KR200409496Y1 - Compression sea water ice making machine - Google Patents

Abstract

The present invention relates to a pressurized sea ice deicing device which is intended to obtain sea ice that is not easily melted by hardening the crystal structure by hardening the crushed ice made of sea water instantaneously, and in detail, the rotating part to the upper side of the support supporting the ground. The filling unit, the pressing unit and the discharge unit are sequentially disposed while maintaining a predetermined distance from each other, and the filling unit, the pressing unit and the discharge unit are located at each lower portion each time the rotating disc is temporarily stopped by the control unit. Work is started on the containers, and when each work is completed, the operation of starting the intermittent rotation of the rotating disc of the rotating part is continued, so that each time the rotating disc is rotated, the crushed ice is produced as large sea ice crystals. The present invention relates to a type of sea ice deicing device, and according to the present invention, the structure of sea ice crystals is dense, so that the conventional piece ice is easily melted. By eliminating and provides a dense freezing stagnant water rescue is a useful devise that can long maintain the freshness of foods, including fresh, ie live fish, shellfish.

Crimping, sea ice, flake ice, ice, ice, seafood

Description

Compressed Sea Ice Deicing System {COMPRESSION SEA WATER ICE MAKING MACHINE}

1 is a schematic perspective view of the present invention the compressed sea ice deicing device

2 is an enlarged perspective view of a rotating disc which is a part of the present invention;

Figure 3 is a schematic cross-sectional view of the compression sea ice deicing device of the present invention

4 and 5 is a view showing the operating state of the sensor of the filling portion and the discharge portion of a portion of the present invention

6 is a view showing an example of a conventional compressed sea ice deicing device.

7 is a view showing an example of a conventional compressed sea ice deicing device.

* Description of the symbols for the main parts of the drawings *

1. Ice sculpture 2. Sea ice crystal

10. Support 20. Swivel

30. Filling part 40. Crimping part

50. Outlet 60. Control unit

110. Hydraulic cylinder fixing frame 210. Rotary disc

212.Stop bar 214.Contact sensor

220. Retaining plate 222. Outlet hole

230. Vessel 240. Drive motor

250. Rotating shaft 260. Reducer

270. Gear 310. Carving Ice Hopper

320. Rotating screw 330. Rubber film

410. Crimping Hydraulic Cylinder 412. Piston Rod

420. Pressure plate 430. First moving bar

442. Pressure plate lowering sensor 444. Pressure plate lowering sensor

510. Hydraulic cylinder for discharge 512. Piston rod

520. Mild 530. Second moving bar

542. Knocker falling sensor 544. Knocker falling sensor

550. Disc 560. Grinding blade

The present invention relates to a sea ice deicing device, and more particularly, by pressing the crushed ice made of sea water with instantaneous large force to harden the crystal structure, it is a compression sea ice deicing ice which can be produced as large sea ice crystals that are not easily melted. Relates to a device.

In general, when supporting freshness and quality of fresh foods, the fresh foods are immersed in a low temperature liquid obtained by mixing ice with water or sea water, for example, water or sea water, cooled, kept at low temperature, and not frozen. Storage, ie ice refrigeration.

Regarding the freshness of such fresh food, it can be maintained depending on the low temperature liquid, but salt and concentration are a problem in terms of quality.

For example, in the case of fish and shellfish, when immersed in fresh water or a liquid having a high salt concentration, there is a problem that the surface of the body is discolored or causes clouding of the eye, thereby significantly reducing the value of the product.

The concentrated salt concentration here is usually said to be 3% or more, and is lower than 3.4% which is the salt concentration of seawater.

For this reason, the low temperature liquid which immerses fishery products is prepared by putting the seawater cooled to near 0 degreeC in the water tank into which fishery products are thrown in, and adding the ice manufactured from fresh water.

By injecting fish and shellfish into the low-temperature liquid thus obtained, part of the ice melts, and finally, a salt concentration of 3% or less is prevented and the quality of the fish and shellfish that is immersed is prevented.

However, obtaining such a low temperature liquid requires enormous effort in mixing ice and seawater, and requires fresh water to prepare ice, so that the storage tank needs to be separately installed.

In particular, as a method for maintaining freshness of fish, the simplest method conventionally used is to cool the fish with ice. For example, when a fishing boat comes out to fish, a large amount of ice is loaded on a boat and the captured fish is iced. It is transported while preserving in seawater cooled by water.

However, since ordinary ice is easily melted and fresh water, there has been a problem that over time, salt concentration of seawater decreases and freshness of fish falls.

In order to solve this problem, a method of reducing fresh water has recently been performed by freezing a part of seawater and preparing sea ice having fluidity.

For example, a method is known in which seawater is produced by spraying seawater into a water tank in advance and by freezing part of the seawater forcibly.

That is, as an ice making method using seawater, as shown in FIG. 6, a coolant pipe is installed on the outer surface of the cylindrical ice making plate, and the seawater is attached to the film on the smooth inner surface from the top, while the seawater film flows down. A method of freezing and producing ice and continuously scraping the produced ice with an auger screw or the like is disclosed.

In addition, as shown in Fig. 7, the heating medium peeling method is installed in a vertical or inclined plane of the ice sheet to be cooled in accordance with the refrigerant, and the coolant and the fruit alternately on the ice making plate while flowing sea water from the upper portion of the ice making plate Disclosed is a method of producing ice on an ice making plate by flowing and peeling the generated ice from the ice making plate.

In this figure, (A) is a water tank, (B) is a pump, (C) is a motor, (D) is ice to be produced, and (E) is an ice making plate.

The sea ice produced in this way is not only able to produce large particles of sea ice, but also when the salt concentration is thinner than 2% because the ice produced by the rotating blades is mechanically scraped off or peeled off from the ice making plate. The ice had an issue that could not be highly scraped.

In addition, there is a problem that seawater and ice (fresh water ice) are easily separated, and that crystals are small and easily melted by flake ice or powdered ice, which is not suitable for preservation ice such as fish and shellfish.

The present invention provides a pressurized sea ice deicing device which can produce seawater ice that has been completed by conventional piece ice without using fresh water quickly and accurately by a series of mechanical continuous operations to produce large sea ice crystals. The purpose.

In addition, the pressurized sea ice deicing device according to the present invention can automatically produce flake ice as ice crystals of sea ice by a series of mechanical continuous operations. Another object is to provide a pressurized sea ice deicing device that can greatly improve the productivity and quality of ice.

In order to achieve the above object, the pressurized sea ice deicing device according to the present invention includes a plurality of vertical frames integrally formed vertically at both ends of a plate supporting the ground, a fixed plate fixed to an upper end of the vertical frame, and A support having a contact sensor attached to an outer circumferential surface of the fixed plate; A rotating disc which is provided at the center of the support part and is continuously intermittently rotated in one direction by a predetermined angle at a time by a driving motor and a reducer which supplies rotational force to the rotating shaft, and a predetermined interval at an upper periphery of the rotating disc. A rotating part having a plurality of containers radially attached to each other and a stop bar attached to an outer circumferential surface of the rotating disc; A filling part having a piece ice hopper for filling piece ice in each container; A pressing part having a pressing plate for pressing the piece of ice filled in the container; And a discharge part having a seal for discharging the seawater ice crystals in which the crushing ice is aggregated in the form of lumps after the pressing operation is completed. The filling part, the pressing part, and the discharge part are fixed to each other around the rotary disc. The filling part, the pressing part and the discharge part start working on the containers located at each lower part each time, while being spaced at intervals and sequentially disposed by the control unit during the intermittent rotation of the rotating disc. When each of these operations is completed, the operation of starting the intermittent rotation of the rotating disc is continued, and the program control is performed so that the filling, pressing, and discharging operations of the slicing ice are sequentially performed every rotation of the rotating disc.

In addition, the rotating unit according to another preferred embodiment of the present invention, the contact detected by the contact sensor provided in the support portion for attaching the stop bar at a predetermined interval in the circumferential direction of the rotating disc and detects the rotation of the stop bar By sending a signal to the control unit to control the rotation of the drive motor is characterized in that the rotating disc is configured to be intermittent rotation.

In addition, the filling unit according to another preferred embodiment of the present invention is installed on the upper side of the support so that the container on the rotating disc is located below, the rotating disc is intermittently rotated by the control unit into the crushing ice hopper. It is provided with a rotating screw that is operated whenever it is paused, the stop bar of the rotating unit is rotated in contact with the contact sensor of the support, characterized in that the rotating screw is rotated when the detected contact signal is generated to insert the flake ice into the container.

In addition, the crimping portion according to another preferred embodiment of the present invention is installed on the upper side of the support so that the container on the rotating disc is sequentially positioned while maintaining a constant distance from the filling portion, the rotation disc by the control unit A pressurized hydraulic cylinder is provided which is operated whenever it is paused during the intermittent rotation, and the pressure plate attached to the tip of the piston rod of the pressure hydraulic cylinder descends to press the piece ice into the container, and when the pressure is completed, the pressure plate is raised. It characterized in that it comprises a pressure plate detection sensor for detecting the position of the pressure plate to return.

In addition, the pressure plate detection sensor of the pressing unit according to the present invention, the pressure plate falling detection sensor for generating a contact signal by contacting the first moving bar installed on one side of the piston rod completely lowered; And a pressure plate lift detection sensor for contacting at a position where the first moving bar is fully raised to generate the contact signal.

In addition, the discharge unit according to another preferred embodiment of the present invention, while maintaining a constant distance from each other with the crimping portion is installed on the upper side of the support so that the container on the rotating disc is sequentially located below, the member disc by the control unit A discharge hydraulic cylinder is provided which is operated whenever it is paused during the intermittent rotation, and the discharge hydraulic cylinder is operated by the operation signal of the control unit, and the pusher attached to the end of the piston rod of the discharge hydraulic cylinder moves forward. When it is pushed to the discharge plate located below the container of the rotating disc and characterized in that configured to include a pusher sensor for detecting the position of the pusher so that the pusher retreat when the discharge operation is completed.

In addition, the closet detection sensor of the discharge unit according to the present invention, the second drop bar installed on one side of the piston rod is a contact point in the fully lowered position to generate a contact signal falling detection sensor; And a close up detection sensor for contacting the second moving bar at a fully raised position and generating a contact signal thereof.

In addition, the discharge portion of the compressed sea ice deicing device according to another embodiment of the present invention, is coupled to the upper side of the discharge plate, the grinding blade so as to crush the sea ice passing through the container by pressing the pusher; It is preferable that it is further provided.

Hereinafter, the configuration of the present invention by the accompanying drawings in detail as follows.

1 is a schematic perspective view of a crimping sea ice deicing device according to the present invention, FIG. 2 is an enlarged perspective view of a rotating disc, which is a part of the present design, and FIG. 4 and 5 are views showing the operating state of the sensor of the filling portion and the discharge portion of a portion of the present invention, respectively.

1 is a schematic view of the entire compressed sea ice deicing device according to the present invention, wherein reference numeral 10 is a support portion, and reference numeral 20 is located at the center of the support portion at a constant speed, one at a time. A rotating part 20 having a circular rotating disc 210 intermittently rotating in a direction, and a plurality of containers 230 are fixed to the upper surface of the rotating disc 210 radially at regular intervals, and on the support part 10, A plurality of stations 30, 40, and 50 are installed at the proximal positions corresponding to the containers 230 to perform the respective working steps of the sea ice making process in association with the containers 230.

According to FIG. 2, there are three vessels 230 in total, so that the rotating disc 210 is intermittently rotated 120 ° at a time and each vessel 230 stays at any station and then at any station. The time to move to the station can be adjusted according to the working situation.

The support portion 10 is composed of a plurality of vertical frame (10b) integrally formed perpendicular to both ends of the plate (10a) for supporting the ground.
Here, the fixing plate 220 is installed on the upper end of the vertical frame (10b).
In addition, the upper portion of the fixing plate 220 of the support 10, the rotating portion 20 having a rotating disk 210 is provided with a plurality of containers 230, the flake ice (1) in each of the containers 230 Filling unit 30 having a flake ice input hopper 310 for filling the, and the pressing portion 40 having a pressing plate 420 for pressing the flake ice (1) filled in the container 230, and Discharge parts 50 having a sealer 520 for discharging the seawater ice crystals 2, which are compressed ice cubes, are sequentially disposed while maintaining a predetermined interval from each other.
In addition, the support 10 is connected to the drive motor 240 for intermittently rotating the rotary disk 210 of the rotating unit 20, and the operation of the drive motor 240 and the components constituting the respective stations, as appropriate Control unit 60, and other necessary structures are installed.

In the above configuration, when the rotation disc 210 intermittently rotates 120 ° once by the driving of the driving motor 240, the containers 230 attached to the upper surface of the rotating disc 210 are rotated, and at this time, each filling part 30 and the pressing part ( 40 and the working structure of the discharge unit 50 is to perform a predetermined operation, respectively, while the rotary disk 210 is stationary on the container 230 transported below, respectively, accordingly the rotary disk ( The vessels 230 on the one-to-one circumference of each station in turn, and each time finally passing through the station to produce a series of sea ice crystals (2) of each one large crystals in succession, and the finished sea ice formed in this way When the received container 230 passes through the station, the container 230 is discharged from the container 230, crushed into a predetermined size, and then transferred to a predetermined place by a conveyor.

Each station on the rotating disc 210 supplies one piece of sea ice crystals (2), such as supplying pieces of ice (1) to the container (230), compressing the pieces of ice (1), and then removing them. All tasks required for the fixed work is divided into stages to perform appropriate sharing. The details of the work performed by each station and the characteristic components of each station to perform the tasks are as follows.

First, as shown in FIGS. 1 to 3, each station including the filling part 30, the pressing part 40, and the discharge part 50 is disposed around the circumference of the rotating part 20 installed above the support part 10. The control unit 60 for collectively controlling the rotating part 20, the filling part 30, the pressing part 40, and the discharge part 50 is installed around the support part 10. It is.

First, as shown in FIG. 2, the rotating part 20 is formed by fixing a plurality of containers 230 capable of accommodating the flake ice 1 therein to an upper surface of the rotating disc 210. 230 serves to circumvent each station on the rotary disk 210 in order to stably receive a piece of ice (1) supplied in a certain amount, the interior of the container 230 has a shape that is opened up and down, A fixing plate 220 is further provided to prevent the bottom of the container 230 drilled under the rotating disc 210.

That is, the fixing plate 220 is fixed to be in close contact with the lower side of the rotating disk 210, the filling portion 30 and the pressing portion 40 in the position of the crushed ice (1) for filling and pressing the container ( 230, but the bottom of the discharge portion 50 in the position of the discharge portion 50 is discharged cut into the same size as the bottom of the container 230 in order to discharge the sea ice crystals (2) crushed ice in the form of lumps Has a hole 222.

In addition, a contact sensor 214 attached to the stop bar 212 and the support 10 at predetermined intervals is attached to the side of the rotation disk 210.

Therefore, when the contact sensor 214 sends the signal to the control unit 60 by the contact from the stop bar 212, the reduction unit 260 by controlling the rotation of the drive motor 240 by the control unit 60. And the rotation disc 210 by intermittent rotation by the gear 270.

The rotation disk 210 is rotated by the rotational force from the drive motor 240 is transmitted to the rotating shaft 250 via the gear 270, if the container 230 is rotated by the interval of the reduction by the reducer 260 An intermittent rotation is made which pauses and then rotates again after a certain time.

Therefore, according to the intermittent rotation of the rotating disc 210, a series of vessels 230 continue to carry out various operations such as rotation transfer, pause, filling, rotation transfer, pause, pressing, rotation transfer, pause, and discharge. Will be repeated.

The intermittent rotary motion and filling operation, the pressing operation, and the discharge operation of the rotating disc 210 are collectively controlled by the control unit 60 by a series of preset computer programs. By processing to drive the drive motor 240 and the hydraulic cylinder and the like, the filling, pressing and discharging operations are automated.

On the other hand, the filling part 30 according to the present invention is the first station on the rotary disk 210 in accordance with the intermittent rotation of the rotary disk 210 in accordance with the intermittent rotation of any container 230 that is rotated and stopped in the ice (1) It is responsible for supplying a certain amount of).

The configuration of the filling unit 30 for performing this is composed of a crushing ice hopper 310 having a rubber film 330 as shown in FIG.

In addition, the inside of the crushing ice hopper 310 is provided with a rotating screw 320, the control unit 60 is rotated by the control unit 60, the rotation screw 320 is paused every time during the intermittent rotation. Rotation of the rotating screw 320 is stopped when the flake ice (1) filling operation is completed into the container 230 in the engraving ice input hopper 310 by rotating.

In addition, the rubber membrane 330 provided between the flake ice input hopper 310 of the filling unit 30 and the container 230 is a container 230 filled with the flake ice 1 of the rotating disc 210. When the conveyed according to the rotation to prevent the flake ice (1) to overflow the upper surface of the container 230 and overflows to serve to sweep the filled flake ice (1).

On the other hand, the crimping portion 40 according to the present invention is the second station on the rotating disc 210 as soon as any container 230 is rotated stop the hydraulic cylinder 410 is operated by the hydraulic cylinder 410 pressure plate ( After lowering the 420 to compress the piece ice (1), the hydraulic cylinder 410 is deactivated at the same time as the home position to prepare for the next operation.

As described above, the crimping portion 40 is responsible for crimping the pieces of ice 1 supplied to the container 230, and the configuration of the crimping device for performing this is fixed to the bottom plate as shown in FIG. The hydraulic cylinder fixing frame 110 fixed to the support 10 is coupled to the upper support 10, the piston plate 412 by the hydraulic cylinder 410 for the fixed plate 220 is a predetermined distance up and down A pressure plate 420 reciprocating is provided.

Therefore, when the pressure plate 420 attached to the tip of the piston rod 412 moves downward as the hydraulic pressure is supplied to the crimping hydraulic cylinder 410, the engraved ice 1 filled in the container 230 is compressed. When the pressing operation is completed, the pressure plate 420 is configured to retreat back.

Here, the force that the pressing plate 420 is preferably pressed for 2 to 5 seconds with a force of about 50 to 100 tons (TON).

Therefore, the crushed ice 1 in the container 230 is a dense crystal structure of the crystal structure will be produced as a large sea ice crystal (2).

In addition, the crimping portion 40 is configured to include a pressure plate detection sensor 442, 444 for detecting the position of the pressure plate 420, as shown in Figure 4 and 5, the pressure plate detection sensor (442, 444) The first movement bar 430 installed on one side of the piston rod 412 moves together with the first movement bar 430 contacting at a fully lowered position to generate a contact signal, and the first movement bar ( 430 is composed of a pressure plate rising detection sensor 444 for contacting at a fully raised position to generate the contact signal.

Therefore, when the crimping work for the piece ice 1 in the container 230 is completed by the crimping portion 40 and the contact point is raised to the pressure plate rising detection sensor 444 by the first moving bar 430, the contact signal Is input to the control unit 60 to drive the driving motor 240, the reduction gear 260, etc. again to rotate the paused rotating disk 210 again.

On the other hand, the discharge part 50 according to the present invention is installed on the upper side of the support portion 10 so that the container 230 on the rotating disc 210 is sequentially positioned while maintaining a constant distance from the crimping portion 40 do.

The discharge part 50 may include a seal 520 formed by the discharge hydraulic cylinder 510 and the piston rod 512, and a second moving bar 530 vertically attached to the tip of the piston rod 512. Consisting of the pressure detection sensor (542, 544) and the discharge plate 550 for guiding the discharge direction of the sea ice crystals (2) for detecting the position of the second moving bar 530, the discharge hydraulic cylinder 510 When the seal 520 attached to the tip of the piston rod 512 moves downward as the hydraulic pressure is supplied to the piston rod, the pressed seawater ice crystal 2 in the vessel 230 is pushed out of the vessel 230, and the discharge operation is performed. Upon completion, the sealer 520 is configured to retreat.

Here, the discharge hydraulic cylinder 510 is installed to be operated whenever the rotation disc 210 is paused during the intermittent rotation by the control unit 60.

In addition, the close detection sensor (542, 544) is installed on one side of the piston rod 512, the second moving bar 530 to move together in contact with the fully lowered position to generate the contact signal falling detection sensor ( 542 and the second moving bar 530 are contacted at the fully raised position to generate a close up rise detection sensor 544 to generate the contact signal.

Accordingly, when the discharge operation of the seawater ice crystals 2 compressed in the container 230 by the discharge unit 50 is completed and the contact point is detected by the second moving bar 530 to the push-up rising sensor 544. The contact signal is input to the control unit 60 to drive the driving motor 240, the reduction gear 260, etc. again to rotate the paused rotating disc 210 again.
Here, the control unit 60 to stop at the correct position of each part during the rotation operation of the rotary disk 210, and to control the operation of each part is provided.
The control unit 60 is provided with five contact sensors around the periphery of the support 10, first contact that determines the stop position of the rotating disk 210 when the rotating disk 210 of the rotating unit 20 is rotated Sensor 214 is installed on one side of the fixed plate 220 of the support 10, the pressure plate lowering for detecting the lifting position of the pressure plate 420 attached to the tip of the piston rod 412 of the crimping hydraulic cylinder 410 The sensor 442 and the pressure plate lift detection sensor 444 are installed on one side of the pressure plate 420, and the lifting position of the pusher 520 attached to the tip of the piston rod 512 of the discharge hydraulic cylinder 510 is adjusted. A dense drop detection sensor 542 and a dense rise detection sensor 544 are respectively installed on one side of the dense 520.

On the other hand, the discharge portion 50 according to another embodiment of the present invention, the grinding blade 560 to crush the sea ice crystals 2 passing through the container 230 by the pressure of the sealer 520 It is preferable that this is further provided.

Therefore, by controlling the number of the grinding blade 560, the crushed ice (1) can be manufactured in a size convenient to use by crushing the sea ice crystals 2 compressed in a lump shape to a certain size.

In this embodiment, the grinding blade 560 is provided in a cross shape to divide the sea ice crystals 2 into four.

The operation method of the device of the present invention configured as described above is as follows.

First, when the start switch of the control unit 60 is pressed, the rotating disk 210 starts the rotational movement, and the crushing ice 1 filling and pressing operations are started.

At this time, the rotation disk 210 is rotated by the angle divided by the reducer 260, and then stops and then repeats the intermittent rotation operation to rotate again, in the embodiment of the present invention 120 ° in the intermittent rotation operation After rotating at intervals, the intermittent rotation is interrupted.

Therefore, the container 230 installed on the rotating disc 210 is made while being sequentially transported from the filling part 30 to the discharge part 50 while continuing the intermittent rotation as shown in FIG.

First, a case in which the empty container 230 of the rotating disc 210 is positioned in the filling part 30 while repeating the intermittent rotation is as follows.

As shown in FIG. 3, the rotation disc 210 is rotated to detect the stop bar 212 mounted on the side of the rotation disc 210 by the contact sensor 214 installed on the support 10 to control the contact signal. When sent to the unit 60, the control unit 60 accordingly stops the drive motor 240 to position the container 230 in the correct position below the filling unit 30.

At the same time, the control unit 60 performs a filling operation for injecting the flake ice 1 into the container 230 by operating the rotating screw 320 inside the flake ice input hopper 310 of the filling unit 30. .

At this time, the signal to stop the operation of the rotary screw 320 is interrupted by the push-open detection sensors (542, 544) of the discharge unit 50 to be described later, the operation of the rotary screw 320 is stopped to complete the filling operation.

 When the filling operation is completed as described above, the rotating disc 210 continues to rotate intermittently, and the container 230 having completed the filling operation is transferred toward the crimping unit 40.

 When the rotation disc 210 is rotated again and the stop bar 212 mounted on the side of the rotation disc 210 is sensed by the contact sensor 214 to send a contact signal to the control unit 60, the control unit accordingly. At 60, the drive motor 240 is stopped to position the container 230 at the correct position below the crimping portion 40.

At this time, the hydraulic pressure is supplied to the pressure hydraulic cylinder 410 by the control unit 60 so that the piston rod 412 attached to the lower end of the pressure plate 420 moves downward and ascends to the pressure plate 420. When the container 230 is completed filling operation below the pressure plate 420, the piston rod 412 is lowered with respect to the hydraulic cylinder 410 and filled in the container 230 as described above. The piece ice 1 is pressed, and when the pressing is completed, the piston rod 412 is raised and returned to complete the pressing operation.

When the crimping operation is completed as described above, the rotating disc 210 continues to rotate intermittently, and the container 230, which has completed the crimping operation, is transported toward the discharge part 50 front.

In this case, when the rotation disc 210 is rotated again and the stop bar 212 is rotated, the contact sensor 214 installed on the support 10 detects this and sends the contact signal to the control unit 60. Accordingly, the control unit 60 stops the drive motor 240 to position the container 230 at the correct position under the discharge unit 50.

As a result, the control unit 60 supplies the hydraulic pressure to the discharge hydraulic cylinder 510 so that the piston rod 512 provided with the seal 520 moves forward, thereby removing the sea ice crystals 2 in the container 230. It is to be pushed toward the discharge hole 222 of the fixing plate 220, and when the discharge is completed as described above, the piston rod 512 is returned to complete the discharge operation.

At this time, the rotary disc 210 is continuously intermittently rotated until the operation stop button of the rotary disc 210 is pressed in the control unit 60, so that the rotating disc 210 of the rotary disc 210 is continuously When the piece of ice (1) is supplied into the container 230, the filling, pressing and discharging operations continue to be sequentially performed.

In addition, the operation of the components and drive motors and other necessary devices of all the stations described above are collectively controlled so that the control unit 60 can be linked to each other at the correct time.

The pressurized sea ice deicing device of the present invention, which is constructed and operated as described above, can automatically and precisely carry out sea ice that has been completed only by conventional piece ice by a series of mechanical continuous operations as a sea ice crystal with large crystal grains. This is an industrially useful design that can greatly improve the productivity and quality of sea ice.
The present invention has been described with reference to specific embodiments of the present invention, but it is apparent that various modifications and changes can be made as described above without departing from the technical spirit described in the claims of the present invention. Accordingly, the detailed description and the accompanying drawings of the present invention should not be construed as limiting the technical spirit of the present invention but merely as illustrative.

Compressed sea ice deicing device of the present invention can produce large ice crystals by compressing the sea ice which was completed by conventional piece ice without using fresh water, and can be produced with large ice crystals. There is an effect that can provide a compressed sea ice deicing device that can maintain fresh food, fresh fish, fish and shellfish for a long time.

In addition, the pressurized sea ice deicing device according to the present invention is capable of automatically producing slice ice automatically as ice crystals of sea ice by a series of mechanical continuous operations, thereby maximizing the manufacturing efficiency of sea ice and lowering the cost of products by sea water There is an effect that can greatly improve the productivity and quality of ice.

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Claims (8)

A support having a plurality of vertical frames integrally formed at both ends of the plate supporting the ground, a fixed plate fixed to an upper end of the vertical frame, and a contact sensor attached to an outer circumferential surface of the fixed plate; A rotating disc which is provided at the center of the support part and is continuously intermittently rotated in one direction by a predetermined angle at a time by a driving motor and a reducer which supplies rotational force to the rotating shaft, and a predetermined interval at an upper periphery of the rotating disc. A rotating part having a plurality of containers radially attached to each other and a stop bar attached to an outer circumferential surface of the rotating disc; A filling part having a piece ice hopper for filling piece ice in each container; A pressing part having a pressing plate for pressing the piece of ice filled in the container; And Comprising; the discharge portion having a seal for discharging the sea ice crystals in which the compacting operation is completed and pieces of ice are aggregated in the form of lumps; The filling part, the pressing part, and the discharge part are sequentially disposed while maintaining a constant distance from each other around the rotating disc, and the filling part, the pressing part, and each time the rotating disc is paused during intermittent rotation by a control unit. The discharge part starts working on the vessels located at each lower part, and when each part completes each work, the operation of starting the intermittent rotation of the rotating disc is continued, so that the filling, pressing and Compression sea ice deicing device, characterized in that configured to be a program control to sequentially discharge operation. The method of claim 1, wherein the rotating unit, Rotating disk by attaching a stop bar at predetermined intervals in the circumferential direction of the rotating disc and sending a contact signal detected by a contact sensor provided in the support unit to detect rotation of the stop bar to a control unit to control the rotation of the drive motor. Pressed sea ice deicing device, characterized in that configured to be intermittent rotation. The method of claim 1, wherein the filling unit, It is installed on the upper side of the support so that the container on the rotating disc is located below, An engaging signal detected by contacting the contact sensor of the support part by rotating the stop bar of the rotating part having a rotating screw which is operated whenever the rotating disc is paused during intermittent rotation by the control unit inside the crushing ice feeding hopper. Compression sea ice deicing device, characterized in that by inserting the flake ice into the container by rotating the rotating screw when generated. The method of claim 1, wherein the crimping portion, It is installed on the upper side of the support so that the container on the rotating disc is sequentially positioned while maintaining a constant distance from the filling portion, The control unit is provided with a pressure hydraulic cylinder for operating whenever the rotation disc is paused during the intermittent rotation, the pressure plate attached to the end of the piston rod of the pressure hydraulic cylinder is lowered to squeeze the ice cube into the container Compression sea ice deicing device configured to include a pressure plate detection sensor for detecting the position of the pressure plate to return to the pressure plate when the pressure is completed. The pressure plate detecting sensor of claim 4, A pressure plate falling detection sensor configured to generate a contact signal by contacting the first moving bar installed at one side of the piston rod in a fully lowered position; And Compression sea ice deicing device, characterized in that consisting of; pressure plate rise detection sensor for contacting the first moving bar in a fully raised position to generate the contact signal. The method of claim 1, wherein the discharge unit, While maintaining a constant distance from the crimping portion and sequentially installed on the upper side of the support so that the container on the rotating disc is located below, A discharge hydraulic cylinder is provided which is operated whenever the member disc is paused during the intermittent rotation by the control unit, and the discharge hydraulic cylinder is operated by the operation signal of the control unit, thereby leading to the piston rod of the discharge hydraulic cylinder. When the pusher attached to the moving forward is pushed to the discharge plate located under the container of the rotating disc and when the discharge operation is completed, including a pusher detecting sensor for detecting the position of the pusher to retreat back Pressed sea ice deicing device. The method of claim 6, wherein the close detection sensor of the discharge portion, A push-down falling detection sensor contacting at a position where the second moving bar installed on one side of the piston rod is completely lowered to generate a contact signal; And Compression sea ice deicing device, characterized in that consisting of; the second moving bar is in contact with the fully raised position to generate a contact signal rising sensor. The method of claim 6, wherein the discharge unit, Combining the upper side of the discharge plate, the grinding blade so as to crush the sea ice passing through the container by the pressure of the pusher; Compression sea ice ice making apparatus further comprises.

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