KR102337939B1 - Ice maker - Google Patents

Abstract

The present invention relates to an ice maker with an improved structure, which comprises: a cover plate in which a plurality of first half-formed bodies are formed on a plate member and arranged to protrude, and a water inlet hole and a water outlet hole are formed at intervals in a double-hole structure on an outer surface of the first half-formed bodies; an ice-making plate which is a plate member arranged relative to the cover plate, and having a plurality of second half-formed bodies arranged to protrude in a direction opposite to the first half-formed bodies of the cover plate; a water supply pipe fixedly coupled to the cover plate, positioned on the outside of the first half-formed bodies on the side of the cover plate at an interval, and supplying water to the water inlet hole of each of the arranged first half-formed bodies; a refrigerant pipe provided in contact with the second half-formed bodies of the ice-making plate, and installed to circulate and supply cool air for ice-making; and a motor coupled to the cover plate, and driven to be closely arranged or separated on/from the ice-making plate by rotating the cover plate. According to the present invention, a plastic cover plate having a half-formed body and a copper ice-making plate are arranged relative to each other, and thus, various shapes of ice including sphere can be automatically formed, and ice with a complete shape can be formed. Also, ice can be automatically formed through a double-hole structure of the water inlet hole and the water outlet hole formed on the first half-formed bodies on the cover plate and transparent ice can be formed by preventing formation of bubbles while preventing expansion of the ice. In addition, the flow of a refrigerant is controlled through an efficient structural arrangement design of the refrigerant pipe, such that the overall ice-making efficiency can be improved while reducing ice-making time as compared to the conventional invention.

Description

Ice Maker {ICE MAKER}

The present invention relates to an ice maker for automatically forming and manufacturing ice of various shapes including spherical shapes, and more particularly, a cover plate having a half-formed body and an ice making plate are arranged relative to each other, and using the same, various types of ice including spherical shapes are formed. It has an improved structure that allows ice to be automatically formed and formed into a perfect shape, and can increase the efficiency for water supply and automatic forming and ice making of ice, and enables continuous and mass production of ice. It's about the ice machine.

In general, an ice maker is a device for making ice, and is mainly provided to make prismatic or half-moon-shaped ice.

Such an ice maker is often used as a single device for mass production of ice, and recently, it is installed in a refrigerator or a water purifier to provide ice.

Also, in recent years, the demand for ball-shaped ice having a spherical shape compared to conventional prismatic ice has been increasing, and techniques for ice making of spherical ice have been proposed.

Looking at prior art documents for performing ice making of conventional spherical ice, spherical shapes in Korean Patent Nos. 10-1400785 and 10-1660962, and Korean Patent Publication Nos. 10-2017-0077363 and 10-2020-0038110 A device for ice making (ball type) ice has been proposed and disclosed.

However, conventional ice makers including the aforementioned prior art documents have problems in that the ice making process is complicated or it is difficult to form and make completely spherical ice.

In addition, in the case of an industrial ice maker, a large amount of spherical ice is required, which cannot be solved, and there is a problem in that defects such as bubbles are generated during ice making.

Meanwhile, the applicant of the present application has proposed an ice ball maker that makes spherical (ball-shaped) ice through Korean Patent Registration No. 10-2071263, and is continuing research on the development of an ice maker for improved technology and practical use.

Republic of Korea Patent Publication No. 10-1400785 Republic of Korea Patent Publication No. 10-1660962 Republic of Korea Patent Publication No. 10-2017-0077363 Republic of Korea Patent Publication No. 10-2020-0038110

The present invention has been devised to solve the problems of the prior art and was devised in consideration of this. A cover plate having a half-formed body and an ice-making plate are arranged relative to each other, and various types of ice including a spherical shape are automatically formed using the same and a form having a complete shape. It is an object of the present invention to provide an ice maker having an improved structure that enables continuous production and mass production of ice, and increases the efficiency for water supply and automatic forming and ice making of ice. .

The present invention provides an ice maker having an improved structure to improve overall ice making efficiency, such as preventing the formation of bubbles and making transparent ice while preventing the expansion of ice that is automatically formed and made by the flow of water and refrigerant. Its purpose is to provide

The present invention is provided with different materials for the cover plate and the ice-making plate for ease of manufacture as well as workability such as ice-making efficiency and easy separation after ice-making. It is an object of the present invention to provide an ice maker having an improved structure that can be used.

In an ice maker according to the present invention for achieving the above object, a plurality of first half-formed bodies are formed on a plate member and arranged to protrude, and a water input hole and a water discharge hole are formed at intervals in a double hole structure on the outer surface of the first half-molded body. cover plate; an ice-making plate disposed to face the cover plate, wherein a plurality of second half-formed bodies are formed and arranged to protrude in a direction opposite to the first half-formed body having the cover plate; a water supply pipe fixedly coupled to the cover plate, spaced apart from the cover plate side of the first half molded body, and provided to supply water to each water input hole of the first half molded body that is formed and arranged in plurality; a refrigerant pipe provided to be in contact with the second half molded body of the ice making plate and installed to circulate and supply cool air for ice making; and a motor coupled to the cover plate and configured to be disposed in close contact with the ice-making plate or to be detachably driven by rotating the cover plate.

Here, the cover plate is made of a plastic material to prevent the cold air from being transmitted to the ice-making plate side, so that it is possible to easily separate the ice after ice-making from the ice-making plate having cold air when removing ice, and ice is trapped in the water during ice making. to prevent; The ice-making plate may be of a copper material so that cold air from the refrigerant tube side is transmitted well to increase ice-making efficiency.

Here, in the water inlet hole and the water outlet hole formed on the outer surface of the first half molded body on the cover plate side, the water outlet hole is formed to be positioned higher than the water input hole, thereby eliminating air bubbles in the ice being made and generating transparent ice. It can be configured to prevent the expansion of the ice while enabling it.

Here, in order to increase the cold air transfer efficiency and ice-making efficiency to the second half-formed bodies formed and arranged in plurality on the ice-making plate, the refrigerant pipe first zigzags so as to be in contact with the lower outer surface of each of the second half-formed bodies. A second zigzag arrangement structure in which the first refrigerant pipe part is installed in a type arrangement structure so that the supply of the refrigerant starts at the center point of the ice making plate, and the first refrigerant pipe unit is in contact with the left and right outer surfaces of each of the second half molded bodies sequentially However, it may be of a configuration in which the second refrigerant pipe part is installed so that the refrigerant is discharged from the outer direction of one edge.

Here, the first refrigerant pipe part has a refrigerant supply pipe so that the refrigerant is supplied from the central point of the ice-making plate, and after guiding it to one edge region of the ice-making plate, it is installed to form a flow of the refrigerant to the other edge region via the central region do; The second refrigerant pipe part is connected at the supply end of the first refrigerant pipe part, and after guiding it back to one edge area of the ice-making plate, it is installed so that a flow of refrigerant is formed to the other edge area via the central area, but the other edge It may be configured to be installed so that the final discharge of the refrigerant is made at the outermost side of the region.

Here, each of the first half molded body and the second half molded body has the same shape, and is provided to form ice into any one shape selected from spherical shape, star shape, diamond shape, and cube shape through mutual matching It may be a configuration that becomes

Here, the ice-making plate may be formed by nickel plating on the surface of the copper plate to prevent corrosion.

According to the present invention, by arranging the cover plate having the half-formed body and the ice-making plate to correspond to each other, ice of various shapes including spherical shapes can be formed automatically and ice can be made into a shape having a complete shape, but on the first half-formed body on the cover plate side Through the double hole structure of the water inlet and water outlet formed in the By controlling this, it is possible to provide a useful effect of improving the overall ice making efficiency while shortening the ice making time compared to the conventional one.

According to the present invention, it is possible to provide an ice maker having an improved structure that enables continuous and mass production of ice, and increases workability such as ease of manufacture as well as ice making efficiency and easy separation after ice making. The state can provide an ice maker with an improved structure.

1 is a block diagram showing an ice maker according to an embodiment of the present invention.
2 is a view showing a cover plate and a water supply pipe in the ice maker according to an embodiment of the present invention.
3 is a bottom perspective view of the main part of the ice maker according to the embodiment of the present invention.
4 is a view showing the detailed configuration of the refrigerant pipe side and the refrigerant flow in the ice maker according to an embodiment of the present invention.
5 is a view showing a configuration including a motor in the ice maker according to the embodiment of the present invention.
6 is a view showing a state in which the cover plate is aligned with the ice maker in the ice maker according to the embodiment of the present invention.
7 is a view showing a state in which the cover plate is separated from the ice maker in the ice maker according to the embodiment of the present invention.

Preferred embodiments of the present invention will be described with reference to the accompanying drawings as follows, and through such detailed description, it will be possible to better understand the purpose and configuration of the present invention and its features.

The ice maker according to an embodiment of the present invention proposes a main configuration for an ice maker that is installed inside the main body case and produces ice in a desired shape such as a spherical shape by exerting an ice making function according to the supply of cold air.

In detail, the ice maker 100 according to the embodiment of the present invention includes a cover plate 110 , an ice maker plate 120 , a water supply pipe 130 , a refrigerant pipe 140 , and as shown in FIGS. 1 to 7 , and It consists of a configuration including a motor (150).

The cover plate 110 has a plurality of first half molded bodies 112 formed on the plate member 111 and arranged to protrude, and a water inlet 113 and a water outlet hole ( 114) are spaced in a double hole structure.

A plurality of the first half-formed bodies 112 are arranged in a matrix structure on the plate member 111 .

Through the double hole structure formed by the water inlet 113 and the water outlet 114 , it is possible to provide a function of preventing the expansion of ice while enabling transparent ice generation by eliminating air bubbles in the ice being made.

At this time, in the water input hole 113 and the water discharge hole 114 that are spaced apart in the double hole structure, it is preferable to form the water discharge hole 114 to be positioned higher than the water input hole 113, and , it is possible to provide the advantage of further increasing the ice making efficiency, such as preventing the expansion of the ice while enabling the generation of transparent ice by eliminating air bubbles in the ice being made.

The ice-making plate 120 is a plate member 121 disposed to face the cover plate 110 , and is opposite to the first half molded body 112 of the cover plate 110 on the plate member 121 . A plurality of second half molded bodies 122 are formed and arranged to protrude in the direction.

A plurality of the second half molded bodies 122 are arranged in a matrix structure on the plate member 121 .

The first half-formed body 112 of the cover plate 110 and the second half-formed body 122 of the ice-making plate 120 have a symmetrical structure in shape, and when combined, form one complete shape. provided

Each of the first half molded body 112 and the second half molded body 122 has the same shape, but is formed into any one shape selected from among a spherical shape, a star shape, a diamond shape, and a cube shape through mutual matching. It may be a half molded body provided to mold the.

The first half molded body 112 and the second half molded body 122 are not limited to the above-described examples, and may be provided in more various shapes through shape transformation or modification.

The cover plate 110 is provided in a rotatable structure so as to be closely disposed or separated from the ice-making plate 120 disposed to face each other.

That is, the cover plate 110 and the ice-making plate 120 are provided so that the plate members facing each other coincide or separate. The cover plate 110 is hinged to the ice-making plate 120 side, but rotates. It can be installed in a drivable structure.

The cover plate 110 is provided as a rotatable moving body, and the ice making plate 120 is provided as a fixed body.

The cover plate 110 and the ice making plate 120 are vertically arranged in parallel and installed to rotate in the vertical direction with the upper end of the cover plate 110 as a pivot axis.

The cover plate 110 is made of a plastic material to prevent cold air from being transmitted to the ice-making plate 120 side, so that it is possible to easily separate the ice after ice-making from the ice-making plate 120 having cold air when removing ice. It is preferable to configure it to prevent the phenomenon of ice being trapped in the water.

The ice-making plate 120 is preferably made of a copper material having excellent thermal conductivity so that cold air from the refrigerant pipe 140 side is transmitted well to increase ice-making efficiency.

The ice-making plate 120 includes the plate member 121 as a copper plate, and it is preferable to use a nickel-plated surface to prevent corrosion on the copper plate side.

The water supply pipe 130 is fixedly coupled to be positioned on the outside of the cover plate 110, but is arranged to be slightly spaced apart from the first half molded body 112 on the cover plate 110 side, and is formed in a plurality The first half molded body 112 is installed to spray and supply water to be used for ice making to a position corresponding to the water input hole 113 of each of the half molded bodies 112 by using a pumping pressure.

The water supply pipe 130 is installed to supply water to the water inlet hole 113 on the cover plate 110 side in a state where the cover plate 110 and the ice making plate 120 are matched. The water supply holes are formed at positions corresponding to the water inlet holes 113 of the , respectively, and are arranged in a straight line.

The water supply pipe 130 is connected to the water supply tank.

The water supply pipe 130 may be installed in a distribution type arrangement structure in which a number is distributed according to the arrangement structure of the first half molded body 112 on the side of the cover plate 110, and water supply by a sequential flow is sometimes difficult. It may be installed to make it happen.

The refrigerant pipe 140 is provided to be in contact with the second half molded body 122 of the ice making plate 120 and is installed to circulate and supply cool air for ice making.

The refrigerant pipe 140 is installed on the ice-making plate 120 to increase the cold air transfer efficiency and the ice-making efficiency to the second half molded body 122 that is formed and arranged.

The refrigerant pipe 140 is provided with a first refrigerant pipe part 141 in a first zigzag arrangement structure so as to be in contact with the lower outer surface of each of the second half molded bodies 122 arranged on the ice-making plate 120, but the ice-making plate Installed so that the supply of refrigerant starts at the central point of 120, and connected in a second zigzag arrangement structure to be in contact with the left and right outer surfaces of each of the second half molded bodies 122 consecutively to the first refrigerant pipe part 141, but It is preferable to install the second refrigerant pipe part 142 so that the refrigerant is discharged from the outer side of the one edge.

In other words, the first refrigerant pipe part 141 has a refrigerant supply pipe 141a so that the refrigerant is supplied from the central point of the ice-making plate 120, guides it to one edge region of the ice-making plate 120, and then passes through the central region. Therefore, it is preferable to install it so that the flow of the refrigerant is formed in the other edge area.

The second refrigerant pipe part 142 is connected at the supply end of the first refrigerant pipe part 141, and after guiding it back to one edge area of the ice making plate 120, it passes through the central area to the other edge area of the refrigerant. It is installed so that a flow is formed, but it is preferable to install so that the final discharge of the refrigerant is made from the outermost side of the other edge region.

The motor 150 is configured to provide a rotational force for matching or separating from the ice-making plate 120 by closely contacting the cover plate 110 with the ice-making plate 120 .

The motor 150 enables automatic molding and ice making on the side of the ice maker 100 by closely contacting the cover plate 110 with the ice maker plate 120 to match, and provides an ice maker plate ( 120), which is a power supply means that enables ice removal by separating from it.

The motor 150 may selectively use a gear or a bracket to provide a structure rotatable with respect to the cover plate 110 .

The motor 150 induces rotation of the cover plate 110 side when the drive shaft rotates forward or reversely, so that it can be combined with or separated from the ice-making plate 120 . .

In addition, in the present invention, the present invention may include a control unit for automatically checking the current state of the device, replacement time of parts, and a defective part, and controlling the overall operation of the device.

Through the control unit, the power saving function can be memorized to minimize operation at midnight or non-use time to save power, and to perform the function of optimizing the operation of the device by itself according to the time of day or seasonal situation It can be configured, and it can be configured to operate in response to other customer needs.

In addition, in the present invention, a user using the ice machine 100 can have a configuration including a communication module that enables communication with a user terminal owned by the user or a cloud server used by the owner of the ice machine 100, Through this, information on the current state of the ice maker 100, replacement time of parts, and faulty parts is transmitted to the cloud server or user terminal, and the operation of the device can be remotely controlled and monitored from the user terminal.

The operation sequence and operation of the ice maker 100 according to the present invention having the above-described configuration will be described as follows.

The motor 150 is driven to rotate forward to move the cover plate 110 , so that the ice-making plate 120 and the plate member are brought into close contact with each other to perform matching.

At this time, the first half-formed body 112 of the cover plate 110 and the second half-formed body 122 of the ice-making plate 120 are matched at positions corresponding to each other to form one complete molded body.

In this way, water is supplied through the water supply pipe 130 in a state in which the cover plate 110 and the ice making plate 120 are aligned.

At this time, the water supply pipe 130 supplies water to the water inlet holes 113 formed in each of the first half molded bodies 112 on the cover plate 110 side, so that the first half molded bodies 112 and the second are in a matched state. Water is put into the inner space of the half molded body 122 and the inside is filled with water.

By filling the internal space of the first half-molded body 112 and the second half-molding body 122 in a matched state with water, and at the same time supplying and circulating the refrigerant from the refrigeration system having a refrigeration cycle to the refrigerant pipe 130, cold air is produced transmit

Ice in various shapes such as spherical shapes is automatically formed by the transfer of cold air from the portion of the second half-formed body 122 on the side of the ice-making plate 120 that is in contact with the refrigerant pipe 130, and the cold air spreads throughout the ice-making process to form a complete shape.

At this time, in the present invention, the formation of water inlet holes 113 and water outlet holes 114 spaced apart in a double hole structure on the first half molded body 112 prevents bubbles from being generated in the ice being made. By removing air bubbles, it is possible to create transparent ice, and by the action of the water discharge hole 114, it is possible to provide advantages such as preventing the expansion of the ice that is molded and made inside the ice. It can increase efficiency.

In addition, in the present invention, the cover plate 110 is provided with a metal material including a copper material and the ice-making plate 120 is provided with a plastic material to use different materials to prevent ice from being trapped in the water during ice making through cold air transmission. can do.

Furthermore, in the present invention, the refrigerant starts to be supplied from the central point of the ice-making plate 120 through the first refrigerant pipe part 141, is guided to one edge region of the ice-making plate 120, and then passes through the central region to the other edge. A flow of refrigerant is formed in the region, and then is guided again to the edge region of one side of the ice-making plate 120 through the second refrigerant pipe part 142, and then the flow of refrigerant is formed to the edge region of the other side via the central region, As having a system in which the refrigerant is finally discharged from the outermost side of the other edge region, it is possible to increase ice making efficiency such as ice making as a whole while enabling quick ice making.

In the inner space of the first half-molded body 112 and the second half-molded body 122 in the state of being matched in this way, ice is automatically formed into a desired shape including a spherical shape and ice is made, and then the supply of cold air by the refrigerant is blocked. And, by supplying and circulating refrigerant-free air from a refrigeration system having a refrigeration cycle, heat is transferred to the refrigerant pipe 130 and the ice made in the form of a complete body is controlled to slightly melt.

Then, the motor 150 is driven in reverse rotation to rotate the cover plate 110 in the opposite direction to the previous one, thereby separating it from the ice making plate 120 .

At this time, since the cover plate 110 and the ice-making plate 120 are provided with different materials, the ice-making plate 120 having cold air and the cover plate 110 in contact with the ice-making plate 120 having cold air when ice is removed from the ice-making process are easy. One separation can be performed.

Accordingly, the ice made at the same time as the cover plate 110 is separated from the ice-making plate 120 is also separated from the inner space of the first half molded body 112 and the second half molded body 122 , and the When continuous rotation is performed, the naturally made ice is automatically dropped in the downward direction.

The naturally-falling ice is immediately stored in an ice bucket, and through the repeated operation of the above-described process, ice having a certain shape, such as a spherical shape, can be continuously manufactured and mass-produced.

Accordingly, according to the ice maker 100 according to the present invention having the above-described configuration, the cover plate 110 and the ice-making plate 120 having the half-formed body are disposed relative to each other, and cold air is supplied using the cover plate 110 to provide various shapes including a spherical shape. of ice can be automatically formed and formed into a complete shape, and a double hole of a water input hole 113 and a water outlet hole 114 formed on the first half molded body 112 on the cover plate 110 side Through the structure, it is possible to make transparent ice by preventing the generation of bubbles while preventing the expansion of the ice that is automatically formed and ice-making, and by controlling the flow of the refrigerant through the efficient structural arrangement design of the refrigerant pipe 140, overall ice making compared to the existing one. It can provide the advantage of improving the efficiency.

The embodiments described above are merely illustrative of preferred embodiments of the present invention and are not limited to these embodiments, and various modifications and variations by those skilled in the art within the technical spirit and claims of the present invention It will be said that this can be done, and it will be said that it falls within the scope of the technical rights of the present invention.

100: ice machine 110: cover plate
111: plate member 112: first half molded body
113: water inlet 114: water outlet
120: ice making plate 121: plate member
122: second half molded body 130: water supply pipe
140: refrigerant pipe 141: first refrigerant pipe part
142: second refrigerant pipe 150: motor

Claims (7)

a cover plate in which a plurality of first half-formed bodies are formed on the plate member and arranged to protrude, and the water inlet and water outlet holes are formed at intervals in a double hole structure on the outer surface of the first half-formed body;
an ice-making plate disposed to face the cover plate, wherein a plurality of second half-formed bodies are formed and arranged to protrude in a direction opposite to the first half-formed body having the cover plate;
a water supply pipe fixedly coupled to the cover plate, spaced apart from the cover plate side of the first half molded body, and provided to supply water to each water input hole of the first half molded body that is formed and arranged in plurality;
a refrigerant pipe provided in contact with the second half molded body of the ice making plate and installed to circulate and supply cool air for ice making;
a motor coupled to the cover plate and configured to be placed in close contact with the ice-making plate or to be detachably driven by rotating the cover plate; includes,
The cover plate is made of a plastic material so that cold air is not transmitted to the ice-making plate side, so that it is possible to easily separate the ice after ice making from the ice-making plate having cold air when removing ice, and to prevent the phenomenon of ice being trapped in the water during ice making. do,
The ice-making plate is provided with a copper material so that cold air from the refrigerant tube side is well transmitted to increase ice-making efficiency,
The ice maker according to claim 1, wherein the cover plate and the ice maker are vertically arranged in parallel, and are installed to be rotatable in the vertical direction with an upper end of the cover plate as a pivot axis. delete The method of claim 1,
In the water input hole and the water outlet hole formed on the outer surface of the first half molded body on the cover plate side, the water outlet hole is formed to be positioned higher than the water input hole, thereby eliminating air bubbles in the ice to be made and making transparent ice possible. An ice maker configured to prevent the expansion of ice. The method of claim 1,
In order to increase the cold air transfer efficiency and the ice making efficiency to the second half molded body arranged in a plurality of the refrigerant pipes on the ice making plate,
Install the first refrigerant pipe portion in a first zigzag arrangement structure so as to be in contact with the lower outer surface of each of the second half molded bodies, but install so that the supply of the refrigerant starts at the center point of the ice-making plate,
A second refrigerant pipe part is installed so as to be connected to the first refrigerant pipe part in a second zigzag arrangement structure so as to be in contact with the left and right outer surfaces of each of the second half molded bodies in succession, but the discharge of the refrigerant is formed in the outer direction of one edge,
The first refrigerant pipe part has a refrigerant supply pipe so that the refrigerant is supplied from the central point of the ice-making plate, and is installed so that the refrigerant flows to the other edge region through the central region after guiding it to one edge region of the ice-making plate;
The second refrigerant pipe part is connected at the supply end of the first refrigerant pipe part, and after guiding it back to one edge area of the ice-making plate, it is installed so that a flow of refrigerant is formed to the other edge area via the central area, but the other edge An ice maker, characterized in that it is installed so that the final discharge of the refrigerant is made at the outermost side of the area. delete The method of claim 1,
Each of the first half molded body and the second half molded body is made of the same shape,
An ice maker, characterized in that it is provided to shape ice into any one shape selected from among a spherical shape, a star shape, a diamond shape, and a cube shape through mutual matching. The method of claim 1,
The ice maker is characterized in that the surface of the ice maker is nickel plated to prevent corrosion of the copper plate.

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