KR102317462B1 - Ice manufacturing device - Google Patents

Abstract

An object of the present invention is to provide an apparatus for making ice, which includes a support frame (10); a freezing drum 20 mounted on the support frame 10 and having a plurality of freezing cups 26 therein; a cooling pipe 40 built into the freezing drum 20; and a water sleeve (30) for supplying water so that ice is generated inside the freezing cup (26) of the freezing drum (20) by the cold air of the cooling tube (40), and the freezing drum (20) ), a cover 24 coupled to the support frame 10 and having an ice discharge hole communicating with the inner and outer surfaces; and a rotation drum 22 coupled to the inside of the cover 24 and provided with the plurality of freezing cups 26, and an open portion is provided at an outer end of the freezing cup 26, The opening portion of 26) is disposed at a position facing the inner circumferential surface of the cover 24, and the water sleeve 30 allows water to enter the inside of the freezing cup 26 through the opening portion of the freezing cup 26. It is supplied to be filled so that ice is made inside the freezing cup 26 by the cooling tube 40 .

Description

Ice manufacturing device

The present invention relates to an ice-making apparatus, and more particularly, it is possible to make ice smoothly using a compact-sized freezing drum, to allow the produced ice to fall freely, and to automatically clean a main part that makes ice. It relates to an ice making device of a new configuration that can be

In general, an ice-making apparatus (ice-making apparatus) manufactures ice by transferring a refrigerant to an ice-making tube by the pressure of a compressor and performing heat exchange through a condenser.

A conventional ice making apparatus includes an ice-making plate in which a plurality of ice-making grooves are arranged in a grid shape to be installed in a stationary manner, and a refrigerant pipe disposed behind the ice-making plate, and two holes are formed in the plurality of ice-making grooves. there is one thing

The ice-making plate has a rectangular frame, and the ice-making plate has a plurality of ice-making grooves arranged in a top, bottom, left, and right lattice shape. The fact that the ice maker is installed stationary means that it is upright, and the ice maker is both upright and slightly tilted forward at the same time. The ice-making plate was fixed in one place and stood up with a slight inclination to one side.

According to the ice-making apparatus, when water is injected toward the front of the ice-making plate, the ice-making plate is cooled by the cooling tube, so that water is frozen in the inside of each ice-making groove of the ice-making plate to form ice.

When ice is formed in each ice-making groove of the ice-making plate, hot gas is injected from the front of the ice-making plate to melt the ice. However, as it melts slightly, the ice falls out of each ice-making groove by its own weight. At this time, since the water slightly melted in the ice holds the ice inside the ice making groove by capillary action, it is difficult to remove the ice from the ice making groove of the ice making plate. Thus, two holes are drilled in each ice-making groove of the ice-making plate, and air enters the ice-making groove through the hole in each ice-making groove, so that ice can fall out of each ice-making groove. There is a small hole in the ice making groove so that the ice can be easily removed from the ice making groove.

However, in the case of the ice-making apparatus, water is shot from the front of the ice-making plate to form ice inside each ice-making groove, and the water injected to make ice wets the refrigerant pipe, and the ice-making apparatus is turned on countless times. As it is used a lot, scale and mold may form on the refrigerant pipe, and foreign substances such as scale and mold are difficult for ordinary people to clean and cause hygiene problems. That is, water flows into the refrigerant pipe and is contaminated with scale or mold, which causes many hygiene problems, and it is not easy to clean the scale or mold.

In addition, in order to clean the scale or mold, the ice manufacturing apparatus itself must be disassembled. However, there is a problem in maintenance due to the disassembly and reassembly of the ice manufacturing apparatus after cleaning.

Korean Patent Registration No. 10-1449900 (Registered on October 02, 2014) Korean Patent Registration No. 10-1502287 (registered on March 06, 2015)

It is an object of the present invention to smoothly make ice using a compact-sized freezing drum, to allow the ice to fall freely, to automatically clean the freezing drum, which is a main part of making ice, and to An object of the present invention is to provide an ice manufacturing apparatus of a new configuration that is advantageous in terms of hygiene by preventing contamination by harmful substances such as mold.

According to the present invention for solving the above problems, a support frame; a freezing drum mounted on the support frame and having a plurality of freezing cups therein; a cooling tube built into the freezing drum; and a water sleeve for supplying water so that ice is generated inside the freezing cup of the freezing drum by the cool air of the cooling tube.

The freezing drum may include a cover coupled to the support frame and having an ice discharge hole communicating with the inner and outer surfaces; and a rotation drum coupled to the inside of the cover and provided with the plurality of freezing cups, wherein an open portion is provided at an outer end of the freezing cup, and the open portion of the freezing cup faces the inner circumferential surface of the cover. is disposed, and the water sleeve is characterized in that the water is supplied to fill the inside of the freezing cup through the opening of the freezing cup.

The opening portions of the plurality of freezing cups provided in the freezing drum are disposed to face the inner circumferential surface of the cover, and the water sleeve includes a main supply sleeve extending along the outer circumferential surface of the cover, and in the main supply sleeve. It is characterized in that it is branched and configured to include a branch supply sleeve communicating with the inside of the freezing cup.

The cover is configured in a circular loop shape and coupled to the support frame, and the freezing drum is configured such that the plurality of freezing cups are arranged at regular intervals along the circumferential direction and is rotatably coupled to the support frame. .

The freezing drum is characterized in that the plurality of freezing cups are configured to be arranged in two rows.

The support frame, the support tray portion; and a pair of drum mounting panels coupled to the support tray and arranged to face each other, and shafts are provided on both sides of the freezing drum, and the shafts are the pair of drum mounting panels via a bearing. characterized in that it is coupled to

The support tray portion is configured in a cross-sectional channel box shape with an open top, and is provided at the upper end of the support tray portion and includes a pair of panel connection bars arranged in parallel with each other, and the pair of panel connection bars is attached to the pair of panel connection bars. It is characterized in that the drum mounting panel of the connected.

The panel connecting bar is configured in a cross-sectional channel bar shape.

A motor is mounted on any one of the drum mounting panels among the pair of drum mounting panels, a gear is coupled to the motor shaft of the motor, and a driven gear meshed with the driving gear is provided on one side of the freezing drum. characterized in that

The motor is provided with a reducer, and the driving gear is connected to the motor shaft connected to the reducer.

The support frame is characterized in that the discharge guider is provided so as to be disposed under the freezing drum.

The freezing drum may include a cover coupled to the support frame and having an ice discharge hole communicating with the inner and outer surfaces; and a rotation drum coupled to the inside of the cover and provided with the plurality of freezing cups, and a steam nozzle disposed under the discharge hole.

According to the present invention, a support frame; a freezing drum mounted on the support frame and having a plurality of freezing cups therein; a cooling tube built into the freezing drum; and a water sleeve for supplying water so that ice is generated inside the freezing cup of the freezing drum by the cold air of the cooling tube, wherein the freezing drum is coupled to the support frame and communicates with the inner and outer surfaces of the ice a cover having a discharge hole; and a rotation drum coupled to the inside of the cover and provided with the plurality of freezing cups, wherein an open portion is provided at an outer end of the freezing cup, and the open portion of the freezing cup faces the inner circumferential surface of the cover. is disposed, the water sleeve supplies water to be filled into the inside of the freezing cup through the opening of the freezing cup, the rotation drum is configured such that the plurality of freezing cups are arranged in two rows, and the cooling tube comprises: An ice manufacturing apparatus is provided, wherein a surface in contact with the freezing cup is configured as a flat surface.

The cooling tube is configured to include a plurality of contact cooling tube portions, an inlet tube portion and an exhaust tube portion, and the flat surface is provided on the contact cooling tube portion, so that the flat surface of the contact cooling tube portion is in contact with the freezing cup characterized.

The contact cooling tube portion comprises a side contact cooling tube portion having a flat surface in contact with the side of the freezing cup, and an inner side contact cooling tube portion having a flat surface in contact with an inner end of the freezing cup.

The side contact cooling pipe part and the inner side contact cooling pipe part are provided in plurality.

According to the present invention, a support frame; a freezing drum mounted on the support frame and having a plurality of freezing cups therein; a cooling tube built into the freezing drum; a water sleeve for supplying water so that ice is generated inside the freezing cup of the freezing drum by the cold air of the cooling tube, a gear is provided on a side surface of the freezing drum, and the support frame is equipped with a motor is mounted with a driving gear rotating through There is provided an ice making apparatus, characterized in that it is provided.

The idle gear is provided in plurality, and any one idle gear among the plurality of idle gears is disposed at a diagonal position facing the driving gear with respect to the center of the rotation drum.

The ice manufacturing apparatus according to the present invention cools the rotation drum, which is a main part of the freezing drum, by heat exchange with vaporized gas entering the cooling tube, and also cools the plurality of freezing cups inside the rotation drum by rotating the rotation drum. When water is supplied to each freezing cup, ice is formed inside the freezing cup. After the rotation drum rotates and ice is made in the plurality of freezing cups, the lower ice discharge hole of the cover, which is a component of the freezing drum, is closed. Since the ice can be freely dropped through it, it is easy and quick to make ice, and there is a convenient and quick effect in collecting ice.

In addition, in the present invention, by supplying steam to the inside of the freezing drum in a state in which the rotation drum is rotated in the freezing drum, it is possible to automatically clean the freezing drum by steam. The rotating drum, freezing cup and cover, which are the main parts of the freezing drum, can be automatically cleaned. As this automatic cleaning of the freezing drum is possible, it is very convenient for maintenance such as cleaning compared to the conventional one.

In addition, since it prevents contamination by harmful substances such as scale or mold, there is an advantageous effect in hygiene.

1 is a right side perspective view of an ice making apparatus according to the present invention;
Figure 2 is a left side perspective view of Figure 1;
3 is a perspective view showing the structure of the gear, the motor, and the driving gear of the freezing drum, which is the main part of the present invention;
4 and 5 are perspective views showing the cooling tube and the freezing cup inside the rotation drum, which are the main parts of the present invention.
6 is a perspective view showing the structures of the cooling tube and the rotating drum shown in FIGS. 4 and 5, and the freezing cup and water sleeve;
7 and 9 are perspective views of the cooling tube shown in FIG.
9 is a side view of the ice making apparatus according to the present invention;
Figure 10 is a plan view of Figure 9
11 is a side view of an ice making apparatus according to another embodiment of the present invention;
12 is a perspective view of a snowflake ice-water manufacturing apparatus used in combination with the ice-making apparatus of the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by referring to the accompanying drawings and the following detailed description. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the component from other components, and the essence, order, or order of the component is not limited by the term. For example, when a component is described as being "connected", "coupled" or "connected" to another component, the component may be directly connected or connected to the other component, but between each component. It will be understood that another component may be “connected,” “coupled,” or “connected.”

Referring to the drawings, in the ice making apparatus of the present invention, a freezing drum 20 is mounted on a support frame 10 , and a plurality of freezing cups 26 are provided inside the freezing drum 20 , and the free A cooling tube 40 is built in the jingle drum 20 and includes a water sleeve 30 for supplying water to the inside of the freezing cup 26 inside the freezing drum 20 to form ice. do.

The support frame 10 includes a support tray 12 and a pair of drum mounting panels 14 .

The support tray part 12 includes a support bottom piece and a pair of support side wall parts extending upward from both sides of the support bottom piece and arranged in parallel with each other. Accordingly, the support tray part 12 is configured in a cross-sectional channel shape with an open top. At this time, a support jaw portion is provided on the upper portion of the pair of support side wall portions.

A panel connecting bar 16 is coupled to the pair of support sidewalls. The panel connecting bar 16 has a cross-sectional channel bar shape having an upper support piece and a lower support piece at upper and lower ends of the side support piece. The lower support piece of the panel connecting bar 16 may be connected to the support jaw portion of the support side wall portion by a bonding means such as welding in a state in which it rests on the support jaw portion provided on the upper portion of the support side wall portion. It is configured such that the panel connecting bar 16 is fixed to the supporting jaw of the support side wall in a state where the supporting jaw of the support side wall part supports the panel connecting bar 16 from below. A panel connecting bar 16 is coupled to each of the pair of support sidewalls of the support tray 12 . A pair of panel connecting bars 16 are coupled to the support tray unit 12 to face each other in parallel.

A pair of drum mounting panels 14 are coupled to the support tray 12 . A lower portion of the drum mounting panel 14 is coupled to a pair of left and right panel connecting bars 16 provided on a pair of left and right support sidewalls of the support tray 12 . The drum mounting panel 14 has a plate shape having a lower rim piece, an upper rim piece, and a front and rear rim piece on a periphery, and the lower rim piece of the drum mounting panel 14 is the panel connecting bar 16 . It is configured to be coupled to the upper support piece by a fastener such as a bolt. The lower edge of the drum mounting panel 14 may be configured to be coupled to the upper support piece of the panel connecting bar 16 by a bonding means such as welding. A pair of drum mounting panels 14 are coupled to the support tray 12 to form a structure arranged in parallel with each other.

The freezing drum 20 includes a cover 24 and a rotation drum 22 .

The cover 24 is configured in a circular loop shape. The cover 24 has an ice discharge hole communicating with the inner and outer surfaces. The cover 24 is supported by a pair of left and right drum mounting panels 14 of the support frame 10 . The cover 24 may be configured to be supported by a pair of left and right drum mounting panels 14 of the support frame 10 by fixing means such as brackets and bolts. The ice discharge hole of the cover 24 is disposed above the support tray 12 so that ice generated in the freezing cup 26 inside the rotation drum 22 passes through the ice discharge hole of the cover 24 . It may be collected by falling to the support tray unit 12 .

In addition, a steam nozzle 52 is provided to be disposed under the ice discharge hole of the cover 24 . The front end of the steam nozzle 52 is disposed under the ice discharge hole of the cover 24 , the base end of the steam nozzle 52 is connected to the water supply pipe 54 , and the water supply pipe 54 is provided with a pump 56 . Thus, water is discharged to the tip of the steam nozzle 52 through the water supply pipe 54 by the operation of the pump 56 . Water discharged from the steam nozzle 52 is sprayed at a predetermined pressure toward the opening of the freezing cup 26 provided in the rotation drum 22 .

A water sleeve 30 is provided on the cover 24 . The water sleeve 30 includes a main supply sleeve part 32 extending along the outer circumferential surface of the cover 24 , and a branch supply sleeve branching from the main supply sleeve part 32 and communicating with the inside of the freezing cup 26 . A portion 34 is provided.

The main supply sleeve 32 extends in a direction parallel to an outer circumferential surface of a circular loop shape. The main supply sleeve 32 is configured in a circular tube shape. A water supply pipe 54 (not shown) is connected to the main supply sleeve 32 . Water may be introduced into the main supply sleeve 32 through the water supply pipe 54 .

The branch supply sleeve portion 34 communicates with the main supply sleeve portion 32 . A branch supply sleeve 34 protrudes from both sides of the main supply sleeve 32 . A pair of branch supply sleeves 34 protrude from the main supply sleeve 32 on both left and right sides. The branch supply sleeve parts 34 are arranged at regular intervals along the outer circumferential surface of the cover 24 . The branch supply sleeve portion 34 is configured to communicate from the outer surface to the inner surface of the cover 24 . The branch supply sleeve part 34 has a structure in which the main supply sleeve part 32 and the inner surface of the cover 24 communicate with each other. The water flowing into the main supply sleeve 32 is configured to be supplied to the inner surface of the cover 24 through the branch supply sleeve 34 .

The rotation drum 22 is configured in a circular drum shape. A plurality of freezing cups 26 are provided inside the rotation drum 22 . The plurality of freezing cups 26 are configured to be arranged at regular intervals along the circumferential direction. In the present invention, a plurality of freezing cups 26 arranged along the circumferential direction are arranged in a plurality of sets. When the rotation drum 22 is viewed in a longitudinal section, a plurality of freezing cups 26 are arranged side by side in two rows. The freezing cups 26 of each row are spaced apart from each other by a predetermined distance. Since the branch supply sleeve part 34 is branched from the main supply sleeve part 32 in both left and right sides, the plurality of freezing cups 26 are arranged in two rows.

A rotation drum 22 is disposed inside the cover 24 . An open portion is provided at the outer end of the freezing cup 26, the open portion of the freezing cup 26 is disposed at a diagonal position facing the inner surface of the cover 24, and the water sleeve 30 is provided with a freezing cup ( 26), water is supplied to fill the inside of the freezing cup 26. Water entering the main supply sleeve 32 of the water sleeve 30 enters the inner surface of the cover 24 through the branch supply sleeve 34, and the water entering the inner surface of the cover 24 is It is configured such that water is injected into the inside of each freezing cup 26 through the opening formed at the outer end of each freezing cup 26 of the rotation drum 22 .

The rotation drum 22 is provided with shafts extending from the center to both sides. The shaft is coupled to both left and right drum mounting panels 14 of the support frame 10 . Both left and right shafts of the rotation drum 22 are coupled to the left and right drum mounting panels 14 of the support frame 10 via a bearing. The rotation drum 22 has a structure in which the support frame 10 is rotatably mounted. The rotation drum 22 is configured to have a cooling tube accommodating space on the inner surface of the plurality of freezing cups 26 .

A gear 37 is provided on one side of the left and right side surfaces of the rotation drum 22 . A disk-shaped gear 37 is provided on one side of the rotation drum 22 . The gear 37 is provided on one side of the rotation drum 22 so that the center of the gear 37 coincides with the center of the rotation drum 22 .

A motor 38 is mounted on the drum mounting panel 14 facing the gear 37 among the pair of drum mounting panels 14 of the support frame 10 . A driving gear 39 is coaxially coupled to the motor shaft of the motor 38 . A motor shaft of the drive motor 38 is connected to a drive shaft provided at the center of the drive gear 39 . The motor shaft of the drive motor 38 is connected to the drive shaft protruding from one side of the drive gear 39 through a connecting means such as a connector. At this time, the drive motor 38 is provided with a speed reducer, and since a motor shaft connected to the reduction gear is connected to the drive shaft of the drive gear 39 , the motor shaft of the drive motor 38 drives the drive gear 39 . The structure is connected to the shaft.

The driving gear 39 is meshed with a gear 37 provided on one side of the rotation drum 22 . A plurality of drive jaws are provided on the outer circumferential surface of the drive gear 39, and the drive jaws of the outer circumferential surface of the drive gear 39 are configured to mesh with the jaws of the outer circumferential surface of the gear 37 provided on one side of the rotation drum 22 do. When the driving gear 39 rotates by the motor 38 , the gear 37 rotates, and the rotation drum 22 on which the gear 37 is mounted on one side is also a pair of left and right drums of the support frame 10 . It is rotated in the mounting panel (14).

A cooling pipe 40 is disposed in the cooling pipe accommodating space inside the rotation drum 22 . The cooling tube 40 is configured in a coil shape.

The cooling pipe 40 is configured to include a plurality of contact cooling pipe parts 41, an inlet pipe part, and an exhaust pipe part. A flat surface is provided on the contact cooling tube portion 41 , so that the flat surface of the contact cooling tube portion 41 is in contact with the freezing cup 26 .

At this time, the contact cooling pipe part 41 includes a side contact cooling pipe part 42 having a flat surface in contact with the side of the freezing cup 26 , and an inner having a flat surface in contact with the inner end of the freezing cup 26 . It includes a side contact cooling tube portion (44). In addition, the side contact cooling pipe part 42 and the inner side contact cooling pipe part 44 are provided in plurality. The flat surfaces of the plurality of side contact cooling tube portions 42 are in contact with both side surfaces of the plurality of freezing cups 26 inside the rotation drum 22, and the flat surfaces of the plurality of inner side contact cooling tube portions 44 are in contact with each other. The surface is in contact with the inner end of the plurality of freezing cups 26 (that is, the inner end opposite to the outer end in which the opening is formed in the freezing cup 26).

The cooling pipe 40 has an inlet pipe part and an outlet pipe part extending laterally, and the inlet pipe part and the discharge pipe part are connected to the rotary joint (36). A passage is provided in the inside of the inlet pipe side rotary joint 36 connected to the inlet pipe part of the cooling pipe 40 and the discharge pipe part side rotary joint 36 connected to the discharge pipe part of the cooling pipe 40 . At this time, an expansion valve is connected to the inlet pipe portion of the cooling pipe 40 .

In the present invention, the rotary joint 36 is connected to the inlet tube portion of the cooling tube 40, and the refrigerant inlet tube is connected to the inner passage of the inlet tube side rotary joint 36. The refrigerant inlet tube and the rotary joint 36 By connecting the expansion valve to the path between the internal passages of It can be said that the expansion valve is connected to the cooling pipe 40 . That is, the inlet pipe portion of the cooling pipe 40 is connected to the rotary joint 36, and the refrigerant inlet pipe is connected to the inlet pipe side rotary joint 36. A vaporized gas is formed by this, and the vaporized gas passes through the inlet tube through the passage inside the rotary joint 36 on the inlet tube side and enters the cooling tube 40 .

The vaporized gas enters the cooling tube 40 through the inlet tube to exchange heat, and the heat-exchanged vaporized gas passes through the passage inside the rotary joint 36 on the discharge tube side and is supplied toward the compressor, The vaporized gas introduced into the compressor is made into a liquid refrigerant again by the condenser of the cooling cycle, and then is converted into vaporized gas again by the expansion valve, and then into the cooling tube 40 through the inlet tube of the cooling tube 40. vaporized gas enters.

The cooling tube 40 is built into the cooling tube receiving space of the rotation drum 22 to cool the rotation drum 22 by the vaporized gas passing therein. That is, the liquid refrigerant is vaporized as it passes through the expansion valve, and the vaporized gas enters the cooling tube 40 and heat exchange occurs, thereby cooling the rotation drum 22 and the plurality of freezing cups 26 . The cooling tube 40 cools the rotation drum 22 and the plurality of freezing cups 26 to a temperature sufficient to freeze ice when water is supplied to the plurality of freezing cups 26 of the rotation drum 22 . make it

A guider 62 is provided on the support frame 10 to be disposed under the cover 24 . Each of the guider mounting brackets are detachably coupled to the pair of side by side drum mounting panels 14 of the support frame 10 by a fastener, and a pair of side by side guiders 62 mounting to the support frame 10 A bracket is disposed, and a guider 62 is detachably coupled to the pair of guider mounting brackets by a fastener, and the guider mounting bracket is detachably attached to the pair of drum mounting panels 14 by a fastener. coupled to each other, the guider 62 is disposed under the cover 24 . The guider 62 is configured in a mesh shape in which a plurality of wires are arranged side by side, and is arranged to be inclined downwardly on the support frame 10 . When viewed from one side of the support frame 10 , the guider 62 has a structure in which the cover 24 is inclined downward from the bottom to the front.

According to the present invention having the above configuration, the rotation drum 22 is cooled by the cooling tube 40 (cooled by the vaporized gas passing into the cooling tube 40), and The plurality of freezing cups 26 are also cooled, while the rotation drum 22 and the cooling tube 40 are connected to the support frame 10 by the drive motor 38 , the drive gear 39 , and the gear 37 . When water is supplied to the plurality of freezing cups 26 by the water sleeve 30 while rotating at When the opening part is disposed at a position facing the lower ice outlet of the cover 24 by rotation of the rotation drum 22, ice falls from the freezing cup 26 and falls to the guider 62, and the guider (62) What is necessary is just to put the ice falling upwards into a container placed under the guider (62).

At this time, a sensor is provided on the inner circumferential surface of the cover 24 , and the sensor is disposed at a position facing the opening of the freezing cup 26 inside the rotation drum 22 . The sensor may be configured as a proximity sensor or an optical sensor.

The sensor detects whether the inner space of the freezing cup 26 is filled with ice, and when the sensor detects that the inner space of the freezing cup 26 is filled with ice, When the supply of water from the water sleeve 20 is stopped and the supply of vaporized gas for cooling to the inside of the cooling tube 40 is also stopped, the freezing cup 26 is The ice made inside is discharged through the ice discharge hole formed in the lower part of the cover 24 . When all the ice made in all the freezing cups 26 inside the rotation drum 20 is discharged, the sensor detects that the insides of all the freezing cups 26 are empty and puts them in the water sleeve 30 . Thus, water is supplied again and vaporized gas is again supplied to the inside of the cooling tube 40 to make ice again inside each freezing cup 26 of the rotation drum 22 .

On the other hand, the support tray part 12 is configured in a box shape with an open top, and the water that is sprayed from the water sleeve 30 and made into ice and the water that may be generated inside the rotation drum 22 are It may be collected by falling into the box-shaped support tray unit 12 .

In the ice manufacturing apparatus according to the present invention, in a state in which vaporized gas entering the cooling tube 40 cools the rotation drum 22 by heat exchange and also cools the plurality of freezing cups 26 inside the rotation drum 22 When water is supplied to each freezing cup 26 by rotation of the rotation drum 22, ice is formed inside the freezing cup 26. As the rotation drum 22 rotates, a plurality of freezing cups ( 26), when the ice is completely formed inside the freezing cup 26, the ice can be freely dropped through the lower ice discharge hole of the cover 24. Therefore, it is easy and quick to make ice, and it is convenient and quick to collect ice.

In addition, in the present invention, the cooling tube 40 is configured in a coil shape embedded in the cooling tube accommodating space inside the rotation drum 22 and is built into the rotation drum 22 of a compact size, so that the ice manufacturing apparatus has the effect of significantly reducing the size of

In addition, since the cooling pipe 40 is configured in a coil shape, the heat exchange passage is sufficiently long as the vaporized gas passes through the coil-shaped cooling pipe 40, and heat exchange is more reliably performed. Ice can be made more reliably inside each of the freezing cups 26 .

In addition, as the rotation drum 22 and the plurality of freezing cups 26 rotate, the ice is made layer by layer inside the freezing cup 26, so that the finally made ice is made of high-quality ice as clear as glass grains. can be made

In addition, the steam discharged from the steam nozzle 52 is sprayed toward the opening of the freezing cup 26 provided in the rotation drum 22 , and the steam discharged from the steam nozzle 52 causes the freezing drum 20 to ) can be self-cleaning. The rotating drum 22 itself of the freezing drum 20 as well as the cover 24 itself can be automatically cleaned with steam. For example, it is possible to automatically clean the rotation drum 22 and the cover 24 by steam shot from the steam nozzle 52 while rotating the rotation drum 22 while taking a period of about one month to one month. .

In addition, in the present invention, the cooling pipe 40 is configured to include a plurality of contact cooling pipe parts 41 , an inlet pipe part and an exhaust pipe part, and the contact cooling pipe part 41 has a flat surface on the side of the freezing cup 26 . It is configured to include a side contact cooling tube portion 42 in contact with an inner side contact cooling tube portion 44 having a flat surface in contact with the inner end of the freezing cup 26, Since the flat surface is in contact with the freezing cup 26 inside the rotation drum 22 when the vaporized gas passes, the heat exchange efficiency between the cooling tube 40 and the freezing cup 26 is maximized while the freezing cup ( 26) makes the speed of ice formation in the inside faster, so the efficiency of making ice increases.

In addition, the side contact cooling tube portion 42 and the inner side contact cooling tube portion 44 are provided in plurality, and the flat surfaces of the plurality of side contact cooling tube portions 42 are arranged in a plurality of rows. ), while the flat surfaces of the plurality of inner side contact cooling tube portions 44 are in surface contact with the inner surfaces of the plurality of freezing cups 26 arranged in a plurality of rows, the cooling tube ( As the vaporized gas passes through the inside of the 40 , the heat exchange rate between the cooling tube 40 and the plurality of freezing cups 26 is further increased, thereby further improving the efficiency of forming ice in the freezing cup 26 . In other words, the cooling tube 40 and the rotation drum 22 are maximized by maximizing the contact area between the freezing cup 26 and the cooling tube 40 inside the rotation drum 22 when the vaporized gas passes through the cooling tube 40 . ) to maximize the heat exchange efficiency between the freezing cups 26 , so ice can be made more quickly in the freezing cup 26 , and between the cooling tube 40 and the freezing cup 26 of the rotation drum 22 . As the heat exchange is made faster, the function of supplying only vaporized gas to the compressor can be performed more reliably.

In addition, in the freezing drum 20, the cover 24 supplies water from the water sleeve 30 to make ice while enclosing the outer circumferential surface of the rotation drum 22, and the cover 24 is provided with the supplied water. This will prevent it from popping out.

At this time, the size of the pair of left and right drum mounting panels 14 of the support frame 10 is larger than the side area of the freezing drum 20, and the drum mounting panel 14 is made of a stainless plate. , since the strain-less plate blocks both sides of the freezing drum 20, the drum mounting panel 14 prevents water from splashing out even when water is about to jump out from both sides of the freezing drum 20. prevent.

On the other hand, in the present invention, at a position out of the driving gear 39 , while meshing with the jaws of the outer peripheral surface of the gear 37 provided on the side surface of the rotation drum 22 , the driving gear is based on the center of the rotation drum 22 . An idle rear is disposed at a diagonal position facing 39 , and the idle jaws of the outer peripheral surface of the idle gear 33 may be configured to mesh with the jaws of the gear 37 provided on the side surface of the rotation drum 22 .

In this case, when the driving gear 39 is rotated by the motor 38 to rotate the rotation drum 22 , the idle gear 33 is a force that the driving gear 39 pushes toward the center of the rotation drum 22 . to offset the overload of the motor 38 due to the eccentric force acting on the driving gear 39 toward the rotation center of the rotation drum 22 (that is, toward the shaft coupled to the support frame 10) It is possible to prevent damage to the motor 38 due to such an overload of the motor 38 can be reliably prevented.

In addition, in the present invention, a plurality of idle gears 33 are disposed on the periphery of the rotation drum 22 , and the idle jaws on the outer peripheral surface of the plurality of idle gears 33 mesh with the jaws on the outer peripheral surface of the rotation drum 22 . do. At least three idle gears 33 are structured to support the rotation drum 22 in at least three places.

When the at least three idle gears 33 support the circumference of the rotation drum 22 in at least three places, the driving gear 39 is rotated by the motor 38 to rotate the rotation drum 22. The idle gear 33 has at least three parts that support the force pushing the drive gear 39 toward the center of the rotation drum 22, and the offsetting force is at least three times or more, so the Damage to the motor 38 due to overload can be prevented more reliably.

On the other hand, the ice manufacturing apparatus of the present invention and the snowflake ice water manufacturing apparatus may be installed and used together. At this time, the snowflake ice-water manufacturing apparatus includes a main frame 130 , an ice disk 140 rotatably mounted on the main frame 130 and provided with a cooling tube inside to be cooled by the cooling tube, and the ice disk A water nozzle for supplying water to the side of the icing disk so that the ice is frozen on the side of the icing disk 140, and a blade for scraping off the ice frozen on the side of the icing disk 140 to form snowflake ice . Reference numeral 139 denotes a driving gear meshed with the icing disk 140 , 143 denotes a motor that rotates the driving gear so that the icing disc 140 rotates, and 137 denotes a guider that receives snowflake ice and descends.

The ice disk 140 rotates in the main frame 130 , and water is supplied to the side of the ice disk 140 cooled by the cooling pipe by a water nozzle to freeze the ice, and On the side, the ice is scraped off by the blade to make snowflake ice, and the snowflake ice is configured to come down on the guider 137 and be contained in a container.

If the ice manufacturing device of the present invention and the snowflake bingsu maker are installed together and used for both purposes, it is possible to make and use snowflake bingsu while manufacturing ice, so the efficiency is good. As such, there is an advantageous effect in terms of cost and the like.

Terms such as "include", "compose" or "have" described above mean that the corresponding component may be inherent unless otherwise stated, so it does not exclude other components. It should be construed as being able to further include other components. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs, unless otherwise defined. Terms commonly used, such as those defined in the dictionary, should be interpreted as being consistent with the contextual meaning of the related art, and are not interpreted in an ideal or excessively formal meaning unless explicitly defined in the present invention.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

Therefore, since the embodiments described above are provided to fully inform those of ordinary skill in the art to which the present invention pertains the scope of the invention, it should be understood that they are exemplary in all respects and not limiting, The invention is only defined by the scope of the claims.

10. Support frame 12. Support tray part
14. Drum mounting panel 20. Freezing drum
22. Cover 24. Rotating Drum
26. Freezing Cup 30. Water Sleeve
32. Main supply sleeve part 34. Branch supply sleeve part
36. Rotary joint 40. Cooling tube
42. Contact cooling pipe section 44. Inner side contact cooling pipe section
52. Steam Nozzle

Claims (12)

support frame 10;
a freezing drum 20 mounted on the support frame 10 and having a plurality of freezing cups 26 therein;
a cooling pipe 40 built into the freezing drum 20;
a water sleeve 30 for supplying water so that ice is generated inside the freezing cup 26 of the freezing drum 20 by the cold air of the cooling tube 40;
The cooling pipe 40 is provided with a contact cooling pipe part 41,
The contact cooling tube portion 41 includes a side contact cooling tube portion 42 having a flat surface in contact with the side surfaces of the plurality of freezing cups 26 , and a flat surface contacting an inner end of the freezing cup 26 . An ice manufacturing apparatus comprising: an inner side contact cooling pipe part (44).
According to claim 1,
The freezing drum 20,
a cover 24 coupled to the support frame 10 and having an ice discharge hole communicating with the inner and outer surfaces;
A rotation drum 22 coupled to the inside of the cover 24 and provided with the plurality of freezing cups 26;
An open portion is provided at the outer end of the freezing cup 26 , the open portion of the freezing cup 26 is disposed at a position facing the inner circumferential surface of the cover 24 , and the water sleeve 30 is the freezing cup Ice, characterized in that the water is supplied to fill the inside of the freezing cup (26) through the opening of (26) so that ice is made in the inside of the freezing cup (26) by the cooling pipe (40) manufacturing equipment.
3. The method of claim 2,
The opening portions of the plurality of freezing cups 26 provided in the freezing drum 20 are disposed to face the inner circumferential surface of the cover 24 , and the water sleeve 30 covers the outer circumferential surface of the cover 24 . Ice, characterized in that it comprises a main supply sleeve (32) extending along the side, and a branch supply sleeve (34) branched from the main supply sleeve (32) and communicated with the inside of the freezing cup (26). manufacturing equipment.
3. The method of claim 2,
The cover 24 is configured in a circular loop shape and coupled to the support frame 10, and the freezing drum 20 is configured such that the plurality of freezing cups 26 are arranged at regular intervals along the circumferential direction. An ice manufacturing apparatus, characterized in that it is rotatably coupled to the support frame (10).
5. The method of claim 4,
and the freezing drum (20) is configured such that the plurality of freezing cups (26) are arranged in two rows.
3. The method of claim 2,
The support frame 10,
Including; and a support tray 12 and a drum mounting panel 14 coupled to the support tray 12 and arranged to face each other,
Shafts are provided on both sides of the freezing drum (20), and the shaft is configured to be coupled to the drum mounting panel (14) through a bearing.
7. The method of claim 6,
The support tray part 12 is configured in a cross-sectional channel box shape with an open top, and is provided at the upper end of the support tray part 12 and consists of panel connection bars 16 arranged in parallel with each other,
The ice making apparatus, characterized in that the drum mounting panel (14) is connected to the panel connecting bar (16).
8. The method of claim 7,
and the panel connecting bar (16) is configured in a cross-sectional channel bar shape.
7. The method of claim 6,
A motor 38 is mounted on the drum mounting panel 14 , a driving gear 39 is coupled to a motor shaft of the motor 38 , and the driving gear 39 is coupled to one side of the freezing drum 20 . ) and a gear (37) meshed with each other.
delete According to claim 1,
The ice manufacturing apparatus, characterized in that the support frame (10) is provided with a discharge guider (62) to be disposed under the freezing drum (20).
According to claim 1,
The freezing drum 20,
a cover 24 coupled to the support frame 10 and having an ice discharge hole communicating with the inner and outer surfaces;
A rotation drum 22 coupled to the inside of the cover 24 and provided with the plurality of freezing cups 26;
A steam nozzle (52) is disposed below the ice discharge hole.

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