unit of the present invention, Figure 5b is an exploded view of another embodiment showing the inside of the immersion protrusion of the ice making unit of the present invention, Figure 6a is an immersion of the ice making unit of the present invention Figure 6 is a cross-sectional view of one embodiment showing the inside of the projection, Figure 6b is a cross-sectional view of another embodiment showing the inside of the immersion protrusion of the present invention ice making unit, Figure 7 is an exploded perspective view of the evaporation tube to which the immersion protrusion of the present invention is applied, Figure 8 is It is a figure which shows an example of the bonding method of an evaporation tube.

In the drawings, the immersion protrusion 20 of the first embodiment of the present ice making unit according to FIG. 5A has a rectangular horizontal plane so that the immersion protrusion 20 is coupled to the evaporation pipe 40, and upwards with respect to the bottom of the rectangle. Opened in the front and rear to form a semi-cylindrical shape, the left and right sides form a bottom surface formed with the wing-shaped coupling blades (21a) on both sides, and below the bottom surface of the cylindrical male joint portion (21b) Partially dug the inner circumferential surface of the upper end portion so as to be engaged with the formed coupling member 21 and the lower male fastening portion 21b of the coupling member 21, and then form a female coupling portion 22a on the inner circumferential surface thereof, While forming a cylindrical inclined toward the inside is made of the immersion member 22 filled with the same material.

In the drawing, the immersion member 23 according to the second embodiment of the present invention according to FIG. 5B forms a horizontal horizontal surface of a rectangle so as to be coupled to the evaporation tube 40. And a coupling member 21 formed by opening a semi-cylindrical shape, and having wing-shaped coupling blades 21a formed on both sides at the left and right sides thereof, and having a cylindrical male engagement portion 21b formed under the bottom surface again. To form the inner circumferential surface of the upper end portion so as to be fastened to the lower male fastening portion 21b of the coupling member 21, the inner coupling portion 23a is formed in the upper edge portion in a hollow shape, and the inclined middle portion ( 23b) and the intermediate portion 23b extends to form a hollow cylindrical shape consisting of a block 23c is blocked, forming a fastening portion 23a to form an inclined cylindrical downwards but the inside of the same material It is made of a filling immersion member 23.

Each of the immersion members 22 and 23 of the immersion protrusion 20 of the present invention forms an ice making cap 30 to be in close contact with an outer circumferential surface thereof. The ice making cap 30 is made of stainless steel to be inserted and closely covered to prevent corrosion and contamination caused by prolonged contact with water dipped in the outer circumferential surface of the immersion protrusion 20. As stainless steel is known, corrosion does not occur, which prevents the unsanitary side caused by the immersion corrosion of ice.

The ice making cap 30 has a cylindrical shape and forms an immersion protrusion insertion space a corresponding to the lower outer surface of the immersion members 22 and 23, and an upper edge of the immersion members 22 and 23 upwards. The opening 31 is formed to be in close contact with each other, and the intermediate wall portion 32 also forms an inclined surface to be inserted in correspondence with the outer circumferential surface of the immersion members 22 and 23, and the bottom is curved to protrude to the bottom surface 34 of the curved surface. Formed to form a cylindrical insertion structure that is in close contact with the outer peripheral surface of the immersion members (22, 23).

The assembly of the immersion member 22 of the immersion protrusion 20 of the present invention is inserted into the bottom of the evaporation tube 40 as shown in Figures 5a, 6a by inserting the blade-shaped coupling blade (21a) to the front and rear half It is inserted into the evaporator tube 40 opened in a cylindrical shape, and the female coupling part 22a is coupled to the male coupling part 21b by screwing.

The assembly of the immersion member 23 of the immersion protrusion 20 of the present invention is inserted into the bottom of the evaporator tube 40 as shown in Figure 5b and 6b by inserting the blade-shaped coupling blade (21a) to the front and rear half It is inserted into the evaporator tube 40 opened in a cylindrical shape, and the female coupling part 23a is coupled to the male coupling part 21b by screwing or forced press.

Such a combination of the evaporation tube 40 and the immersion protrusion 20 of the present invention ice making unit is inserted into the evaporation tube 40, the coupling piece 21 of the immersion protrusion 20 as shown in FIG. Dipping bonds in the bath are desirable.

20: immersion protrusion, 21: coupling member, 22, 23: immersion member, 30: ice making cap,

Claims (6)

delete In the immersion protrusion of the ice making unit,
The bottom surface 21 is coupled to the ice making unit, and the upper and rear surfaces of the rectangle are opened in a semi-cylindrical shape and have wing-shaped coupling blades 21a formed on both sides at left and right sides of the bottom surface 21. A coupling member 21 having a circular male fastener 21b formed downward;
Immersion protrusion of the ice-making unit comprising an immersion member 22 is formed on the inner peripheral surface of the engaging portion (21a) to form a female fastening portion (22a). delete The method of claim 2, wherein the immersion protrusion 20,
In order to be coupled to the evaporation tube 40, the left and right wing-shaped coupling blades 21a are formed on both sides, and the male coupling portions 21b of the coupling member 21 are formed in the lower portion. It is a hollow immersion member 23 is formed to form a fastening portion 23a to be fastened, and comprises an inclined middle portion 23b and a bottom portion 23c from which the middle portion 23b extends and is blocked. Immersion protrusion of the ice making unit characterized in that. The method according to claim 2 or 4,
Immersion protrusion of the ice making unit further comprises an ice making cap 30 in the immersion protrusion 20. The ice making cap 30 of claim 5,
An immersion protrusion insertion space a is formed corresponding to the immersion protrusion 20, and an opening 31 is formed to be in close contact with an upper edge of the immersion protrusion 20, and the intermediate wall part 32 is an immersion protrusion ( An immersion protrusion of the ice making unit, characterized in that the inclined surface is formed to be inserted corresponding to the outer circumferential surface of 20), and the bottom surface 34 of the curved surface protrudes.

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