KR102032824B1 - ice making apparatus and method - Google Patents

Abstract

The present invention relates to an ice piece making apparatus and a method, wherein an ice piece generated in an ice making machine is unfolded in a single layer to be transferred to a transfer conveyor, and moisture of an ice piece surface is re-frozen through a freezer to prevent mutual condensation of the ice piece. Moreover, each unit of the ice piece is discharged and accommodated for a following process such as packaging and processing to be easily performed. A specific height of the accommodated ice piece is detected to effectively use energy by controlling a moving speed of the transfer conveyor and a temperature of the freezer.

Description

Ice making apparatus and method

The present invention relates to an apparatus and method for producing crushed ice, and more particularly, to spread crushed ice in a single layer, and to pass the freezer with a conveying conveyor to re-freeze and remove moisture from the crushed ice surface, and to separate the crushed ice into pieces. The present invention relates to an apparatus and method for producing crushed ice, which discharges and stores it in an ice receiving unit, and controls the moving speed of the conveying conveyor and the temperature of the freezer according to a specific height of the crushed ice contained therein.

In general, ice is provided in the form of crushed ice so as to ingest beverages such as summer juice or coffee in the summer, or foods such as cold noodles or greens, and is used to maintain cold temperatures for a long time.

To provide crushed ice, large ice is crushed with a grinder or made with an ice maker that produces crushed ice. During this process, moisture is present on the surface of the ice, which is immediately packaged, transported into a freezer, frozen and supplied to consumers.

The prior art (Korean Patent No. 10-1488112) discloses an ice making machine in which ice making and freezing storage are dualized, and efficiently maintains ice by supplying cold air to ice making and freezing, respectively. However, the prior art has a problem that the ice produced in the ice maker is directly put into the reservoir, where the pieces of ice stick together as the water freezes on the surface of the ice.

Korean Registered Patent (No. 10-1488112)

An object of the present invention is to solve the conventional problems, by spreading the crushed ice produced by the ice maker in a single layer and transported to the transfer conveyor to pass through the inside of the freezer to re-freeze the moisture on the surface of the flake ice to prevent mutual aggregation, The present invention provides an apparatus and method for producing crushed ice that efficiently utilizes energy by controlling a moving conveyor speed and a temperature of a freezer according to a specific height of crushed ice.

According to a preferred embodiment for achieving the object of the present invention described above, the present invention provides an ice maker for producing flake ice, a conveying conveyor provided at the lower part of the ice maker to convey the flake ice generated in the ice maker, and the transfer A part of the conveyor passes through the inside of the freezer to re-freeze the flake ice, disposed at the end of the conveying conveyor passing through the freezer, the ice discharge portion for discharging the crushed ice, and located in the lower portion of the ice discharge portion And a controller configured to control a moving speed of the transfer conveyor and a temperature of the freezer according to the height of the ice receiving portion accommodated in the discharged pieced ice and the piece of ice received in the ice receiving portion. And an ice spreading film spreading the piece of ice in a single layer, wherein the freezer is provided in the freezer. An upper freezing fan disposed at an upper part of the inside and a lower freezing fan disposed at a lower part of the inside of the freezer, and a lower freezing fan disposed at a lower part of the conveying conveyor, wherein the ice discharge part is narrowed from an upper end to a lower end; Located in the lower portion of the inlet, and includes an outlet having a spiral passage therein, wherein the ice receiving portion is located in the reservoir and the lower portion of the reservoir containing the crushed ice to the predetermined height away from the ice discharge portion and the valve is It is installed to include a valve discharge unit for discharging the crushed ice by a predetermined amount, the upper one side of the storage provides a flake ice generating device including a sensor for detecting a specific height of the crushed ice.

According to another embodiment of the present invention, the present invention is an ice spreading step of spreading the crushed ice supplied from the ice maker in a single layer, and a re-freezing step of transferring the crushed ice spread in the single layer to a conveying conveyor and re-freezing through a freezer; And a single discharge step of discharging the re-frozen piece of ice to the ice discharge unit individually, and a height sensing step of receiving the discharged pieced ice into the ice receiving unit and detecting a specific height of the piece of ice received by the sensor; A transfer control step of controlling the transfer conveyor by the control unit according to the detection of the detection sensor, a temperature sensing step of detecting a temperature change of the temperature sensor of the freezer, and the control unit of the freezer according to the operation of the temperature sensor It provides a method of producing ice cubes comprising a temperature control step of controlling.

In addition, the piece ice generating method, if the detection sensor does not detect a specific height of the piece ice in the height detection step, the temperature rise detection step of detecting a temperature rise of the temperature sensor of the freezer, and the control unit A cold air increasing step of accelerating the upper freezing fan and the lower freezing fan and the speed reduction step of the control unit slows down the conveying speed of the conveying conveyor, if the temperature rise is not detected in the temperature rise detection step, A temperature drop detection step of detecting a temperature drop by a temperature sensor, a cold air reduction step of decelerating the upper refrigeration fan and a lower refrigeration fan, and a speed increase step of accelerating the transfer speed of the transfer conveyor by the control part; can do.

The flake ice generating device according to the present invention can prevent flake ice from agglomeration by removing flake ice generated in an ice maker by transferring it to a conveying conveyor in a single layer unfolded and supplying cold air to freeze and remove moisture on the flake ice surface. .

In addition, the flake ice generating device according to the present invention can easily discharge the flake ice removed by freezing the moisture on the surface to facilitate the subsequent process such as packaging and processing.

In addition, the crushed ice generating device according to the present invention can uniformly and effectively supply cold air to crushed ice in the upper and lower freezing fan and the lower freezing fan inside the freezer.

In addition, the flake ice generating device according to the present invention, the control unit controls the moving speed of the conveying conveyor and the temperature of the freezer according to the specific height of the crushed ice accommodated in the ice receiving unit, or the moving speed of the conveying conveyor according to the temperature change of the freezer By controlling the temperature, energy can be efficiently used by providing optimum cooling for removing the flake ice surface moisture.

1 is a view schematically showing an apparatus for producing crushed ice according to the present invention.
FIG. 2 is an enlarged view of the region A shown in FIG. 1.
3 is an enlarged view of the region B shown in FIG. 1.
4 is an enlarged view of the ice receiving portion shown in FIG.
5 is a view showing a method of generating crushed ice according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of a flake ice generating device according to the present invention. At this time, the present invention is not limited or limited by the embodiment. In addition, in describing the present invention, a detailed description of known functions or configurations may be omitted to clarify the gist of the present invention.

1 is a view schematically showing the crushed ice generating device according to the present invention, FIG. 2 is an enlarged view of the region A shown in FIG. 1, FIG. 3 is an enlarged view of the region B shown in FIG. 4 is an enlarged view of the ice accommodating part illustrated in FIG. 1, and FIG. 5 is a view illustrating a method of generating crushed ice according to another exemplary embodiment of the present invention.

Referring to FIG. 1, the flake ice generating device 10 according to an embodiment of the present invention includes an ice maker 100, a conveying conveyor 200, a freezer 300, an ice discharge unit 400, and an ice receiving unit 500. ) And the control unit 600.

Here, the conveying conveyor 200 includes an ice spreading film 240, the freezer 300 includes an upper freezing fan 310 and a lower freezing fan 320, the ice discharge unit 400 is an inlet 410 and an outlet 420 disposed below the inlet 410, and the ice receiving unit 500 includes a storage unit 510 and a valve discharge unit 520 positioned below the storage unit 510. ), And may include a sensor 530 that detects the height of the piece of ice on the upper side of the storage unit 510.

The ice maker 100 generates the crushed ice by receiving bottled water. The ice maker 100 may be a conventional ice maker. The ice breaker extends from the bottom or the side of the ice maker 100 to one end of one side of the transport conveyor 200. The prevention film 110 may be included.

Here, the ice escape prevention film 110 to prevent the separation of the flake ice generated in the ice maker 100 in the shape of a hollow square pillar, a circular column or a polyhedron, accommodates a portion of the conveying conveyor 200 The conveying conveyor 200 prevents the inflow of external foreign substances during the transfer from the ice maker 100 to the freezer 300, and prevents the debris of the ice fragments and debris generated during the crushed ice production process and clean working environment. Can be maintained.

The conveying conveyor 200 is to receive and convey the crushed ice produced by extending a predetermined length at the bottom of the ice maker 100, may be a conventional conveyor, the conveying conveyor 200 is a conveyor belt 210 ), A support 220, a conveyor guide 230, and an ice spreading film 240, some of which pass through the inside of the freezer 300 to freeze and transport moisture on the flake ice surface.

Here, the conveyor belt 210 may receive the ice generated by the ice maker 100 and transfer the ice to the freezer 300. In addition, the conveyor belt 210 is provided as a mesh material may pass through the cold air to freeze the moisture of the ice surface, and minimize the contact area of the crushed ice and the conveyor belt 210 to minimize the moisture of the crushed ice surface Re-freezing can be prevented from sticking, and the freezing efficiency can be improved by enlarging the contact area between the flake ice surface and the cold air.

In addition, the supporter 220 supports the conveyor belt 210 and the outside of the freezer 300 so that the conveyor belt 210 can move the crushed ice from one side of the freezer 300 to the other side. It may be arranged in plural on one side, the other inside and the other.

In addition, the conveyor guide 230 is provided on the support 220 to be located at a predetermined height at both ends in the width direction along the conveying direction of the conveyor belt 210 can prevent the separation of the piece of ice during conveying. have.

In addition, the ice spreading film 240 may be provided in the conveyor guide 230 in a direction perpendicular to the conveying direction to unfold the crushed ice generated in the ice maker and transfer the ice to the freezer 300.

Here, referring to FIG. 2, the ice spreading film 240 may include an aggregated ice spreading film 241 and a single layer ice spreading film 242. The packed ice spreading film 241 is located close to the ice maker 100 to spread the crushed pieces of ice. It is provided with a single layer of the ice passing through the aggregated ice spreading film 241 to the conveyor belt 210 and transported to the freezer 300 to prevent mutual agglomeration of each piece of ice, cold air between the pieces of ice Can pass between the can improve the refrigeration efficiency.

The freezer 300 is to supply the cold air to the upper freezing fan 310 and the lower freezing fan 320 provided up and down to freeze, may be a conventional freezer, the freezer 300 is the upper In addition to the freezing fan 310 and the lower freezing fan 320 may include a transport conveyor hole 330, a temperature sensor 340, the door 350.

Here, the upper freezing fan 310 is provided in plurality in the upper portion of the freezer 300 to supply the cold air from the upper, the lower freezing fan 320 is the conveying conveyor passing through the freezer (300) ( 200) It is located in a plurality of lower portion to supply the cold air from the bottom, by supplying the cold air from the top and bottom to increase the amount of cold air supplied to the flake ice surface can shorten the re-freezing time to improve the freezing efficiency.

In addition, the conveying conveyor hole 330 is provided in a pair to the height of the conveying conveyor 200 on one side and the other side of the freezer 300, the conveying conveyor 200 passes through the freezer 300. The crushed ice from the ice maker 100 located outside one side of the freezer 300 through the freezer 300 to the ice discharge unit 400 located outside the other side of the freezer 300 Can be frozen and transported.

2 and 3, the transport conveyor hole 330 may further include a cold air blocking curtain 331. The cold air blocking curtain 331 is to prevent the cool air inside the freezer 300 to flow out, it may be a curtain of a normal transparent material, provided in one pair and the other side of the freezer 300 in pairs It can keep the freezing effect as much as possible by minimizing the outflow of cold air.

In addition, the temperature sensor 340 is located inside the freezer 300 to detect a temperature change of the freezer 300, may be a conventional temperature sensor, if outside the temperature range set by the user A temperature change may be sensed, and the control unit 600 controls the upper freezing fan 310 and the lower freezing fan 320 of the freezer 300 according to the sensing operation of the temperature sensor 340. The temperature of 300 can be maintained in a set range, which will be described later.

In addition, the door 350 is provided on the side of the freezer, the operator can enter and exit the inside of the freezer 300 to facilitate management and cleaning.

Referring to FIG. 3, the ice discharge unit 400 is disposed at an end of the transfer conveyor 200 that has passed through the freezer 300, and the transfer conveyor 200 transfers through the freezer 300. Collecting the re-frozen piece of ice to collect the individual pieces, it may include the inlet 410 and the outlet 420.

Here, the inlet 410 is separated from the conveyor belt 210 at the end of the conveying conveyor 200 by passing through the freezer 300, the crushed ice re-frozen in a funnel shape narrowing from the top to the bottom And scattered and collected falling to the lower end of the inlet 410, the outlet 420 is located in the lower portion of the inlet 410, provided with a spiral passage therein the pieces of ice collected from the lower end of the inlet 410 Can be discharged individually through a spiral passageway.

In addition, referring to Figure 3, the ice discharge unit 400 may further include a discharge ice escape prevention film 430.

The discharge ice escape prevention film 430 is in the shape of a hollow rectangular column, a circular column or a polyhedron, and is fixed from an upper portion of the transfer conveyor hole 330 provided at the other side of the freezer 300 to an upper portion of the inlet 410. It is installed to extend the height of the crushed ice passing through the freezer 300 is separated from the conveyor belt 210 and prevents the inflow of foreign substances while being discharged, the ice fragments and debris generated during the crushed ice separation process It can prevent the departure and keep the working environment clean.

Referring to FIG. 4, the ice accommodating part 500 is positioned below the ice discharge part 400 and accommodates the piece of ice that is individually discharged, and the storage part 510 and the valve discharge port 520. And a sensor 530.

Here, the storage unit 510 is located at the lower end of the discharge port 420 of the ice discharge unit 400 to accommodate a predetermined amount of the pieces of ice falling individually, it may be a variety of hollow open shape of the top, The upper side of the storage unit 510 may include the detection sensor 530.

In addition, the valve outlet 520 is located in the lower portion of the storage unit 510 and discharges the flake ice contained in the storage unit 510, the valve 521 is provided in the passage for discharging the flake ice. The crushed ice may be discharged for subsequent processing.

In addition, the detection sensor 530 is located on one side of the upper portion of the storage unit 510 to detect when the crushed ice is accommodated to a specific height, may be a conventional infrared sensor, a pair of the upper one and the other side It may be provided or individually provided, the control unit 600 controls the crushed ice generating device 10 in accordance with the operation of the sensor 530 to maintain the crushed ice does not overflow the storage unit 510. This may be described later.

The control unit 600 controls the moving speed of the transfer conveyor 200 and the temperature of the freezer 300 according to a specific height of the crushed ice accommodated in the ice receiving unit 500, the transfer conveyor ( It is possible to control the moving speed of the 200 and the rotational speed of the upper freezing fan 310 and the lower freezing fan 320 of the freezer 300, respectively, to efficiently use the energy of the flake ice generating device 10 Can be.

Here, when the crushed ice is accommodated up to the height of the sensor 530 in the storage unit 510 of the ice accommodating unit 500 and the detection sensor 530 detects this, the control unit 600 By recognizing the operation of the sensor 530 can control the moving speed of the conveying conveyor 200, it is possible to accommodate the crushed ice in the storage unit 510 not to overflow.

In addition, when the temperature sensor 340 of the freezer 300 detects a temperature change out of a set temperature range due to the movement speed control of the transfer conveyor 200, the controller 600 controls the temperature sensor 340. Recognizing the operation of the) can control the temperature by controlling the amount of cold air supplied by controlling the rotational speed of the upper freezing fan 310 and the lower freezing fan 320 of the freezer 300, the freezer ( By calculating the moving speed of the transfer conveyor 200 that can freeze the moisture of the crushed ice surface compared to the temperature of 300) it is possible to efficiently use energy without loss of cold air.

Referring to Figure 5, the method of producing crushed ice according to the present invention, ice spreading step (S100), re-freezing step (S200), single discharge step (S300), height sensing step (S400), feed control step (S410) It may include a temperature sensing step (S420) and a temperature control step (S430).

The ice spreading step (S100) may be generated by the ice maker 100 and the piece of ice supplied to the conveyor belt 210 may be unfolded in a single layer by the ice spreading film 240.

In the re-freezing step (S200), the conveying conveyor 200 passes the freezer 300 through the piece ice spread in a single layer and the upper freezing fan 310 and the lower freezing fan 320 inside the freezer 300. ) Can be re-frozen by supplying cold air to the surface of the crushed ice up and down

The piece discharge step (S300) is the crushed ice re-frozen through the freezer 300 is separated from the conveyor belt 210 falls to the ice discharge unit 400 located at the end of the conveying conveyor (200) In addition, the pieces of ice may be collected into the discharge port 420 having a spiral passage therein by collecting the pieces of ice falling into the inlet 410 of the ice discharge unit 400.

The height sensing step (S400) is the ice receiving unit 500 receives the piece of ice discharged individually from the ice discharge unit 400 in the storage unit 510, the upper side of the storage unit 510 It may detect a specific height of the piece of ice received by the sensor 530 located.

The transfer control step (S410) is the control unit 600 recognizes the operation of the detection sensor 530 when the crushed ice is accommodated to the height of the detection sensor 530 of the storage unit 510 By controlling the moving speed of the transfer conveyor 200 can be accommodated in the storage unit 510 so as not to overflow the crushed ice.

The temperature sensing step (S420) is the temperature sensor 340 is detected when the control unit 600 controls the transfer speed of the conveyer 200, the temperature change of the freezer 300 occurs outside the set temperature range can do.

In the temperature control step (S430), when the temperature sensor 340 detects a temperature change of the freezer 300, the controller 600 recognizes the change and the upper freezing fan 310 and the lower part of the freezer 300. The freezer 300 may be maintained within a set temperature range by controlling the amount of cold air supplied by controlling the freezing fan 320.

In another embodiment, the crushed ice accommodated in the storage unit 510 in the height sensing step (S400) is discharged to a certain amount to the valve outlet 520 for subsequent processing to accommodate the height of the sensor 530 If it is not detected by the sensor 530, it may further include a temperature increase detection step (S500), cold air increase step (S510), speed reduction step (S520).

The temperature rise detection step (S500) is the temperature sensor 340 detects the temperature rise of the freezer 300, the control unit 600 recognizes this, the upper freezing fan 310 of the freezer 300 And the cold air increasing step S510 for increasing the rotational speed of the lower freezing fan 320 and the speed decreasing step S520 for reducing the moving speed of the conveying conveyor to set the freezer 300 in a set temperature range. Can be maintained.

In another embodiment, if the temperature sensor 340 does not detect the temperature rise in the temperature rise detection step (S500), temperature drop detection step (S600), cold air reduction step (S610), speed increase step (S620) It may further include.

The temperature drop detection step (S600) is the temperature sensor 340 detects the temperature drop of the freezer 300, the control unit 600 recognizes this, the upper freezing fan 310 of the freezer 300 And the speed increase step (S620) of accelerating the movement speed of the cold air reduction step (S610) and the conveying conveyor 200 to reduce the rotational speed of the lower freezing fan 320 to the freezer (300). Can be maintained within the set temperature range.

As described above, according to the crushed ice generating device 10 and the crushed ice generating method according to the present invention, the crushed ice generated by the ice maker 100 is supplied to the transfer conveyor 200 and unfolded in a single layer to freeze the refrigerator ( By passing through 300 to freeze and remove the moisture on the surface of the crushed ice to prevent mutual aggregation of the crushed ice, the piece of ice passed through the freezer 300 is discharged individually to the ice discharge unit 400 And by receiving and discharging a certain amount in the ice receiving portion 500 can supply the crushed ice separated in the subsequent process without mutual agglomeration, the control unit 600 of the crushed ice accommodated in the ice receiving unit 500 It is possible to control the moving speed of the transfer conveyor 200 and the temperature of the freezer 300 according to a specific height to efficiently use energy without losing cold air. .

As described above, preferred embodiments of the present invention have been described with reference to the drawings. However, those skilled in the art should understand the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. Can be modified or changed in various ways.

10: Flake Ice Generating Device
100: ice maker 110: ice escape prevention film
200: conveying conveyor 210: conveyor belt 220: support 230: conveyor guide
240: ice film 241: ice cube film 242: single layer ice film
300: freezer 310: upper freezing fan 320: lower freezing fan
330: transfer conveyor hole 331: cold air cut curtain 340: temperature sensor 350: door
400: ice discharger 410: inlet 420: outlet 430: discharge ice escape prevention film
500: ice receiving unit 510: storage unit 520: valve discharge unit 530: detection sensor
600: control unit
S100: Ice spreading step S200: Re-freezing step S300: Single discharge step
S400: height detection step S410: feed control step S420: temperature detection step
S430: temperature control step
S500: Temperature increase detection step S510: Cold increase step S520: Speed decrease step
S600: temperature drop detection step S610: cold air reduction step S620: speed increase step

Claims (3)

Ice makers to produce flake ice;
A conveying conveyor provided under the ice maker to convey the crushed ice produced by the ice maker;
A freezer for recooling the crushed ice through a portion of the conveying conveyor;
An ice discharge part disposed at an end of the transfer conveyor passing through the freezer and discharging the crushed ice;
An ice accommodating part disposed under the ice discharge part and accommodating the discharged piece ice; And
A control unit for controlling the moving speed of the transfer conveyor and the temperature of the freezer according to the height of the piece of ice accommodated in the ice receiving portion,
The ice maker,
It includes an ice escape prevention film is accommodated in a portion of the conveying conveyor in the shape of a hollow polyhedron extending from the bottom or side of the ice maker to one end of the freezer,
The conveying conveyor includes an ice spreading film spreading the piece of ice in a single layer,
The ice spread film,
A packed ice spreading film formed in a plate shape at a predetermined height in a direction perpendicular to the conveying direction of the conveying conveyor; And
It is formed parallel to the packed ice spreading film, provided with a predetermined height lower than the packed ice spreading film is formed single layer ice spreading film; includes,
The freezer includes an upper freezing fan disposed above the inside of the freezer and a lower freezing fan disposed below the inside of the freezer and disposed below the transfer conveyor.
The ice discharge part is located in the lower portion of the inlet and the inlet of the shape narrowed toward the lower end from the top, and includes an outlet having a spiral passage therein,
The ice accommodating part includes a storage part in which the flake ice is separated from the ice discharge part, and is located below the storage part and a valve discharge part which is installed at a lower portion of the storage part and discharges the flake ice by a predetermined amount. Sculpture ice generating device, characterized in that on the upper side comprises a sensor for detecting a specific height of the crushed ice. delete delete

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