KR101118843B1 - A drum type machine for making ice - Google Patents

Abstract

The present invention relates to an ice making device, comprising: a cooling drum in which a refrigerant is vaporized to form ice on a surface thereof, and a refrigerant circulator installed in the cooling drum to inject and discharge the refrigerant into the cooling drum; The refrigerant circulator is fixedly installed in the cooling drum and rotates together with the cooling drum, and a fixing part which is disposed inside the rotating part and which is fixed without being rotated to supply and recover gas; The rotating part is composed of a housing pack fixed to a cooling drum and a rotating slider, and two bearings for supporting the rotating part while freely rotating the rotating part with respect to the fixing part; The fixed part is supplied with a refrigerant supply pipe for injecting refrigerant into the cooling drum, a refrigerant recovery pipe inserted into the refrigerant supply pipe to recover the refrigerant in the cooling drum, and installed outside the refrigerant supply pipe, and a rotary slider A fixed slider for contacting in an airtight state, a press holder coupled to the outside of the coolant supply pipe to push the fixed slider to the airtight state with respect to the coolant supply pipe, and one or more gases coupled to the front end of the coolant supply pipe An injection nozzle and a tip cap coupled to an outer side of the gas injection nozzle inserted into the refrigerant drum to allow a plurality of gas injection nozzles to be kept in an airtight state. The drum type ice making device of the present invention having such a structure can simplify the structure of the refrigerant circulator for supplying the refrigerant into the cooling drum, and in particular, the refrigerant injection nozzle body has a surge space for temporarily storing the refrigerant therein. In addition, the surface of the nozzle body has an oval shape, and a plurality of small diameter refrigerant injection holes connected to the surge space can be formed on the outer surface of the nozzle body on the elliptical surface so that the refrigerant can be efficiently injected into the cooling drum. You can get the effect.

Cooling drum, ice maker, cooling circulator, rotary support shaft, refrigerant spray nozzle

Description

Drum type ice machine {A drum type machine for making ice}

The present invention relates to an ice making apparatus for making ice by freezing water, and more particularly, to a drum ice making apparatus in which a cooler for making ice is formed in a drum shape and injecting refrigerant into the cooling drum to generate ice on the surface of the cooling drum. will be.

In general, ice makers which artificially freeze water to obtain ice have a type of crushed ice and a type of powdered ice such as snow.

Depending on the type of ice making, there is a type in which water is put into a case and frozen as it is, or a drum type for obtaining powdered ice.

Among them, the drum type ice maker cools the cooling drum 101 by injecting a coolant into the cooling drum 101 having an empty space, as shown in FIG. 5, and partially cools the cooling drum 101. When the cooling drum 101 is rotated by using the drive motor 103 and the power transmission means 104 in the state of the submerged container 102, ice is frozen on the surface of the cooling drum 101, and the ice is frozen. Scraping off with the knife 105 causes the powdered ice 106 such as snow to fall down, which is to be stored in a reservoir 107 disposed below.

On the other hand, such a drum-type ice maker generally has one sidewall 109a of the cooling drum 101 supported on the support frame 108, as shown in FIG. 6, for injecting refrigerant into the cooling drum 101. As shown in FIG. From the refrigerant circulator 110 is inserted.

However, in the conventional drum-type ice maker, since the refrigerant circulator 109 forms an internal rotation support shaft of the cooling drum 101, the refrigerant circulator 110 extends from one side wall 109a to the opposite side wall 109b. It is installed.

On the other hand, the refrigerant circulator 110 is installed to cool the cooling drum 101 by injecting the refrigerant into the cooling drum 101, the used refrigerant is to recover, the center of rotation of the cooling drum 101 It is difficult to match with.

Therefore, when the refrigerant circulator 110 extends to both side walls 109a and 109b as described above, the center of rotation of the cooling drum and the center of rotation of the refrigerant circulator 110 do not coincide with each other. There is a problem that a bearing or the like provided at the supporting points of both side walls 109a and 109b is easily broken.

In order to solve this problem, the "open flake ice deicing device" of 10-0470841 has been proposed, in which the refrigerant circulator 110 is inserted from one side wall without the side walls 109a and 109b. Then, the other front end is not supported in the cooling drum 101, but merely forms a free end.

As such, when one end of the refrigerant circulator 110 forms a free end, the center of rotation of the refrigerant circulator 110 does not have to coincide with the center of rotation of the cooling drum 101. There is no problem that the bearings are easily broken.

However, in the above-described invention, the support means for supporting the refrigerant circulator 110 so as to be rotatable on one side wall 109a of the cooling drum is not perfect, and the refrigerant is injected into the cooling drum 101 although its structure is complicated. There is a problem that can not block completely.

In addition, since the nozzle 111 installed at the tip of the refrigerant circulator 110 is made of a thin pipe made of a material such as copper, it is impossible to inject the refrigerant finely. It is difficult to produce water as a dry ice powder because it cannot be lowered to cryogenic temperatures below 35 ° C.

Moreover, if the temperature of the cooling drum 101 is not cooled to the ultra-low temperature as described above, there is a problem that it is difficult to make the liquid mixed with water and other substances such as milk or salt into powder ice.

In addition, in the conventional refrigerant circulator 110 as in the present invention, since the refrigerant injected from the nozzle 111 is injected only in a predetermined direction, the refrigerant injected perpendicular to the surface of the cooling drum 101 is drum 101. Since it is reflected from the inner surface of the recovery immediately, the cooling jet gas is difficult to be delivered to the cooling drum 101 in the entire surface has a disadvantage of low cooling hydration.

In addition, when the refrigerant is injected into the cooling drum 101, the lubrication oil of the compressor compressing the refrigerant is mixed with the refrigerant and mixed together. When the refrigerant is injected into the cooling drum, the compressor is injected into the surface of the cooling drum 101. The lubricating oil of the sedimentation not only lowers the cooling effect of the cooling drum 101, but also causes a phenomenon that the compressor lacks lubricating oil and overheats and wears.

In addition, in the apparatus according to the present invention, in order to provide a space required for the refrigerant to evaporate, the length of the capillary supply pipe for supplying the refrigerant is increased to secure an internal volume thereof. In order to achieve this, there are inconveniences of winding a lot of thin pipes in the refrigerant circulator, and there is a problem that its manufacture and maintenance are not easy.

On the other hand, as a way to solve this problem, there is a "drum-type ice making device" of the Patent Registration No. 10-878589 registered by the inventor of the present invention, in which a separate auxiliary drum is installed between the refrigerant circulation and the cooling drum. In this case, the refrigerant is temporarily collected in the auxiliary drum to make the refrigerant uniform, and then sprayed. However, the auxiliary drum has various problems such as complicated structure, troublesome operation, and large volume.

Accordingly, the present invention solves the conventional problems as described above, simplifying the structure of the refrigerant circulator for injecting and discharging the refrigerant into the cooling drum, and strengthening the support structure for supporting the refrigerant circulator in the cooling drum. It is an object of the present invention to provide a drum type ice making device which can further increase the refrigerant effect by finely injecting a coolant and can easily remove and recover the compressor lubricating oil flowing into the cooling drum together with the coolant.

Drum-type ice making device of the present invention for achieving the above object is made of a drum-like cooling drum that is cooled by a refrigerant circulated and supplied inside while rotating in contact with the water-filled head to freeze the thin ice on the circumferential surface And a coolant circulator inserted into the cooling drum to inject and discharge the coolant into the cooling drum; The refrigerant circulator is inserted at one side of the cooling drum and extends only to the middle without being connected to the opposite side, and the leading end thereof is at the free end; In the drum-type powder ice ice making apparatus comprising a rotating part fixed to the cooling drum and rotating together with the cooling drum, and a fixing part which is disposed inside the rotating part and is fixed without being rotated. ; The rotating part comprises a housing pack fixed to the cooling drum, a rotating slider, and two bearings for supporting the rotating part while freely rotating the rotating part with respect to the fixing part; The fixed part is supplied with a refrigerant supply pipe for injecting refrigerant into the cooling drum, a refrigerant recovery pipe inserted into the refrigerant supply pipe to recover the refrigerant in the cooling drum, and installed outside the refrigerant supply pipe, and a rotary slider A fixed slider for contacting in an airtight state, a press holder coupled to the outside of the refrigerant supply pipe to push the fixed slider in a hermetically sealed state to the refrigerant supply pipe, and one or more coupled to the front end of the refrigerant supply pipe A coolant injection nozzle and a tip cap coupled to an outer side of the coolant injection nozzle inserted into the coolant drum to maintain a hermetic state of the plurality of coolant injection nozzles.

In addition, the body of the refrigerant injection nozzle has a surge space for temporarily storing the refrigerant therein, the surface of the nozzle body is made of an oval, a plurality of diameters connected to the surge space on the outer surface of the nozzle body of the elliptical surface It has a structure with small refrigerant injection holes and is made of stainless steel.

In addition, it has a structure having a plate-like net having a fine mesh to block the inflow of foreign matter at the inlet of the refrigerant injection hole of the refrigerant injection nozzle.

The drum-type ice maker of the present invention having such a structure can firmly support the refrigerant circulator for supplying the refrigerant into the cooling drum with a simple structure in the cooling drum, the refrigerant supply pipe for supplying the refrigerant, and the rotating cooling drum. It is possible to simplify the structure of the coolant circulator for supplying the coolant to the inside of the cooling drum and preventing the coolant from leaking in between.

In addition, since the refrigerant injection nozzle according to the present invention can be made of stainless steel, the diameter of the refrigerant injection hole can be processed to a minimum size, thereby effectively injecting the refrigerant into the cooling drum.

In addition, the drum-type ice maker according to the present invention is to reduce the problem that the cooling effect of the cooling drum is reduced due to the lubricating oil by lubricating oil of the compressor flowing into the cooling drum with the refrigerant is recovered together with the refrigerant. In addition, it is possible to prevent problems caused by lack of lubricant of the compressor.

Hereinafter, with reference to the accompanying drawings, the present invention will be described.

1 is an exploded perspective view showing a cooling drum structure of a drum-type ice maker according to the present invention and a structure of a refrigerant circulator for injecting and recovering refrigerant into the cooling drum, and FIG. 2 is a coupling to a cooling drum of the drum-type ice maker according to the present invention. 3 is a sectional perspective view of a refrigerant injection nozzle installed in a refrigerant circulator of a drum ice maker according to the present invention, and FIG. 4 is an enlarged sectional view of part “C” of FIG. 2.

As shown in these figures, the drum-type ice maker according to the present invention is provided with a cooling drum (10) for freezing ice on the surface while being supplied with a coolant, and inserted into the cooling drum (10) to provide a cooling drum (10). It consists of a refrigerant circulator 20 for injecting and discharging the refrigerant into.

The cooling drum 10 is provided with a cylindrical case 11 and a side wall 13 having a rotating shaft 12 at one end of the case 11, and inserting the refrigerant circulator 20 at the other end. A slider wall 15 having an installation hole 14 for installation is installed, and the inside of the case 11 forms an empty space.

The cooling drum 10 is in contact with the surface of the cooling drum 10 as it rotates in contact with the accompanying (see background art, not shown) in a state cooled by the refrigerant supplied by the refrigerant circulator 20. As the water freezes, it creates ice.

Meanwhile, the refrigerant circulator 20 is fixed to the cooling drum 10 and rotates together with the cooling drum 10, and is disposed inside the rotating unit 30 while being fixed without rotating. It consists of a fixed portion 40 for supplying and recovering.

The rotating part 30 is inserted into the housing pack 31 inserted into the installation hole 14 formed in the side wall 15 of the cooling drum 10, and at the distal end of the fixing part 40 inside the housing pack 31. Combined rotary slider 32 and two bearings 33 installed side by side to support the rotating part of the fixing part 40 while supporting the rotating part 30 so as to rotate freely with respect to the fixing part 40 Is done.

Here, the blocking plate 34 is installed on the housing pack 31 and the bearing 33 to prevent the inflow of foreign matters, and a support frame for supporting the cooling drum 10 on the blocking plate 34 (not shown). Is connected).

Meanwhile, the fixing part 40 is inserted into the refrigerant supply pipe 41 for injecting the refrigerant into the cooling drum 10 and the refrigerant supply pipe 41 to recover the refrigerant in the cooling drum 10. A refrigerant recovery pipe 42, a refrigerant supply passage 43 formed between the refrigerant supply pipe 41 and the refrigerant recovery pipe 42, and installed outside the refrigerant supply pipe 41 to rotate while maintaining an airtight state. A fixed slider 44 which is in contact with the slider 32 so as to be rotatable relative to the slider 32, and coupled to the outside of the coolant supply pipe 41 to couple the fixed slider 44 in an airtight state with respect to the coolant supply pipe 41. And a press holder 45 for supporting the fixed slider 44 not to be pushed backwards, one or more refrigerant injection nozzles 46 coupled to each other at regular intervals in the middle of the refrigerant supply pipe 41, and , Of the refrigerant supply pipe 41 The end cap 47 is provided on the side of the refrigerant injection nozzle 46 installed at the end to couple the plurality of refrigerant injection nozzles 46 to maintain an airtight state.
In the above, both contact surfaces s where the rotary slider 32 of the rotary part 30 and the fixed slider 44 of the fixed part 40 meet each other are surface mirrored and slide each other through these contact surfaces. Even if it can rotate, the close contact force of these contact surfaces s prevents the refrigerant gas from passing through the contact surfaces s.

An injection holder 48a coupled with an injection nipple 48 for injecting a coolant is connected to an inlet end of the coolant supply pipe 41, and a discharge nipple for discharging the coolant to an outlet end of the coolant recovery pipe 42. A discharge holder 49a to which 49 is coupled is installed.

In addition, the O-ring 35 is installed between the housing pack 31 and the blocking plate 34 constituting the rotating part 30 to maintain an airtight state, and the housing pack 31 and the rotary slider 32. O-ring 36 is also provided between) to maintain the airtight state.

On the other hand, the press holder 45 is composed of a holding table 45a and a movable table 45b, the holding table 45a is fixedly coupled to the refrigerant supply pipe 41 by a fixing bolt 45c, and the holding table ( A spring 45d is provided between 45a and the movable table 45b, and this spring 45d pushes the movable table 45b against the fixed table 45a, and the movable table 45b and the fixed slider 44 O-ring 50 is provided between the ().

Therefore, the gas is completely sealed between the press holder 45 and the fixed slide 44 to prevent the refrigerant gas from leaking.

In this way, the inner surface of the fixed slider 44 is hermetically blocked by the press holder 45 and the O-ring 50 in a fixed state, and the outer surface of the fixed slide 44 is a contact surface (surface treated with the rotary slider 32) ( Since the cooling drum 10 rotates while being in contact with the airtightly blocked state through s), the refrigerant in the cooling drum 10 is rotated between the rotary slider 32 and the fixed slider 44. You can prevent the gas from leaking.

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On the other hand, the refrigerant supply pipe 41 is arranged to extend only to the middle portion of the cooling drum 10, a plurality of refrigerant injection nozzles 46 are installed at the front end, the refrigerant injected through the refrigerant supply pipe 41 Is injected into the cooling drum 10 through the injection nozzle 46.

The refrigerant recovery pipe 42 is inserted into the cooling drum 10 through the installation hole 14 and is not connected to the opposite side wall 13, but extends only to the middle portion thereof. ) Is arranged to approach the case 11 of the cooling drum 10.

The refrigerant injection nozzles 46 installed at the front end of the refrigerant supply pipe 41 to inject and inject refrigerant into the cooling drum 10 are elliptical nozzle bodies 46a as shown in FIGS. 3 and 4. And a concave ring-shaped surge space 46b having a rectangular cross-sectional shape for temporarily collecting the refrigerant to adjust the pressure of the refrigerant supplied through the refrigerant supply pipe 41 within In addition, the elliptical nozzle body 46a has a structure in which a plurality of small diameter refrigerant injection holes 46c connected to the internal surge space 46b are formed.

Although the coolant injection holes 46c are arranged in the radial direction on the surface of the elliptical body 46a, four are shown in the figure, but one or more can be formed and used as necessary.

As described above, in the ice making apparatus according to the present invention, a concave ring-shaped surge space 46b having a rectangular cross-sectional shape which temporarily collects refrigerant inside the refrigerant injection nozzle 46 so as to equalize the pressure of the refrigerant. Since the refrigerant supplied from the refrigerant supply passage 43 is mixed in a homogeneous state while waiting in the surge space 46b for a while, it is injected into the cooling drum 10 through the injection hole 46c. Allow vaporization.

In addition, the refrigerant injected through the injection hole 46c radially formed on the surface of the body 46a of the injection nozzle 46 is radially injected, and as shown in FIG. 2, in various directions on the inner surface of the cooling drum 10. The bumps will vaporize to further increase the cooling effect.

As described above, when the cooling drum 10 is cooled by the refrigerant injected through the injection nozzle 46, water that comes into contact with the surface of the cooling drum 10 is frozen, and the frozen ice is removed using a knife or a cutter. Scrape or cut to use powdered or crushed ice.

On the other hand, the refrigerant injected into the cooling drum 10 is from the center of the cooling drum 10 to the front end and the inner surface of the drum case 11, which forms the free end of the extension portion 42a through the extension portion 42a. Is recovered by the refrigerant recovery pipe 42 extending down to reach a distance of 2 to 3 mm. When the extension 42a extends in the radial direction and is located near the inner surface of the drum case 11, the refrigerant contained in the refrigerant is contained. The compressor lubricant can be sucked together and removed.

That is, the lubricating oil of the compressor (piston) is inevitably mixed into the refrigerant slightly in the structure of the device in which the refrigerant comes into contact with the reciprocating piston when the refrigerant is compressed by the compressor. The lubricating oil of the sherr is introduced into the cooling drum 10 together.

When lubricating oil having a specific gravity and viscosity higher than that of the refrigerant flows into the cooling drum 10, the lubricating oil is not easily vaporized and is accumulated on the inner surface of the cooling drum 10. When the refrigerant evaporates, the cooling temperature of the cooling drum 10 may not be sufficiently cooled, thereby decreasing cooling efficiency, and if this phenomenon continues, ultimately, the compressor may run out of lubricating oil. Overheating may occur.

Therefore, in the ice making apparatus according to the present invention, when the refrigerant is recovered, the suction is performed near the inner surface of the cooling drum 10 so that the lubricating oil of the compressor is also recovered, thereby preventing the problem of lowering the cooling efficiency.

In addition, in the ice making apparatus according to the present invention, the inlet of the refrigerant recovery pipe 42 is positioned not to the center along the longitudinal direction of the cooling drum 10 but to one side, so that the refrigerant gas of the cooling drum 10 By not oriented in the center, the efficiency of the cooling action on the surface portion of the cooling drum 10 is reduced so that the problem that affects the ice making yield does not occur.

As described above, in the ice making apparatus according to the present invention, the contact surface s of the rotary slider 32 of the rotary part 30 and the fixed slider 44 of the fixed part 40 is treated with a surface diameter so that the refrigerant gas does not leak. In addition, since the fixed slider 44 and the refrigerant supply pipe 41 are coupled to each other by the O-ring 50 and the press holder 45 in a hermetic state, the rotary part 30 and the rotor 30 can be secured without leakage of refrigerant gas. Allow the government 40 to rotate relative to each other.

And the part which forms the boundary line of the rotating part 30 and the fixed part 40 consists only of the rotating slider 32 and the fixed slider 44, The said fixed slider 44 is only supported by the press holder 45, In addition, since the refrigerant injection nozzle 46 is coupled to the rear of the press holder 45, the structure of the refrigerant circulator 20 is simplified, and thus the maintenance is convenient.

In addition, in the ice making apparatus according to the present invention, since the refrigerant injection nozzles 46 may be connected to any number as necessary, one refrigerant circulator 20 may be used regardless of the size and length of the cooling drum 10. ), You can make ice makers of various sizes.

On the other hand, as shown in Figure 4, in the ice making apparatus according to the present invention has a structure in which the refrigerant injection hole 46c formed in the refrigerant injection nozzle 46 is formed radially in one body 46a in a radial direction. Therefore, the body of the nozzle 46a of the nozzle can be made of a stainless steel material that is harder than copper without hard rust.

In addition, since the size of the injection hole 46c can be processed to a size of about 0.1 to 0.3 mm as it can be made of stainless steel, the vaporization temperature of the refrigerant is further lowered by forming the size of the injection hole 46c smaller. It can be lowered to about -30 ~ -40 ℃ to increase the ice making effect.

In addition, since the refrigerant injection nozzle 46 according to the present invention is provided with a surge space 46b for homogenizing the refrigerant inside the body 46a, a separate auxiliary drum is not required, so the structure thereof is simplified. It can be done.

Further, the coolant is finely divided by installing a plate-like net 46d having a mesh size of 0.1 mm or less in the surge space 46b forming the inlet of the injection hole 46c of the coolant injection nozzle 46. As a result, the injection hole 46c is introduced into the injection hole 46c, and foreign matter is introduced into the injection hole 46c, thereby preventing the phenomenon of clogging.

The net 46d may be made of various materials such as fiber or metal.

1 is an exploded perspective view showing a cooling drum structure of a drum-type ice maker and a refrigerant circulator for injecting and recovering refrigerant into the cooling drum according to the present invention;

FIG. 2 is a cross-sectional view of the cooling drum of the drum ice maker of FIG. 1;

3 is a cross-sectional perspective view of a refrigerant injection nozzle installed in a refrigerant circulator of a drum-type ice maker according to the present invention;

4 is an enlarged cross-sectional view of a portion “C” of FIG. 2;

Figure 5 is a side view showing the structure of a general drum ice maker,

6 is a front view showing the structure of a conventional drum-type ice maker.

* Description of the main symbols in the drawings *

10-cooling drum 20-refrigerant circulator

30-rotating part 40-fixing part

11-drum case 12-axis of rotation

13-side walls 31-housing pack

32-rotary slider 33-bearing

34-Blocker 41-Refrigerant supply pipe

42-Refrigerant recovery pipe 43-Refrigerant supply passage

44-Fixed Slider 45-Press Holder

46-Refrigerant injection nozzle 47-Tip cap

Claims (7)

Cooling drum (10) made of a drum shape and cooled by a refrigerant circulated therein while rotating in contact with a water-filled head to freeze thin ice on a circumferential surface thereof, and is inserted into the cooling drum to be inserted into the cooling drum. It consists of a refrigerant circulator 20 for injecting and discharging; A drum-type ice making device in which the refrigerant circulator is inserted in one side of the cooling drum and extends only to the middle without being connected to the opposite side; The refrigerant circulator 20 is fixed to the cooling drum 10 and rotates with the cooling drum 10, and is disposed inside the rotating unit 30 to supply gas while being fixed without rotation. And a fixed portion 40 to recover; The rotary part 30 is inserted into and fixed in the installation hole 14 formed in the side wall 15 of the cooling drum 10, and at the distal end of the fixing part 40 inside the housing pack 31. A combined rotary slider 32 and a bearing 33 installed to support the rotation of the fixed part 40 while supporting the rotary part 30 so as to be freely rotatable with respect to the fixed part 40; The fixed part 40 is a refrigerant supply pipe 41 for injecting refrigerant into the cooling drum 10 and a refrigerant for being inserted into the refrigerant supply pipe 41 to recover the refrigerant in the cooling drum 10. A rotary slider fixedly installed outside the recovery pipe 42, the refrigerant supply pipe 41, and the refrigerant supply passage 43 formed between the refrigerant recovery pipe 42 and the refrigerant supply pipe 41 to maintain an airtight state. A fixed slider 44 which allows the 32 to rotate while sliding each other through a surface-contacted contact surface s while supporting the refrigerant gas from leaking, and coupled to the outside of the refrigerant supply pipe 41. Press holder 45 for pushing the fixed slider 44 toward the rotary slider 32 so that the fixed slider 44 is hermetically coupled to the refrigerant supply pipe 41, and the refrigerant supply pipe 41. In the middle of) One or more refrigerant injection nozzles 46 coupled to each other at regular intervals, and a plurality of refrigerant injection nozzles 46 installed on the side of the refrigerant injection nozzles 46 installed at the end of the refrigerant supply pipe 41. Drum-type ice maker characterized in that the front end cap 47 for tightly coupling to maintain the airtight state delete According to claim 1, wherein the press holder 45 is composed of a holding table 45a and a movable table 45b, the holding table 45a is fixedly coupled to the refrigerant supply pipe 41 by a fixing bolt 45c. A spring 45d is provided between the fixing table 45a and the movable table 45b, and the spring 45d pushes the movable table 45b with respect to the fixing table 45a, and the movable table 45b. O-ring 50 is provided between the fixed slider 44 and the drum, characterized in that the drum is completely sealed to prevent the refrigerant gas from leaking through the press holder 45 and the fixed slide 44 Type ice maker According to claim 1, wherein the refrigerant recovery pipe 42 is provided with an extension portion 42a extending in the radial direction of the cooling drum 10, the free end of the extension portion 42a of the drum case 11 Drum type ice making device which extends from 2 to 3mm from the inner surface to suck together the lubricating oil of the compressor contained in the refrigerant The method of claim 1, wherein the refrigerant injection nozzle 46 can temporarily collect the refrigerant to adjust the pressure of the refrigerant supplied through the refrigerant supply pipe 41 inside the nozzle body (46a) made of an elliptical shape Refrigerant having a concave ring-shaped surge space 46b having a rectangular cross-sectional shape, and having a plurality of diameters of 0.1 to 0.3 mm connected to the surge space 46b inside the elliptical nozzle body 46a. A drum type ice making device, characterized in that a jetting hole (46c) is formed, and a valve-like net (46d) having a mesh size of 0.1 mm or less is provided in the surge space (46b). delete delete

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