KR101488112B1 - The dual of the frozen ice making and ice Machine - Google Patents

Abstract

The present invention can rapidly produce ice even when the external temperature rises to a high temperature and at the same time drastically shortens the time required for ice-making, and also enables ice-making and freezing storage for facilitating storage of ice in a low temperature for a long time The present invention relates to an ice-
A water supply unit 200 including a solenoid valve 210 so that the purified water can be guided and supplied to the water storage unit 300 in a predetermined amount and water supplied from the water supply unit 200 in a predetermined amount, A low-level sensor 320 is provided so as to be filled in the storage container 310, and is integrally formed with the storage container 310 so as to be movable upward, downward, A water storage portion 300 including a pedestal 330 having a long hole 331 formed therein and a pedestal 330 of the water storage portion 300 are fixed in a predetermined, (500) for cooling the water filled in the storage container (310), and an ice maker (500) for moving the ice container (500) A freezing portion 600 including a high water level sensor 610, It is configured to include a payment 200, a water compartment 300, a conveyance base 400, the bingbu 500, a controller 700 for controlling the operation of the refrigeration unit 600.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to ice making machines,

The present invention relates to an icemaker in which ice storage and freeze storage are binarized. More particularly, the present invention can rapidly produce ice even in a seasonal factor in which the external temperature rises to a high temperature, and at the same time, The ice maker is provided with an ice maker and an ice maker.

An ice maker is an apparatus for producing ice, and is provided in a refrigerator or an ice water purifier to rapidly produce ice.

Such a conventional ice maker can not produce ice quickly in the summer when a long time is required for ice making and thus it is not easy to use ice. In addition, since it takes a long time for ice making, It is.

In addition, various methods for shortening the time required for ice-making have been sought, but they have been structurally complicated, and the scale has become larger than necessary, and thus it has been difficult to use it in a refrigerator or an ice water purifier.

As a prior art related to the above conventional ice maker, Korean Patent Laid-Open No. 10-2010-0057216 (entitled refrigerator), Korean Patent Laid-Open No. 10-2012-0107676 (entitled cold water and ice generator) And Patent Registration No. 10-1231043 entitled " Water purifier with ice-making device ".

Accordingly, the present invention has been devised to eliminate the above-mentioned problems, and it is possible to drastically shorten the time required for the icemaking so that quick deicing can be performed so that there is no inconvenience of using ice in a season or a place where a large amount of ice is required The present invention is directed to an ice maker that can reduce electrical energy by shortening the time required for ice making, as well as an ice maker that is free from ice.

It is another object of the present invention to provide a refrigerator which can reduce the energy required for freezing and storing ice in a storage room to supply cold air to ice making and freezing, The present invention also provides an ice maker in which ice making and freezing can be further shortened.

An ice maker (100) in which ice making and freeze storage are binarized to realize the above object,

A water supply unit 200 including a solenoid valve 210 so that the purified water can be guided and supplied to the water storage unit 300 in a predetermined amount and water supplied from the water supply unit 200 in a predetermined amount, A low-level sensor 320 is provided so as to be filled in the storage container 310, and is integrally formed with the storage container 310 so as to be movable upward, downward, A water storage portion 300 including a pedestal 330 having a long hole 331 formed therein and a pedestal 330 of the water storage portion 300 are fixed in a predetermined, (500) comprising first and second thermoelectric elements (530, 550) for cooling the water filled in the storage container (310), and a second cooling unit A thermoelectric element (not shown) which keeps the ice (900) A freezing unit 600 including a freezing unit 600 for detecting the amount of ice filled in the storage 810 and a full ice level sensor 650 for checking the amount of ice filled in the water storage unit 810, 400, the ice-making unit 500, and the freezing unit 600 according to the present invention.

The pedestal conveyance unit 400 is operated by a limit sensor 430 and a control unit 700 electrically connected to the limit sensor 430. The pedestal conveyance unit 400 includes a lifting rack gear 410 for lifting and lowering the pedestal 330 for a predetermined period, A pair of left and right rack gears 420 and a pair of left and right pinion gears 421 are gear-engaged with each other, And a driving motor 412 and 422 are fixedly coupled to the pinion gears 411 and 421. A lifting rack gear 410 is fixed to the lower end of each of the lifting rack gears 410 in a slot 331 of a pedestal And a separation preventing block 413 that prevents the lifting rack gear 410 and the pedestal 330 from being separated when the lifting rack gear 410 is lifted.

The ice making part 500 further includes a cooling exhaust fan 510 and a radiating fin 520 fastened to and fixed to the exhaust fan 510 at one side of the exhaust fan 510 and a radiating fin 520, A first thermoelectric conversion element 530 and a second thermoelectric conversion element 530. The first thermoelectric conversion element 530 is fixed to the first thermoelectric conversion element 530 by a resin 590. The first thermoelectric conversion element 530 is spaced apart from the first thermoelectric conversion element 530, The second thermoelectric element 550 and the first thermoelectric element 530 and the second thermoelectric element 550 are adhered and fixed by the thermally conductive adhesive resin 590, A cooling block 540 having a three-dimensional structure in a trapezoidal shape that is reduced in size toward the second thermoelectric element so as to prevent loss of cool air when the thermoelectric element 550 is transferred to the second thermoelectric element, And the water contained in the storage container 310 is partially adhered to the storage container 310, And an immersion pin 560 for contacting and immersing the body 800, and is mounted and fixed to one side of the body 800 in the upper direction.

The freezing unit 600 includes a cooling exhaust fan 610 and a radiating fin 620 fastened and fixed to an exhaust fan 610 at one side of the exhaust fan 610 and a radiating fin 620, And a cooling block 640 having a trapezoidal shape that is adhered and fixed to the thermoelectric element 630 for freeze keeping with a thermally conductive adhesive resin 590 and fixed to the thermoelectric element 630 for freeze- And is mounted and fixed to the lower side surface of the main body 800. [

The freezing unit 600 further includes a full ice level sensor 650 for checking the amount of ice filled in the freezing chamber 810 provided at the lower end of the main body 800.

The thermoelectric element 630 for freeze storage of the freezing portion 600 and the trapezoidal cooling block 640 are bonded and fixed so that the wide surface of the cooling block 640 faces the direction of the reservoir 810 .

The ice making machine provided with the ice making and freezing storage provided in the present invention minimizes the loss of cool air required for the ice making so that the ice making can be performed quickly and the use thereof can be provided easily, Can be frozen and stored for a long time by a separate freezing energy.

1 is a front view showing a preferred embodiment of the present invention;
2 is a side view showing a preferred embodiment of the present invention.
FIG. 3 is an exploded perspective view showing the main part of the ice making part of the ice-
FIG. 4 is a perspective view showing a main part of a conveying unit of a pedestal of the ice-
FIG. 5 is a diagram showing an operation state diagram briefly showing an operation state of the conveyance unit according to a preferred embodiment of the present invention.
FIG. 6 is an operating state diagram showing a state in which ice making is performed during an operating state diagram according to a preferred embodiment of the present invention. FIG.
FIG. 7 is a view showing an operation state diagram illustrating a state after ice making in the operation state diagram according to a preferred embodiment of the present invention
FIG. 8 is an operation state diagram illustrating a state in which ice is dehydrated and water is supplied during an operation state diagram according to a preferred embodiment of the present invention. FIG.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments.

1 and 2, the ice-maker 100 having the ice-making and freezer storage units provided in the present invention is provided with a solenoid valve (not shown) for supplying purified water to the water storage unit 300 in a predetermined amount A low water level sensor 320 is provided to fill the water in the storage container 310 with a predetermined amount of water guided and supplied from the water supply unit 200, And a pedestal 330 having elongated holes 331 formed in the forward and backward directions at left and right ends so as to be movable in an upward, A pedestal conveyance part 400 for moving the pedestal 330 of the water storage part 300 to a predetermined position in a selected direction before, after, after, and after a predetermined interval; The first and second thermoelectric elements 530 and 550 A thermoelectric element 630 for keeping the ice 900 dehydrated in the ice making part 500 at a predetermined temperature or lower so as not to melt the ice and a full ice check for checking the amount of ice filled in the ice storage part 810, The operation of the water supply unit 200, the water storage unit 300, the pedestal conveyance unit 400, the ice-making unit 500, and the freezing unit 600, And a control unit 700 for controlling the control unit.

2 and 4 to 5, the pedestal conveyance unit 400 is operated by a limit sensor 430 and a control unit 700 electrically connected to the limit sensor 430. When the pedestal conveyance unit 400 is elevated and lowered And a pinion gear 421 and a pinion gear 421. The pinion gear 421 and the pinion gear 421 are rotatably supported by a rack gear 420 and a pinion gear 421, And a pair of left and right gears are gear-engaged. Drive motors 412 and 422 are fixedly coupled to the respective pinions 411 and 421. At the lower end of each of the rack gears 410, And a separation preventing block 413 for preventing the raising and lowering rack gear 410 and the pedestal 330 from being separated when the slider 410 is inserted into the slot 331 of the pedestal.

5, when the ice making is to be performed, the lifting rack and the pinion gears 410 and 411 operate as shown in (A), and the pedestal 330 is moved to the position where the immersion pin 560 The rack and pinion gears 410 and 411 operate as shown in FIG. 2 (b) so that the rack 330 and the pinion gears 420 and 421 So that the pedestal is seated on the upper surface of the rack gear 420. [

When the pedestal is seated as described above, the driving motor 422 operates to retract the pedestal to the water supply part 200 as shown in (c), and the water storage container 310 is filled with water. At the same time, the second thermoelectric element 550 of the ice-making part 500 is reversed from cold to hot, and the ice 900 and the immersion pin 560 are separated by heat.

1 and 2, the ice-making unit 500 includes a cooling exhaust fan 510, a radiating fin 520 fastened to the exhaust fan 510 at one side of the exhaust fan 510, And at least one first thermoelectric element 530 which is adhered and fixed to the heat radiating fin 520 by a thermally conductive adhesive resin 590 and a second thermoelectric element 530 which is disposed at a certain distance from the first thermoelectric element 530, The first thermoelectric element 530 and the second thermoelectric element 550 are adhered and fixed to each other with a thermally conductive adhesive resin 590 at a ratio of 0.2 to 0.7 of the thickness of the thermoelectric element 530 A cooling block 540 having a trapezoidal three-dimensional structure which is reduced in size toward the second thermoelectric element so as to prevent loss of cool air when the cool air generated in the first thermoelectric element is transferred to the second thermoelectric element, And a thermally conductive adhesive resin 590 with the second thermoelectric element 550, The mouth, and comprises an immersion pin 560 of ice in contact with the water filled in the storage container 310, and is fixed mounted on one side of the upper direction of the main body (800).

And the thermally conductive adhesive resin 590 adheres and fixes the thermally conductive adhesive resin 590 so that the defective fastening of the bolt, which may be caused by shrinkage and relaxation, can be prevented in the process of repeating the thermoelectric element in the cold and on state.

That is, if the thermoelectric element is repeatedly cooled and turned on, the cooling block integrated with the thermoelectric element by the bolt (not shown) is separated from the thermoelectric element, thereby causing defects that must be maintained from time to time Can be blocked.

Particularly, it relates to the structure of the first thermoelectric element 530, the cooling block 540 and the second thermoelectric element 550 as shown in FIG. 3, and the cool air generated in the first thermoelectric element is cooled The cool air is prevented from being dispersed to the outside in the process of being transferred to the block and the cool air is converged in the direction of the second thermoelectric element having a relatively small size as compared with the first thermoelectric element.

It is also very important that two thermoelectric elements are arranged. However, since the shape of the cooling block connecting the two thermoelectric elements is formed in a downwardly rigid shape in the inward direction, it can be transmitted in the direction of the second thermoelectric element without loss of cool air.

As a result, it is possible to perform quick deicing as well as deicing in summer.

2 and 6 to 8, the freezing unit 600 includes a cooling exhaust fan 610 and a radiating fin 610 fixedly coupled to the exhaust fan 610 at one side of the exhaust fan 610, And at least one thermoelectric element 630 for freeze-holding which is adhered and fixed to the heat dissipation fin 620 and the heat dissipation fin 620 with a thermally conductive adhesive resin, and a thermally conductive adhesive resin 590 with the thermoelectric element 630 for freeze- And a cooling block 640 having a trapezoidal shape of a three-dimensional structure, and is mounted and fixed to the lower side surface of the main body 800.

The freezing unit 600 further includes a full ice level sensor 650 for checking the amount of ice filled in the freezing chamber 810 provided at the inner lower end of the main body 800, The control unit stops the supply of the water, and at the same time, the ice-making is also stopped. However, the freezing section operates continuously to prevent the ice stored in the storage room from melting.

The thermoelectric element 630 for freeze storage of the freezing portion 600 and the trapezoidal cooling block 640 are bonded and fixed so that the wide surface of the cooling block 640 faces the direction of the reservoir 810 do.

The reason why the direction of the cooling block 640 in the freezing portion 600 is directed toward the storage space is that the energy required for the freezing is not required because of the already de-iced state, will be. As a result, the wide surface faces toward the reservoir so that the cold air can be transmitted widely.

The main feature of the present invention having the above-described structure is that ice can be quickly dehydrated in summer by separately using the energy consumed for storing ice and deicing ice.

The ice making machine 100 having the ice making and freezing storage of the present invention will be described with reference to the drawings. First, water is supplied from the water supplying part 200 to the water storing part 300 as shown in FIG. The amount of water to be supplied is determined by the low-level sensor 320 and the solenoid valve 210. When the water is filled in a predetermined amount, the front and rear drive motors 422 and the front and rear racks, The gears 420 and 421 operate to advance the pedestal 300 to a position where the immersion pins 560 are present.

When the pedestal 330 is moved to a position where the immersion pin 560 is located, the lifting rack and the pinion gears 410 and 411, which are connected to the lifting drive motor 412 as shown in FIG. 6, So that the immersion pins 560 are received in the storage container 310 to perform the ice making.

When the ice-making is completed, as shown in FIG. 7, the lifting rack and the pinion gears 410 and 411 operate to lower the pedestal so that the pedestal can be seated in the rack gear 420 for forward and backward movement.

When the pedestal 330 is seated, the rack and the pinion gears 420 and 421 operate to move the pedestal backward and the second thermoelectric element 550 reverses its direction from cold to ice so that ice is separated from the immersion pin 560 . At the same time, when water is filled in the storage container, the control unit repeats the above-described series of operations to produce steady ice.

The ice-maker having the ice-making and frozen storage of the present invention described above can be applied variously, and various sensors according to automation can be additionally constructed.

100: Ice maker 200: Water supply part
210: Solenoid valve 220: Water inlet
300: water supply part 310: storage container
320: low-level sensor 330: pedestal
331: Slot 400: Pedestal transmission
410: lifting rack gear 411: lifting pinion gear
412, 422: Driving motor 413:
420: forward and reverse reverse gears 421: forward and reverse pinion gears
430: limit sensor 500:
510: exhaust fan 520: radiator pin
530: first thermoelectric element 540: cooling block
550: second thermoelectric element 560: immersion pin
590: Adhesive resin 600:
610: exhaust fan 620: radiating fin
630: thermoelectric element 640: cooling block
650: full ice level sensor 700:
800: main body 810:
900: Ice

Claims (6)

A water supply unit 200 including a solenoid valve 210 so that purified water can be guided and supplied to the water storage unit 300 in a predetermined amount;
The low water level sensor 320 is provided so that the water guided and supplied by the water supply unit 200 can be filled in the storage container 310 in a predetermined amount and is integrally formed with the storage container 310, A water storage part 300 including a pedestal 330 having a long hole 331 formed in the forward and backward directions at the left and right ends so as to be moved;
A pedestal conveying part 400 for moving the pedestal 330 of the water containing part 300 to a predetermined position in a selected direction before, after, after, and after a certain interval;
A ice making part 500 including first and second thermoelectric elements 530 and 550 so as to cool the water filled in the storage container 310;
A thermoelectric element 630 for keeping the ice 900 dehydrated in the ice making part 500 below a predetermined temperature so as not to melt and a full ice level sensor 650 for checking the amount of ice filled in the ice storage 810 A freezing part 600 constituted by the refrigerating device 600;
A controller 700 for controlling operations of the water supply unit 200, the water storage unit 300, the pedestal conveyance unit 400, the ice-making unit 500, and the freezing unit 600;
Wherein the ice-making and freezing storage are divided into two.
The method according to claim 1,
The pedestal conveyance unit 400 is operated by a limit sensor 430 and a control unit 700 electrically connected to the limit sensor 430. The pedestal conveyance unit 400 includes a lifting rack gear 410 for lifting and lowering the pedestal 330, A pair of left and right rack gears 420 and a pair of left and right pinion gears 421 are gear engaged with each other, A driving motor 412 and a driving motor 422 are fixed to the pinions 411 and 421 and a lifting rack gear 410 is inserted into a long hole 331 of a pedestal at a lower end of each of the lifting rack gears 410 And an escape prevention block (413) for preventing the lifting rack gear (410) and the pedestal (330) from being separated from each other.
The method according to claim 1,
The ice-making part (500)
A cooling exhaust fan 510;
A radiating fin 520 fastened to the exhaust fan 510 at one side of the exhaust fan 510; And
At least one first thermoelectric element (530) adhered and fixed to the radiating fin (520) by a thermally conductive adhesive resin (590); Wow,
A second thermoelectric element 550 disposed at a predetermined distance from the first thermoelectric element 530 and having a size ranging from 0.2 to 0.7 of the first thermoelectric element 530;
The first thermoelectric element 530 and the second thermoelectric element 550 are adhered and fixed by the thermally conductive adhesive resin 590. When the cool air generated in the first thermoelectric element is transferred to the second thermoelectric element, A cooling block 540 having a three-dimensional trapezoid shape that is reduced in size toward the second thermoelectric element so as to prevent the thermoelectric element from being lost;
An immersion pin 560 which is adhered and fixed to the second thermoelectric element 550 by a thermally conductive adhesive resin 590 and which is partly inserted into the storage container 310 to be in contact with the water filled in the storage container 310;
And is mounted and fixed to one side of an upper side of the main body 800. The ice making machine according to claim 1,
The method according to claim 1,
The freezing unit 600 may include:
A cooling exhaust fan 610;
A radiating fin 620 fastened to the exhaust fan 610 at one side of the exhaust fan 610; And
At least one thermoelectric element (630) for freeze-holding which is adhered and fixed to the radiating fin (620) with a thermally conductive adhesive resin; Wow,
A cooling block 640 which is fixed to the thermoelectric element 630 for freeze keeping by a thermally conductive adhesive resin 590 and has a trapezoidal shape of a three-dimensional structure;
And is mounted and fixed to a lower side surface of the main body 800. The ice maker according to claim 1,
5. The method of claim 4,
The freezing unit 600 further includes a ice-making confirmation sensor 650 for confirming the amount of ice filled in the storage 810 provided at the inner lower end of the body 800. [ This dual ice machine.
5. The method of claim 4,
The adhesive fixing direction of the thermoelectric element 630 for freeze storage and the trapezoidal cooling block 640 of the freezing part 600 is adhered and fixed such that the wide surface of the cooling block 640 faces the direction of the reservoir 810 Wherein the freezing and freezing storage are two-dimensionally divided.

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