KR102755222B1 - Ice maker of mold type for a chunk of ice - Google Patents

Abstract

The present invention relates to a mold-type ice maker for cubed ice, which is large in volume and filled internally to be hard and does not easily break or melt quickly due to external impact, and which can be mass-produced at a lower cost, and which comprises: a vertical ice-making mold cooled by a refrigerant pipe through which a low-temperature, low-pressure refrigerant flows and having a plurality of ice-making grooves on the left and right sides; a water spray nozzle for spraying water onto the ice-making grooves of the ice-making mold; and ice produced in the ice-making grooves is configured such that the high-temperature, low-pressure refrigerant flows inside the refrigerant pipes so that the ice inside the ice-making grooves is naturally separated from the ice-making grooves; and the ice-making mold has an assembled structure that is separately composed of an ice-making mold body and left and right ice-making plates.

Description

Ice maker of mold type for a chunk of ice

The present invention relates to a mold-type ice maker for cubed ice, and more specifically, to a mold-type ice maker for cubed ice that is large in volume, has a solid interior and is not easily broken or melted by external impact, and can be mass-produced quickly and at a lower cost.

In general, large fishing vessels that fish in the ocean are equipped with refrigeration equipment on the vessel itself, but small fishing vessels that fish in coastal waters are not equipped with refrigeration equipment on the vessel itself. Accordingly, small fishing vessels use ice cubes to store and transport the fish they catch, and ice cubes are also used in fish markets at each port where the fish they catch are sold on consignment to maintain the freshness of the fish. In addition, large-volume ice cubes are needed to maintain the freshness of seafood for a long time when delivering oysters or seafood.

Fig. 7 shows an example of a conventional piece of ice. A typical ice maker for piece of ice has a number of vertical refrigerant pipes installed inside a tank, and when low-temperature, low-pressure refrigerant flows through the refrigerant pipes and water is sprayed into the tank, the sprayed water freezes and sticks to the refrigerant pipes when it comes into contact with them, which have been cooled by the low-temperature, low-pressure refrigerant, thereby creating ice.

In this state, when high temperature and high pressure refrigerant is allowed to flow through the refrigerant pipe, the contact surface of the ice rod on the refrigerant pipe melts, the ice rod is separated from the refrigerant pipe, and the ice rod moves downward along the vertical refrigerant pipe. The cutter cuts the ice rod moving downward at regular intervals and lengths, thereby creating a tube-shaped piece of ice (100).

However, the tubular ice produced in this way cannot increase in volume due to the limited diameter of the refrigerant pipe, and since the inside remains empty, the inside and outside melt simultaneously, causing the entire product to melt quickly. Therefore, there was a problem that the ice would melt and disappear when oysters and seafood were delivered long distances, reducing the freshness of the product. In addition, since the conventional tubular ice maker requires installing a large number of refrigerant pipes in a limited-space tank and separately providing a cutting device to cut the ice bars produced in the refrigerant pipes, the cost of purchasing the ice maker inevitably increases, resulting in an economic burden for the manufacture and purchase of the device, and there was a problem that the production volume per unit price of the device was low, resulting in inefficiency in ice production.

1. Republic of Korea Registered Utility Model No. 20-0280249 (Publicly Announced on June 29, 2002)

Accordingly, the present invention has been created to solve the above-mentioned problems of the related art, and its purpose is to provide a mold-type ice maker for crushed ice that can be mass-produced quickly and at a lower cost by making crushed ice that is large in volume, has a solid interior, and does not break easily or melt quickly due to external impact.

In order to achieve the purpose of the mold-type ice maker for cube ice according to the present invention, one form of the mold-type ice maker for cube ice is provided, wherein a vertical ice-making mold is cooled by a refrigerant pipe through which a low-temperature, low-pressure refrigerant flows and has a plurality of ice-making grooves on the left and right sides, a water spray nozzle for spraying water onto the ice-making grooves of the ice-making mold is provided, and ice produced in the ice-making grooves is configured such that the high-temperature, low-pressure refrigerant flows inside the refrigerant pipes so that the ice inside the ice-making grooves is naturally separated from the ice-making grooves, and the ice-making mold is characterized in that it is configured to have an assembly structure that is separately configured by an ice-making mold body and left and right ice-making plates.

As described above, the present invention enables mass production of large-volume, internally filled, solid ice cubes that do not easily break or melt due to external impact, at a lower cost and more quickly, thereby further increasing the efficiency of production and use, and further increasing economic feasibility by reducing the production cost.

Figures 1 and 2 are front and side views schematically showing the overall configuration of an ice maker for mold-type ice cubes according to the present invention.
Figure 3 is a perspective view showing the configuration of an ice mold of an ice maker for making ice cubes of a mold type according to the present invention.
Figure 4 is a front view showing the separated state of the ice mold of Figure 3.
Fig. 5 is an enlarged cross-sectional view of the ice making mold of Fig. 3.
Figure 6 is a front view showing the state of the ice mold combination of Figure 3.
Figure 7 is a perspective view showing a conventional piece of ice.

Advantages and features of embodiments of the present invention, and methods for achieving them, will become apparent with reference to the embodiments described below in detail together with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, and the present embodiments are provided only to make the disclosure of the present invention complete and to fully inform a person skilled in the art of the scope of the invention, and the present invention is defined only by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

In describing embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. In addition, the terms described below are terms defined in consideration of functions in the embodiments of the present invention, and these may vary depending on the intention or custom of the user or operator. Therefore, the definitions should be made based on the contents throughout this specification.

Hereinafter, a mold type ice maker for crushed ice according to the present invention will be described in detail according to an embodiment with reference to the attached drawings.

FIG. 1 and FIG. 2 are front and side views schematically showing the overall configuration of an ice maker for cubed ice of a mold type according to the present invention, FIG. 3 is a perspective view showing the configuration of an ice mold of an ice maker for cubed ice of a mold type according to the present invention, FIG. 4 is a front view showing the separated state of the ice mold of FIG. 3, FIG. 5 is an enlarged cross-sectional view of the ice mold of FIG. 3, and FIG. 6 is a front view showing the combined state of the ice mold of FIG. 3.

As shown therein, the present invention is provided with a vertical ice-making mold (1) that is cooled by a refrigerant pipe (31) and has a number of ice-making grooves (25) on the left and right sides. This ice-making mold (1) fills the ice-making grooves (25) by freezing water supplied to each ice-making groove (25) through a continuous cooling action in a cooling environment inside an ice-making room (not shown).

To this end, the ice making room is equipped with a water spray nozzle (41) installed inside, and the water spray nozzle (41) receives water from a water tank (43) by a pump (42) and sprays it onto the ice making mold (1). The ice produced in the ice making mold (1) is configured to be naturally separated from the ice making mold (1) as the ice making room changes from a low-temperature cooling environment to a room-temperature heating environment.

The ice making room can be equipped with multiple ice making rooms, and it is possible to manufacture ice alternately by creating a cooling environment in one ice making room to perform ice making and creating a heated environment in the other ice making room after completing ice making to perform ice separation. This alternating operation can contribute to improving efficiency and productivity by shortening the ice making time.

Meanwhile, the ice-making mold (1) is composed of an ice-making mold body (10) and left and right ice-making plates (20a) (20b) that are separated and assembled to form the ice-making mold (1). The ice-making mold body (10) is formed integrally with a plurality of left and right curved wings (14) (15) spaced vertically apart with a vertical middle support (11) as the center, and the left and right curved wings (14) (15) form a symmetrical structure of the same shape. Here, the left and right curved wings (14) (15) form a semi-elliptical cross-section structure, but this is not limited to this, and any cross-section structure in which the upper and lower curved surfaces (14a) (15a) are symmetrical to each other may be used.

In addition, the middle support (11) of the ice mold body (10) is formed with square-shaped pipe cooling holes (12) and pipe penetration holes (13) that are alternately and repeatedly formed along the vertical direction of the middle support (11), and as shown in FIGS. 2 and 5, the refrigerant pipe (31) is installed in a zigzag manner inside the ice mold (1) while passing through the pipe cooling holes (12) of the middle support (11). At this time, the left and right curved wings (14)(15) described above are integrally formed on both sides of the pipe penetration holes (13) of the middle support (11), and an ice plate assembly space (16) is formed between the vertical left and right curved wings (14)(15), and the pipe cooling holes (12) have uneven convex portions (12a) on both inner sides.

The uneven convex portion (12a) enables the pipe cooling hole (12) and the refrigerant pipe (31) to be in close contact with each other without a gap between them and increases the contact area, thereby helping to quickly transfer the cold air emitted from the refrigerant pipe (31) to the ice-making plate assembly space (16) on both sides of the pipe cooling hole (12). The ice-making mold body (10) is provided with a plurality of unit modules as illustrated, and the vertical length can be increased or decreased as needed.

The unit module of the ice mold body (10) has an assembly structure in which the lower curved surfaces (15a) of the left and right curved wings (14)(15) are positioned at the upper part of the ice mold body (10), and the upper curved surfaces (14a) of the left and right curved wings (14)(15) are positioned at the lower part of the ice mold body (10), as shown in FIGS. 2 and 3, and the unit module can be joined and separated by fitting together by the grooved portion (17a) and the protruding portion (17b) that constitute the attachment/detachment portion (17).

The left and right ice-making plates (20a)(20b) have the same shape and are assembled to the ice-making mold body (10) in a symmetrical direction, so the description of the structure of the right ice-making plate (20b) will be omitted and only the structure of the left ice-making plate (20a) will be described in detail. The left ice-making plate (20a) has a plurality of ice-making grooves (25) that are divided horizontally and vertically by vertical bulkheads (21) and upper and lower curved support protrusions (22)(23) and form a square groove shape with a front opening that is blocked at the back.

The upper and lower curved support protrusions (22)(23) are formed in a protruding shape corresponding to the left and right curved wings (14)(15) of the ice mold body (10), and the opposite sides of the upper and lower curved support protrusions (22)(23) have curved wing insertion grooves (24) into which the left and right curved wings (14)(15) are inserted, and the ice grooves (25) between the curved wing insertion grooves (24) have a protruding shape corresponding to the ice plate assembly space (16) of the ice mold body (10), thereby forming an assembly structure inserted into the ice plate assembly space (16).

The present invention, configured as described above, is installed in the ice-making mold (1) so that the refrigerant pipe (31) passes through the pipe cooling hole (12) of the ice-making mold body (10) in a zigzag manner as shown in FIGS. 2 and 5. At this time, the uneven convex portion (12a) of the pipe cooling hole (12) allows the pipe cooling hole (12) and the refrigerant pipe (31) to come into close contact with each other without a gap between them, and as the contact area increases, the cold air of the refrigerant pipe (31) can be quickly transferred to the ice-making grooves (25) of the left and right ice-making plates (20a) (20b) inserted into the ice-making plate assembly space (16) of the ice-making mold body (10).

The inside of the refrigerant pipe (31) is configured with a low-temperature, low-pressure refrigerant flowing according to the principle of the refrigeration cycle, which is composed of a cooling device (30), i.e., a compressor (32), a condenser (33), an evaporator (34), etc. The low-temperature, low-pressure refrigerant takes away the heat of the ice mold (1) and cools it, thereby cooling the refrigerant pipe (31) for the ice mold (1), and water supply to the ice-making grooves (25) of the left and right ice-making plates (20a) (20b) is performed by a water supply device (40), i.e., a pump (42) supplying water from a water tank (43) to a water spray nozzle (41), and the water spray nozzle (41) spraying water to the ice-making grooves (25).

Accordingly, the inside of the ice-making grooves (25) of the left and right ice-making plates (20a) (20b) gradually forms ice by continuous contact with water, filling the inside of the ice-making grooves (25) to form ice cubes, and the ice thus formed is naturally separated and dropped from the ice-making grooves (25) of the left and right ice-making plates (20a) (20b) by allowing high-temperature and high-pressure refrigerant to flow through the inside of the refrigerant pipe (31), so that the ice can be collected.

Meanwhile, the present invention is divided into one in which a low-temperature, low-pressure refrigerant flows through a refrigerant pipe (31) and one in which a high-temperature, high-pressure refrigerant flows through a refrigerant pipe (31), and, as illustrated in FIG. 2, a compressor (33), a condenser (33), an expansion valve (35), and an evaporator (34) are provided to supply a low-temperature, low-pressure refrigerant or a high-temperature, high-pressure refrigerant to the refrigerant pipe (31). In addition, a valve A (V1) is installed on a refrigerant supply path A (37a) between a refrigerant pipe inlet (31a) and an expansion valve (35). In addition, a branch path (36) is formed between a refrigerant supply path B (37b) between the compressor (32) and the condenser (33) and the refrigerant supply path A (37a), and a valve B (V2) is installed on the branch path (36).

Accordingly, when valve A (V1) is opened and valve B (V2) is closed, the low-temperature and low-pressure refrigerant sent from the expansion valve (35) flows inside the refrigerant pipe (31) to cool the ice-making mold (1) of the present invention, thereby making ice. When valve A (V1) is closed and valve B (V2) is opened, the space between the expansion valve (35) and the refrigerant pipe (31) is blocked, thereby stopping the supply of the low-temperature and low-pressure refrigerant to the refrigerant pipe (31), and the high-temperature and high-pressure refrigerant sent from the compressor (32) to the condenser (33) is supplied to the refrigerant pipe (31) through the branch line (36) and the refrigerant supply line A (37a), thereby heating the ice-making mold (1) of the present invention, so that the contact surface of the ice formed in the ice-making mold (1) melts, thereby allowing the ice to be naturally separated and dropped from the ice-making mold (1). (FIG. 2) reference.)

In this way, the present invention can not only increase the efficiency of production and use by quickly and inexpensively mass-producing large-volume, filled-in-the-internal ice cubes that are hard and do not break easily or melt quickly due to external impact, but also increase economic feasibility by reducing the cost of production.

Although the mold type ice maker for cube ice according to the present invention has been specifically described above, this is only a description of the most preferred embodiment of the present invention, and the present invention is not limited thereto, and the scope thereof is determined and limited by the appended claims. In addition, it will be obvious that anyone having ordinary knowledge in this technical field can make various modifications and imitations according to the description of the specification of the present invention, but this also does not go beyond the scope of the present invention.

1: Ice mold
10: Ice mold body
11: Middle support 12: Pipe cooling hole
12a: Convex and concave portion 13: Pipe penetration hole
14,15: Left and right curved wings 14a,15a: Upper and lower curved wings
16: Ice plate assembly space 17: Removable part
17a: Dovetail ridge 17b: Dovetail groove
20a,20b: Left and right ice plates
21: Bulkhead 22,23: Upper and lower curved support brackets
24: Curved wing insertion groove 25: Ice making groove
30: Cooling device
31: Refrigerant pipe 31a, 31b: Refrigerant pipe inlet and outlet
32: Compressor 33: Condenser
34: Evaporator 35: Expansion valve
36: Branch V1, V2: Valve A, B
40: Water supply device
41: Water spray nozzle 42: Pump
43: Water tank

Claims (5)

A vertical ice-making mold (1) is provided, which is cooled by a refrigerant pipe (31) through which low-temperature and low-pressure refrigerant flows and has a number of ice-making grooves (25) on the left and right sides, and a water spray nozzle (41) for spraying water on the ice-making grooves (25) of the ice-making mold (1) is provided, and ice created in the ice-making grooves (25) is configured such that high-temperature and high-pressure refrigerant flows inside the refrigerant pipe (31) so that the ice inside the ice-making grooves (25) is naturally separated from the ice-making grooves (25), and the ice-making mold (1) is configured to have an assembly structure that is separately composed of an ice-making mold body (10) and left and right ice-making plates (20a) (20b),
The above ice mold body (10) is formed integrally with a plurality of left and right curved wings (14)(15) spaced vertically apart around a vertical middle support (11), and an ice plate assembly space (16) is formed between the vertical left and right curved wings (14)(15), and the left and right ice plates (20a)(20b) have upper and lower curved support protrusions (22)(23) that are formed protruding in a shape corresponding to the vertical bulkhead (21) and the left and right curved wings (14)(15) of the ice mold body (10), and are assembled in a structure that fits into the ice plate assembly space (16) of the ice mold body (10).
The above ice mold body (10) is provided with a plurality of unit modules so that the length can be increased or decreased in the vertical direction as needed, and the unit modules of the ice mold body (10) are characterized by an assembly structure in which the lower curved surfaces (15a) of the left and right curved wings (14)(15) are positioned at the upper part of the ice mold body (10), and the upper curved surfaces (14a) of the left and right curved wings (14)(15) are positioned at the lower part of the ice mold body (10), and the mold type ice maker for piece ice is combined and separated by fitting them together by means of a detachable part (17).
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