KR102319482B1 - Funny transparent ice maker home use - Google Patents

Abstract

The present invention relates to a funny ice making method comprising: a transparent ice generating step of cooling ice-making water around a cooling protrusion while rocking and rotating a rocking plate to form transparent ice around the cooling protrusion; a translucent ice generating step of cooling ice-making water around the cooling protrusion while not rotating the rocking plate to form translucent ice around the cooling protrusion; and a step for alternating the transparent ice generating step and the translucent ice generating step. According to the funny ice making method, ice-making water can be sufficiently fluctuated by rocking and rotation of the rocking plate without the need for rocking an ice-making tray itself, so that transparent ice can be easily formed without a large-sized ice-making tray, the transparent ice generating step and the translucent ice generating step can be made according to whether or not the rocking plate rocks and rotates, and transparent ice and translucent ice are alternately and repetitively formed so that a transparent part and a translucent part can be formed like a tree's ring in a single piece of ice, thereby providing ice with a fun and excellent esthetic feeling beyond simple transparent ice.

Description

How to make funny ice {FUNNY TRANSPARENT ICE MAKER HOME USE}

The present invention relates to an ice-making method, and more particularly, to a funny ice-making method in which ice-making water in an ice maker is shaken to make compact and transparent ice and translucent ice mixed.

In general, an ice maker is a device for making ice by cooling supplied ice-making water.

A conventional ice maker includes an ice maker body and an ice maker unit, wherein the ice maker body includes an ice storage for storing ice made by the ice maker unit, and the ice maker unit includes an ice maker, a cooling plate and an evaporator, and an ice maker. is filled with ice-making water, and a plurality of cooling protrusions immersed in the ice-making water are installed on the lower surface of the cooling plate. The evaporation tube is installed on the upper surface of the cooling plate and is connected to the refrigeration system. A refrigerant flows into the evaporation tube, and the cooling plate and the cooling protrusion are cooled by heat exchange of the refrigerant.

Recently, there has been provided an ice maker capable of producing transparent ice by preventing the cloudiness of the ice becoming cloudy as air bubbles in the ice-making water freeze.

The cloudiness that occurs in the ice during the ice making process is caused by the non-uniform ice making speed during the ice making process. As the water partially surrounded by the previously made ice turns into ice and the volume increases, the previously made ice tissue is destroyed and occurs within the ice tissue. The voids appear as white turbidity.

In order to remove such cloudiness, it is necessary to generate fluctuations in the ice-making water in the ice-making dish to remove voids or air bubbles generated in the ice produced during the ice-making process.

In order to generate fluctuations in the ice-making water, as a conventional ice-making apparatus, it has been proposed that a rocking plate with a structurally L-shaped rocking plate is installed at the lower part of the ice-making dish, but in the prior art, one end of the shaking plate is vibration-free from the outside of the water dish. Since the bent part becomes the axis, there was a problem in that the installation structure for implementing this on the water dish was complicated, and the detection structure for detecting ice in contact with the rocking plate was implemented on the water dish, so it had a more complicated structure.

In addition, in order to generate fluctuations in the ice-making water, as a conventional ice-making apparatus, one in which one side of the ice-making dish is extended and a deflected axial point is formed in order to increase the swinging range of the ice-making dish has been proposed.

However, in the prior art described above, since one side of the ice-making apparatus is extended, the ice-making dish becomes large, and a space for rotating the ice-making dish is required for removing ice. Accordingly, there is a problem in that the amount of ice-making water in the ice-making dish is increased, so that the ice-making efficiency is lowered.

In addition, when the conventional transparent ice maker uses a spray method to produce transparent ice, it is difficult to arbitrarily control the transparency, and there is no choice but to produce transparent ice with uniform transparency. .

Korean Patent No. 10-1391832 (Ice making unit of an ice maker and a method for preventing cloudiness using the same)

The present invention is to solve the problems of the prior art described above, and provides a method for making transparent ice by shaking ice water without shaking the ice tray, and providing a compact and funny ice making method in which transparent and semi-transparent ice are mixed. will provide

In order to achieve the above object, a funny ice-making method according to the present invention includes an ice-making module having an ice-making tray accommodating ice-making water and freezing the ice-making water by refrigerant supplied from a condenser, and inserted into the ice-making tray. An ice making method using an ice maker having an oscillating module having a oscillating plate to oscillate ice water toward a cooling protrusion of the ice maker module, wherein the ice-making water around the cooling protrusion is cooled and the oscillating plate is oscillated and rotated to rotate the cooling protrusion. a transparent ice generating step of freezing transparent ice around the cooling protrusion; and alternately repeating the transparent ice generating step and the translucent ice generating step.

Here, the transparent ice generating step is characterized in that the temperature of the ice-making water of the ice-making module is measured and the swinging rotation speed of the swinging plate is adjusted according to the measured temperature.

Here, the swinging rotation speed of the swinging plate is controlled to swing and rotate at a low speed when the ice making water is at a high temperature, and to swing and rotate at a high speed when the ice making water is low in temperature.

Here, the transparent ice generating step is characterized in that the temperature of the ice-making water supplied to the ice-making module is adjusted to increase the transparency of the transparent ice.

According to the ice-making method of the present invention having the above-described configuration, since it is possible to sufficiently generate fluctuations in the ice-making water by the swinging rotation of the swinging plate without the need to swing the ice-making tray itself, transparent ice without increasing the size of the ice-making tray. can be easily formed.

In addition, the transparent ice generating step and the translucent ice generating step can be formed according to whether the rocking plate is rocked or rotated, and transparent ice and translucent ice are alternately formed to form a transparent part and a translucent part in one ice. It can be formed in the shape of a tree's ring, so it can provide fun and aesthetically pleasing ice beyond simple transparent ice.

1 is an internal perspective view of an ice maker embodying the present invention.
FIG. 2 is a view showing an ice making module and a rocking module of the ice maker of FIG. 1 .
3 is a view showing an ice-making tray and a swinging plate of the present invention.
4 is a view for explaining the rotation of the ice-making tray and the swinging plate according to the present invention.
5 is a flowchart illustrating a furnace ice ice making method according to the present invention.

Hereinafter, the furnace ice ice making method according to the present invention will be described in detail with reference to the accompanying drawings by way of example.

1 to 6 , the ice maker 1 according to the present invention includes a condenser 3 , a compressor 4 , an ice storage tank 6 , an ice making module 10 , and a rocking module 20 . ) is included.

Inside the case, a compressor 4, a condenser 3, and an evaporator (not shown) are installed above the lower case 2a. The refrigerant becomes a high-temperature and high-pressure vapor state in the compressor 4 and moves to the condenser 3, and becomes a high-pressure liquid state in the condenser 3, and the refrigerant moves to the evaporator along a capillary tube to a low-pressure wet vapor state. and flows into an evaporation tube 12 to be described later. At this time, as the refrigerant evaporates and absorbs heat from its surroundings, cold air is provided around the evaporation tube 12 .

The ice-making module 10 includes an ice-making tray 11 , an evaporation tube 12 , a cooling protrusion 12a , and a tray driving unit 14 .

The ice-making tray 11 has a substantially semicircular cross-section, and ice-making water is supplied from an ice-making water supply source and accommodated in the ice-making tray 10 .

The evaporator 12 and the cooling protrusion 12a are accommodated in the ice-making tray 11 . The evaporation tube 12 is disposed in an approximately U-shape inside the ice-making tray 11 .

The cooling protrusion 12a is formed to protrude downward from the evaporation tube 12 toward the ice-making tray 11 side. The evaporation tube 12 is configured to form a part of a refrigeration cycle of a circulation structure that reaches the evaporation tube through a compressor, a condenser, an expansion valve, and the like. The cooling protrusion 12a is immersed in the ice-making water accommodated in the ice-making tray 11, and the ice-making water around the cooling protrusion is cooled by the evaporation temperature conducted from the evaporator 12 to form ice. . The cooling protrusion 12a is installed in the evaporation tube 12 formed in a U-shape, and is formed in a two-row structure.

The ice-making tray 11 may be rotationally driven by the tray driving unit 14 .

A tray rotation shaft 13 is provided on one side of the ice-making tray 11 on the outside of the ice-making tray body. In this embodiment, the tray rotation shaft 13 is formed in the center of the ice-making tray 11, so that additional space is not required when the ice-making tray 11 is rotated, so that it can be configured compactly.

The tray rotation shaft 13 may be connected to the tray driving unit 14 to rotate the ice-making tray. The ice-making tray 11 may be rotated by the tray driving unit 14 to transfer the clear ice removed from the ice to the ice storage tank.

A rocking module 20 for swinging the ice making water is provided on one side of the ice making module 10 . The swinging module 20 includes a swinging plate 22 , a limit switch 23 , a swinging head 24 , and a swinging plate driving unit 25 .

The swinging plate 22 is inserted into the ice-making tray to swing the ice-making water toward the cooling protrusion of the ice-making module. The swing plate 22 is formed coaxially with the tray rotation shaft 13 of the ice-making tray 11 and is configured to rotate about the rotation shaft of the ice-making tray 11 . The swing plate 22 is disposed between each row of the cooling projections arranged in two rows.

Due to the configuration of the rocking plate 22 , the swinging lever can sufficiently generate rocking in the ice-making water by rotation of the swing lever without the need to rock the ice-making tray itself. Since an additional tray portion is not required, the ice maker can be compactly configured and transparent ice can be easily formed.

The swing plate 22 includes a swing shaft 221 , a swing plate 222 , and a cooling water passage hole 223 . The swing shaft 221 is configured to be connected to the tray rotation shaft 13 .

The swinging plate 222 is formed in a substantially plate shape, and a plurality of cooling water passage holes 223 are formed in the swinging plate 222 . By providing the pass-through hole 223 after cooling, the ice-making water on both sides of the rocking plate can pass through each other, thereby making it easier to rotate the rocking plate.

The swinging plate driving unit 25 is installed in the swinging module fixing part 21 fixed to the inner case 5 . The swinging plate driving unit 25 is connected to the swinging plate 22 via the swinging head 24 .

The swinging plate 22 is rotated left and right inside the ice-making tray 11 by the rotational driving of the swinging plate driving unit 25 to vibrate the ice-making water contained in the ice-making tray 11 to generate transparent ice. do.

Limit switches 23 are installed on the left and right sides of the swing head 24 . The limit switch 23 may sense the degree of rotation of the swinging plate 22 by contact with the swinging head 24 .

As the transparent ice generated by the cooling protrusion gradually increases, the rotation range of the swinging plate gradually decreases, and accordingly, the rotation of the swinging head 23 also decreases. When the rotation of the rocking head is reduced and there is no contact with the limit switch 23, it is determined that the ice making of the transparent ice is complete, and whether the ice making is completed can be easily detected.

The guide plate 7 and the ice storage tank 6 are provided on one side of the ice-making tray 11 .

As shown in FIG. 4 , the guide plate 7 forms a first guide plate 7a in contact with the side end of the ice-making tray when the ice-making tray is rotated, and an inclination angle different from that of the first guide plate 7a. and a second guide plate 7b, and a guide connection part 7c connecting the first guide plate and the second guide plate.

An ice storage tank 6 is provided adjacent to the guide plate 7 . The ice storage tank 6 is accommodated inside the inner case 5 accommodating the ice-making module and the ice storage tank, and the ice storage tank 6 has a transparent transparent ice-making module 10 after ice-making has been completed. Ice is transported and stored.

Meanwhile, an ice-making water supply pipe 30 is connected to the ice-making tray 11 . The ice-making water supply pipe 30 is configured to receive ice-making water from an ice-making water supply source and supply the ice-making water to the ice-making tray.

An ice-making water temperature sensor 31 is installed on one side of the ice-making water supply pipe 30 . By installing the ice-making water temperature sensor 31, the temperature of the ice-making water supplied to the ice-making tray 11 is measured and the temperature of the ice-making water is controlled to an optimal temperature for ice making, thereby improving the efficiency of ice making. .

In addition, a second ice-making water temperature sensor 41 for sensing the temperature of the ice-making water accommodated in the ice-making tray may be further provided. One side of the second ice-making water temperature sensor 41 is connected to the inner case by a support bracket 40 , and the other side is immersed in the ice-making water accommodated in the ice-making tray 11 .

By providing the ice-making water temperature sensor 31 and the second ice-making water temperature sensor 41, the temperature of the ice-making water being made in the ice-making tray is measured and the refrigerant circulating in the evaporation tube and the cooling protrusion. It is possible to improve the efficiency of ice making by controlling the cycle time or the swing rotation speed of the swing plate.

A method for making funny ice using the ice maker of the present invention having the above-described configuration will be described.

In the funny ice making method according to the present invention, a transparent ice part and a semi-transparent ice part are alternately formed on a single piece of ice, and when viewed from a cross-section, it is formed like a tree ring to form an interesting shape of ice.

The method for making funny ice according to the present invention includes a transparent ice generating step of freezing transparent ice around the cooling protrusion. The cooling module is cooled by rotating the rocking plate to freeze transparent ice around the cooling module.

At this time, it is preferable to measure the temperature of the ice-making water of the ice-making module and to adjust the swinging rotation speed of the swinging plate according to the measured temperature.

Preferably, the swinging rotation speed of the swinging plate is adjusted to swing and rotate at a low speed when the ice-making water is at a high temperature, and to swing and rotate at a high speed when the ice-making water is low.

The high-temperature ice-making water is frozen by the refrigerant, but it takes more time than the low-temperature ice-making water. Therefore, even if the swinging rotation of the swinging plate is set at a low speed, sufficient fluctuations are generated in the ice-making water to freeze while generating transparent ice. can be improved

A portion of the ice-making water supply pipe 30 may be disposed to surround the outer circumferential surface of the compressor 4 to receive heat supplied from the compressor to increase the temperature of the ice-making water. For example, ice-making water supplied at a predetermined temperature from an ice-making water supply source increases in temperature as it passes through an ice-making water supply pipe disposed in the compressor and is supplied to the ice-making module. Since it takes more time than low-temperature ice-making water to freeze, it can freeze even when the rocking plate is rotated at a low speed, so that transparency can be improved when generating transparent ice.

After transparent ice is formed to a predetermined thickness around the cooling protrusion, translucent ice is formed on the outer peripheral surface of the transparent ice (S2).

The translucent ice generating step cools the ice-making water around the cooling module without rotating the rocking plate to freeze the translucent ice around the cooling module. In the method of generating transparent ice by the spraying method, it is difficult to produce translucent or opaque ice as described above. However, in the present invention, if the rocking plate is frozen without swinging and rotating, the above-described translucent ice can be easily generated.

Then, there is a step (S3) of alternately repeating the transparent ice generating step and the translucent ice generating step.

As a result, it is possible to obtain ice in which transparent ice parts and semi-transparent ice parts are alternately formed on one piece of ice and, when viewed in cross-section, looks like a tree ring.

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, and it is common in the technical field to which the present invention pertains that various substitutions, modifications and changes are possible without departing from the technical spirit of the present invention. It will be clear to those who have the knowledge of

1: Ice machine
3: condenser
4: Compressor
10: ice making module
11: ice-making tray 12: evaporation tube
14: tray drive unit
20: rocking module
22: rocking plate 23: limit switch
24: rocking head 25: rocking plate driving part
30: ice-making water supply pipe 31: ice-making water temperature sensor

Claims (4)

an ice-making module having an ice-making tray for accommodating ice-making water and freezing the ice-making water by refrigerant supplied from a condenser, and a rocking plate inserted into the ice-making tray to swing the ice-making water toward the cooling protrusion of the ice-making module; An ice making method using an ice maker having a rocking module, the method comprising:
a transparent ice generating step of cooling the ice-making water around the cooling protrusion and rotating the rocking plate to freeze transparent ice around the cooling protrusion;
generating semi-transparent ice by cooling the ice-making water around the cooling protrusion without rotating the rocking plate to freeze the semi-transparent ice around the cooling protrusion;
alternately repeating the transparent ice generating step and the translucent ice generating step;
The method of claim 1, wherein the transparent ice generating step includes measuring the temperature of the ice-making water of the ice-making module and adjusting the swinging rotation speed of the swinging plate according to the measured temperature.
delete The method of claim 1,
The oscillating rotation speed of the oscillating plate is adjusted to oscillate at a low speed when the ice-making water is at a high temperature, and to oscillate and rotate at a high speed when the ice-making water is low.
The method of claim 1,
The method of claim 1, wherein the transparent ice generating step is adjusted to increase the transparency of the transparent ice by increasing the temperature of the ice-making water supplied to the ice-making module.

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