KR20110024722A - Freezing unit for ice making machine - Google Patents

Abstract

PURPOSE: A freezing unit for an ice maker is provided to improve the shaking efficiency by directly delivering the repetitive rocking motion to a water tray using a forward reverse motor. CONSTITUTION: A freezing unit for an ice maker comprises a cooling plate(1), a water dish(2), a fluctuation part(4), and an ice separation part(3). The cooling plate comprises an evaporation tube(12) connected to a refrigerating system and a cooling projection(11). A rocking member(43) is formed in the end part of a driving shaft of a drive motor(41).

Description

Ice Making Unit for Ice Maker {FREEZING UNIT FOR ICE MAKING MACHINE}

The present invention relates to an ice making unit that prevents iced ice from becoming transparent and cloudy (hereinafter, referred to as white clouding), and more particularly, cooling protrusions protruding from the lower surface of the cooling plate to the ice making water inside the water plate. In the ice making machine to immerse the to form a dome-shaped ice mass around the cooling projections, the ice mass in the cooling projections to improve the clouding phenomenon to produce a transparent and high value ice mass It relates to an ice making unit for an ice maker.

An ice maker is an apparatus for making ice by cooling supplied ice-making water. In recent years, ice makers are provided which can prevent clouding while freezing bubbles in ice-making water.

The conventional ice maker disclosed in Korean Patent No. 100272894 shown in FIG. 1 includes an ice maker body, an ice making unit, bubble removing means, and ice making completion detection means.

The ice maker body has an ice reservoir for storing ice made in the ice making unit. The compressor and the condenser are installed in the lower part of the ice reservoir. As shown, the ice making unit includes a water plate, a cooling plate, and an evaporation tube.

The ice plate is filled with ice making water, and a plurality of cooling protrusions immersed in the ice making water is installed on the lower surface of the cooling plate. One side of the water plate is provided with a turning means for discharging the ice-making water that is not frozen in the water plate by tilting the water plate.

The evaporator tube is installed on the top of the cold plate and is connected to the refrigeration system. A refrigerant flows into the evaporation tube, and the cooling plate and the cooling projection are cooled by heat exchange of the refrigerant. The bubble removing means removes bubbles in the ice-making water to prevent clouding from occurring during ice-making, and includes a rocking plate that vertically flows in the water plate, and a rocking motor for flowing the rocking plate. When the locking piece installed on the swinging motor lifts the locking pin of the swinging plate, the swinging plate moves and lifts and removes bubbles in the ice making water.

The de-icing completion detecting means includes a detecting switch on which a lever piece is installed and an operating piece installed on an attachment jig to which a swing motor is attached. When ice grows on the cooling projection and the rocking plate collides with the ice, the impact of the rocking plate is applied to the rocking motor through the engaging piece. At this time, the attachment jig rotates about the support shaft, and the operation piece provided on the attachment jig presses the lever piece to operate the detection switch.

The function of the conventional ice maker which has the said structure is demonstrated. When the ice making water flows into the water dish through the ice making water supply pipe and the cooling protrusion is immersed in the ice making water, the cooling water starts to freeze around the cooling protrusion cooled below the freezing point by heat exchange of the refrigerant flowing in the evaporating tube. At this time, the swinging plate which is immersed in the ice-making water while the swinging motor operates is rocked up and down. As a result, the ice making water swings up and down, bubbles in the ice making water are removed, and transparent ice grows around the cooling projection. When ice of a predetermined size grows around the cooling protrusion, the rocking plate collides with the ice, and its impact is transmitted to the rocking motor through the engaging piece. At this time, while the attachment jig with the swinging motor is rotated clockwise around the support shaft, the operation piece is pressed by the lever piece of the detection switch to detect the de-icing completion time. When the ice making is completed, the oscillation plate stops operation, the high temperature refrigerant discharged from the compressor is directly supplied to the evaporator tube without passing through the condenser, and the cooling projection is heated, and the water plate is inclined about the pivot axis by the pivot means. Thus, the generated ice is separated from the cooling projections and falls into the ice reservoir, and the ice making water remaining without freezing in the water dish is discharged to the sump along the drain guide plate.

In order to prevent clouding of the ice tray, a conventional ice maker is provided with a cam on one side of the water plate, and is driven by a motor as a motor, and rotates one end of the engaging piece at an up and down predetermined angle on one side of the bottom of the water plate by the axis. Since there is almost no swing force in the axial point portion and the water plate side farther than the axial point is swinging at many angles, there was a problem that the ice growth of the cooling protrusions immersed in the water plate is not partially improved. Therefore, a water plate swinging device in which the rocking of the water plate is evenly required is required.

 An object of the present invention is to provide an ice making unit that improves the conventional anti-clouding (swinging) means so that the entire water dish generates left and right swing forces, rather than a catching piece having the pivot of one side as the pivot point. There is a purpose.

In addition, the present invention is a rocking member for rocking the water plate is made of a relatively simple structure to be stably supported, as well as to provide an ice making unit that can continuously apply the rocking force to the water plate through the stationary motor rather than the eccentric cam The purpose is.

Another object of the present invention is to provide an ice making unit capable of continuously applying a rocking force at the bottom of the water plate, even if it is an eccentric rocking member for rocking the water plate.

In addition, an object of the present invention is to improve the transparency of the ice grown on the cooling projections by remarkably improving the turbidity in the ice-making water grown on the cooling projections repeatedly and constant fine.

The rocking device of the ice maker of the present invention for achieving the above object,

An evaporator tube connected to the refrigeration system, a cooling plate on which a cooling protrusion is immersed in the ice-making water supplied to the ice-making space, and an ice-making space located below the cooling plate and filled with ice-making water), A water plate formed with a supply path, a guide pin and a fixing pin, and a rocking portion formed at an end of the drive shaft of the drive motor so that the left and right repetitive turns are made by the reverse direction driving of the drive motor from below the water plate. An elastic member is installed between the rocking portion coupled through the ball and the guide pin of the water plate to absorb the vibration of the water plate during the left and right rocking of the rocking portion, and to rotate the water plate to defrost the driving motor. And a base frame having a pivoting eccentric member formed thereon and a hole formed therein so that the guide pin and the elastic members are positioned on the eccentric member. It is achieved by the ice part.

The rocking portion of the rocking device of the rocking device of the icemaker of the present invention for achieving the above object is preferably to form an eccentric cam so as to eccentrically contact the lower portion of the drive plate to the end of the drive shaft, the eccentric cam is a plurality of lower sides of the water plate in the longitudinal direction More preferably.

The present invention improves that the rocking member for rocking the water plate is stably supported as well as the repetitive left and right swings are directly transmitted to the water plate through the stationary motor, thereby providing a wear preventing member between the conventional cam device and the ice making tank. As a result, the swinging efficiency is improved and the breakage of the water plate due to friction is prevented. Therefore, durability can be improved and the ice making unit can smoothly shake even when used for a long time, thereby making it possible to implement an ice making unit capable of maintaining a constant quality of ice.

In addition, compared to the fluctuations caused by the eccentric cam on one side, the sinus fluctuation of the water plate according to the present invention is made to swing left and right at regular angles, so that both sides of the water plate are evenly shaken and bubbles are generated compared to the one side of the water plate as the axis. While reducing the ice growth rate of the cooling projections to improve the transparency can be produced ice.

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

2 is a perspective view showing an embodiment of an ice maker in which the present invention rocking device is implemented, and FIGS. 3A and 3B are perspective views of a rocking device showing another embodiment of the ice maker rocking device of the present invention.

 The rocking device of the icemaker of the present invention according to the drawings,

It consists of the cooling plate 1, the water plate 2, the ice-covering part 3, and the oscillation part 4 largely.

First, the cooling plate 1 is charged and installed on the upper surface of the predetermined plate-shaped structure is connected to the refrigeration system of the ice maker 12, the cooling is immersed in the ice-making water supplied to the ice-making space 21 to be described later The protrusion 11 is formed. Since the cooling plate of this type is known from Korean Patent Laid-Open Publication No. 10-2006-0036986, the description of the specific cooling plate is omitted.

The water plate 2 is located below the cooling plate 1, and forms an ice making space 21 filled with ice making water and a supply path 26 to which purified water is supplied at one side of the upper edge, and several positions outside thereof. The extension piece 22 is formed in the guide pin, and the fixing pin 24 fixed to the guide pin 23 and the moving part 3 to be mentioned later is formed so that the elastic member 33 mentioned later may be interposed.

Reference numeral 25 is a guide member for guiding the lifting and lowering operation of the water plate 2 is inserted into the guide pin 37 of the base frame 36 of the ice portion 3 to be described later.

The moving part 3 connects the eccentric member 32 on the axis of the drive motor 31, and horizontally installs the base frame 36 on the eccentric member 32, but at a predetermined position of the base frame 36. The guide pin 23 of the water plate 2 is positioned so as to correspond to the hole 34 to guide the lifting and lowering freely, but the elastic plate 33 is installed in the guide pin 23 so that the water plate 2 is elastic. The fixing pin 24 is fixed to the pipe hole 35 so that the lifting and lowering is made as the member 33 and the vibration is caused by the left and right swing of the water plate 2 when the swinging part 4 swings left and right. (33). In order to rotate the water plate 2 and to ice it, when the driving motor 31 rotates the eccentric member 32 provided on the shaft, the base frame 36 and the water connected to the eccentric member 32 are shown in FIG. The dish 2 is detached by turning downward integrally.

The swinging portion 4 is repeatedly rotated left and right by the forward and reverse driving of the driving motor 41 under the water plate 2, and the swinging member 43 is formed at the end of the driving shaft 42 of the driving motor 41. ) Is contacted repeatedly from left to right under the water plate (2).

The swinging member 43 of the swinging portion 4 may be an eccentric cam 45 which eccentrically contacts the water dish 2 below when the motor is one-way motor, and the eccentric cam 45 is formed of the water dish 2. It is also preferable to provide more than one in both sides of the longitudinal direction.

On the other hand, in such an ice maker rocking device, it is preferable to form an ice making completion detecting means for detecting the time of completion of ice making by detecting a change in the rocking distance of the base frame according to the size of the ice growing on the cooling projection (11). .

In addition, by detecting a change in the magnetic force according to the flow of the base frame, the ice growing on the cooling projection 11 is defrosted to reach a predetermined size.

Figures 4a, 4b of the accompanying drawings is a cross-sectional view of the operation of the icemaker rocking device of the present invention.

In the rocking operation of the present invention according to the drawings, the driving force is transmitted to the rocking member 43 by the driving motor 41, so that the rocking member 43 is a water plate with repetitive left and right swinging of the drive motor 41 which is a stationary motor. It swings (2) right and left at a certain angle.

At this time, the water plate 2 is absorbed by the elastic member 33 installed in the guide pin 23 of the predetermined position while being buffered between the ice portion 3 and the swinging force.

5A and 5B are cross-sectional views of another embodiment of the icemaker rocking device of the present invention, and FIGS. 6A and 6B are cross-sectional views of another embodiment of the ice maker rocking device of the present invention.

The rocking member 43 of the icemaker rocking device of the present invention according to the drawings is eccentric operation even when rotated in one direction rotation of the drive motor 41 by the eccentric cam 45 by raising and lowering the water plate 2 up and down Let's do it.

Similarly, the rocking force due to the lifting operation is absorbed and buffered by the elastic member 33.

In particular, a plurality of such eccentric cams 45 are provided below both sides of the water plate 2 in the longitudinal direction, so that the vertical movement of the water plate 2 can be made more complete.

7 is a cross-sectional view illustrating the ice-making action of the ice maker in which the rocking device of the ice maker of the present invention is implemented.

In the ice-making operation of the ice maker in which the rocking device of the present invention according to the drawings is implemented, the eccentric member 32 eccentrically connected to the shaft of the drive motor 31 is eccentrically rotated by rotating the water plate 2 on one side thereof. As it rotates, it is integrally fixed to the hole 35 of the base frame 36 connected to the shaft through the fixing pin 24 of the water plate 2, so that it moves downward in a right angle like the base frame 36. do. Since ice is grown in the cooling projections 11 of the cooling plate 1 by such an ice operation, the ice falls to the lower reservoir by a predetermined heating operation.

The assembly structure and rocking operation for this series of rocking of the present invention will grow the state of the ice grown in the cooling projection 11 more clear and clean.

That is, the purified water filled in the water plate 2 is the evaporation of the refrigerant in circulation in the evaporation tube 12 formed in the cooling plate 1 and the predetermined amount of water is supplied during the refrigeration cycle while the cooling projection 11 is immersed. The ice plate grows, but the water plate 2 swings, so the cooling protrusion 11 is immersed, but the purified water causes considerable shaking due to the rocking water plate 2, causing the cooling protrusion to grow at the cooling protrusion 11. The purified water repeatedly forms contact with (11) to form ice, resulting in improved transparency.

1 is a view of an ice maker in which a conventional ice maker is implemented.

Figure 2 is a perspective view showing an embodiment of an ice maker in which the present invention rocking device is implemented,

Figure 3a, 3b is a perspective view of a rocking device showing another embodiment of the ice maker rocking device of the present invention,

Figure 5a, 5b is a cross-sectional view of the action of another embodiment of the icemaker rocking device of the present invention,

Figure 6a, 6b is a cross-sectional view of the working of another embodiment of the icemaker rocking device of the present invention,

7 is a cross-sectional view illustrating the ice-making action of the ice maker in which the rocking device of the ice maker of the present invention is implemented.

Claims (3)

In the rocking device of the ice maker, An evaporating tube 12 connected to the refrigeration system, the cooling plate 1 having a cooling protrusion 11 immersed in the ice making water supplied to the ice making space 21 on a lower surface thereof; A water plate (2) positioned below the cooling plate (1) and forming an ice making space (21), a supply passage (26), a guide pin (23), and a fixing pin (24) filled with ice making water; The rocking member 43 is formed at the end of the drive shaft 42 of the drive motor 41 so that the left and right repetitive turning of the drive motor 41 is performed under the water plate 2. Oscillating portion 4 is coupled through the fixing hole 44 below; And The elastic member 33 is installed between the guide pin 23 of the water plate 2 so that the vibration of the water plate 2 is absorbed when the left and right swings of the rocking part 4 are absorbed, and the water plate ( 2) a driving motor 31 is formed to swing and defrost, and a rotating eccentric member 32 is formed on the shaft, and the elastic member which is supported by the guide pin 22 on the eccentric member 32 ( 33) and an ice-making unit (3) consisting of a base frame (36) formed with holes (34, 35) so that the fixing pins (24) are located. The method of claim 1, The swinging portion (4) is rocking device of the ice maker, characterized in that to form an eccentric cam (45) to eccentrically contact the water plate (2) below the end of the drive shaft (42). The method of claim 2, The eccentric cam (45) is rocking device of the ice maker, characterized in that located in a plurality in the lower side of the longitudinal direction of the water plate (2).

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