KR102354689B1 - Auger type ice maker - Google Patents

Abstract

An auger type ice maker is disclosed. The auger type ice maker comprises: a cover member; a cylindrical evaporation pipe body cooling the inside thereof by a cooling cycle through a refrigerant line and a refrigerant circulation passage inside the cover member; a cylindrical ice making cylinder having a cooling space, where an ice making water supply line is connected, formed inside the evaporation pipe body and having an outlet, discharging manufactured ice, formed in an end part of the cooling space; an auger having at least one spiral blade formed in a rotational shaft inside the cooling space of the ice making cylinder; a driving unit transmitting driving force to the auger; and an ice exit unit (600) installed between the outlets at the bottom stage of ice making of the ice making cylinder, having a discharge body (610) having a cylindrical shape and both opened ends, having an inner circumferential surface (620) having a diameter gradually getting smaller from one opened side end part to the other opened side end part of the discharge body (610), having a spiral guide groove (630) guiding the manufactured ice to the inner circumferential surface (620), and connected to the outlet (320) at an end part where the guide groove (630) ends. The outlet (320) comprises: a flange (110) exchanged and assembled to the outside of the outlet according to a shape of the ice and coupled to a coupling flange; a discharging body (120) formed in a cylindrical shape to the outside of the flange (110); a fastening hole (112) formed inside the flange (110); and an ice forming unit (100) having a cylindrical discharge unit (140) connected from the flange (110) to a discharge space (150).

Description

Auger type ice maker {Auger type ice maker}

The present invention relates to an auger-type ice maker, and more particularly, to an auger-type ice maker capable of discharging ice by variously discharging the shape of the ice discharged through an outlet of an ice-making cylinder and controlling the pressure at the time of discharging.

In general, the auger type ice maker is known as follows.

Patent Laid-Open Publication No. 10-2003-62201,

A vertical ice maker, an auger installed on the same axis in the ice bin to continuously scrape the growing layer of ice on the same inner circumferential surface and transport it upward; In an auger type ice maker having a pressure head fixedly installed on the upper side of a container, when ice scraped off by an auger is pushed up by a pressure head on the inner peripheral surface of the ice container and transferred, the ice is moved in the transport direction An auger-type ice maker in which a screw blade that prevents synchronous rotation with an auger while continuously being compressed with the auger is installed to cross the axial direction, and the intersecting angle of the spiral blade in the axial direction is set to 90 to 110 degrees known,

Patent Publication No. 10-416944,

An auger having a vertical ice maker, an auger coaxially installed in the ice bin, a refrigerant pipe recommended in a closely spiral shape to the outer periphery of the ice bin, and a pressure head installed on the auger shaft on the auger shaft and above the ice maker In the type ice maker, the auger is composed of a main body and a spiral blade provided on the outer periphery of the main body, and the cross-sectional shape of the blade portion of the spiral blade gradually thickens from the vertical edge of the blade toward the base of the main body. Auger type in which the thickness of the tip of the blade is 1-3 mm, the taper angle of the upper surface extending from the tip of the blade to the main body is set to 2 to 8 degrees, and the taper angle of the lower part is set to 10 to 20 degrees, respectively, in a truncated isosceles triangle shape Ice makers are known,

Patent Publication No. 10-2003-0069462,

An ice maker that continuously extrudes and produces ice pillars by shaving the frozen ice by the evaporator of the freezer to generate shavings, and at the same time introducing the shredded ice into an extrusion head equipped with an ice compression passage and compressing it. Pressurized compression pieces made of an elastic material respectively mounted on the partition blades, each of which is pushed out from the side of the partition blade toward the ice compression passage and gradually reduces and regulates the width of the ice compression passage from the inlet side to the exit side of the ice compression passage. An extrusion head for compressing ice in an ice maker configured is known,

Patent Registration No. 20-0138409,

A compressor that compresses a refrigerant, a radiator that liquefies the compressed refrigerant, an evaporator that freezes ice by vaporization of the refrigerant, a water tank for supplying water to the evaporator, and an angle that cuts ice formed in the evaporator into cubes of a certain size In an ice maker having an ice cutting unit and an ice storage unit for storing the cut ice, water generated in the ice cutting unit and the ice storage unit and discharged through a water discharge pipe generated in the refrigerator is combined with water discharged from a water tank to dissipate heat A radiator cooling device of an ice maker is known, which is introduced into the radiator through a pipe inlet, undergoes heat exchange, and then is discharged to the outside through an outlet of the radiator pipe.

On the other hand, in the conventional auger-type ice maker, the ice outlet is in the same direction as the axial direction of the auger (vertical type, hereinafter referred to as a vertical type ice maker), and the method is perpendicular to the auger axial direction (horizontal type, Hereinafter referred to as a horizontal ice maker).

When such a vertical auger type ice maker has a small capacity with a small amount of ice, in the case of the vertical type, the size of the auger and the evaporator where the auger is located as well as the size of the outlet through which a large number of ice comes out are reduced, so the size of the ice particles that come out is also small. and become unsuitable for use. In particular, in the case of a vertical ice maker, ice resistance is applied to the ice resistance applied to the spiral blade of the auger in response to the rotational force of the drive motor driving the auger shaft, opposite to the direction of ice movement, and the position where the pressure is strongest is the outlet side. In other words, the radial load applied in the lateral direction of the auger shaft acts as a component force corresponding to the spiral angle of the auger to the axial load, that is, the thrust load. In preparation for this, the idling means (bearings) of sufficient capacity and the cover fixing structure corresponding to the supporting force were worn on the drive shaft part due to the wear and thus the lifespan of the ice maker was shortened.

On the other hand, the horizontal type ice maker forms an outlet on the upper surface (side) of the ice maker, so it can be used as an ice maker suitable for discharging large particles of ice while having a small capacity compared to a vertical type ice maker.

In addition, the vertical type ice maker is designed to dispose a driving motor, an ice maker such as an auger, and a plurality of outlets including an ice making function through refrigerant circulation and a compression function after ice making. Therefore, it can be said that the force (also called radial load) applied in the direction perpendicular to the auger shaft is small because the ice is compressed in the direction of the auger shaft.

The horizontal type ice maker is designed to be arranged in the order of the ice making unit such as an auger, the outlet including the ice making and post-icing compression function through refrigerant circulation, and the driving motor. Since the force applied in the perpendicular direction increases, as a horizontal ice maker, the number of parts is increased to overcome this, and expensive parts are required, thereby increasing the burden on the manufacturing cost. In particular, in the known horizontal ice maker, the number of parts is small and there is a possibility that the cost can be reduced, but the pressure of the ice making is increased due to the rotation of the auger from the ice making cylinder to the outlet at the end of the ice making process. There was a problem in that durability was deteriorated due to a considerable pressure acting on the side of the drive shaft in which the cover member and the bearing were installed.

In common, the conventional vertical ice maker has a cutting structure in which the cylindrical ice discharged through the outlet is pushed up by the ice making pressure at the end of the ice making, collides with the side of the extrusion head having the inclined surface and is cut. However, since the horizontal installation type auger type ice maker has the outlet formed upward, it is bent in a right angle direction while colliding with the wall of the rising ice-making space, and a special cutting structure is assembled at the outlet (Patent Publication No. 10-2018-0134650 No. ). These discharged ice are constantly contacted, cut, and stored in a cylindrical shape regardless of the length, shape, and shape of the ice being discharged, and are stored and used without restrictions on the type and length of discharge. However, as beverage culture is increasingly diversified, it is necessary to diversify the shape of ice, such as making it very small or large, as well as vulcanized ice. The necessity of discharged ice having various shapes and shapes is recognized. In most cases, except for the cylindrical shape of the ice exiting the outlet and the discharging end in these various shapes, a part of the discharging part has to be blocked (Patent Publication No. 10-2017-0105301), so the discharge pressure at the end of ice making may greatly increase. This increase in discharge pressure acts as a resistive force when discharging as the ice guided in the right angle direction is not discharged as it is at the end of the diameter of the outlet as the rotational pressure of the auger applied at the end of ice making increases. Due to the pressure in the opposite direction due to the resistance applied for a long time, the sealing structure of the discharge part is cracked, the partition wall part of the cover part blocked at the end of the ice making cylinder cracks, and the bearing structure is separated, which causes leakage as well as the cause of noise. Ultimately, it causes cracks in the outer cover member and the insulating part, which is a cause of failure and may shorten the lifespan.

Therefore, there is a need for a structure for guiding and discharging ice at the end of ice making that is installed at the end of the outlet and can smoothly distribute and discharge the increased discharge pressure according to the blocking resistance of the end that specifies the shape of the ice.

(Document 1) Patent Registration Publication No. 10-0416944 (Registration Announcement on January 16, 2004) (Document 2) Patent Registration Publication No. 20-0138409 (Notice on May 15, 1999) (Document 3) Patent Registration Publication No. 10-1594457 (published on February 16, 2016)

(Document 1) Patent Publication No. 10-2003-62201 (published on July 23, 2003) (Document 2) Patent Publication No. 10-2003-0069462 (published on August 27, 2003) (Document 3) Patent Publication No. 10-2018-0134650 (published on December 19, 2018)

The auger-type ice maker according to an embodiment of the present invention for improving the above problems is formed by forming the shape of the discharged ice in the longitudinal direction at the end of the outlet, so that the shape of the ice cubes having various shapes of circumferential surfaces, for example, a cylinder An object of the present invention is to provide an auger-type ice maker that provides ice cubes, such as ice cubes, heart-shaped, or star-shaped ice cubes.

At the same time as achieving the above object, the discharge pressure according to the resistance of the blocking portion (discharge port non-opening portion) generated during discharge due to the shape of the portion blocking partial discharge at the end of the discharge port is reduced in the space portion of the ice making machine at the end of the ice making cycle. Provided is an auger type ice maker having a guiding structure that not only guides the ice to be discharged smoothly after ice making by concentrating the pressure, but also discharges with relatively little resistance even if the ice moving through the discharge path generates resistance. It also has a purpose.

In order to achieve the above object, the guide structure of the auger type ice maker is assembled as a separate assembly module from the ice-making cylinder and forms a cylindrical space with a gradually narrower diameter at the end of the ice-making cylinder. It also aims to increase the density of ice by squeezing the ice more strongly afterward.

In order to achieve the above object, the auger type ice maker separates the two-purpose guide structure assembled to the ice making cylinder as an ice exit module with a spiral groove formed in a narrower space, thereby improving the assembly structure of the auger type ice maker. There is this.

An auger-type ice maker according to an embodiment of the present invention for achieving the above object,

a cover member; a cylindrical evaporating tube that forms a refrigerant circulation path to which a refrigerant line is connected inside the cover member and cools it toward the inside of the refrigerant circulation path in a predetermined cooling cycle through the refrigerant line and the refrigerant circulation path; a cylindrical ice-making cylinder having a cylindrical cooling space to which an ice-making water supply line is connected in the evaporator, and an outlet through which the ice-making water is discharged at the end of ice making; an auger having at least one spiral blade formed on a rotating shaft inside the cooling space of the ice-making cylinder; a driving unit connected to the rotation shaft of the auger to transmit a driving force;

Both ends of the cylindrical shape form an open discharge body, form an inner circumferential surface with a diameter gradually narrowing from the open one end to the other end, form a guide groove on the inner circumferential surface, and communicate with the outlet at the end where the guide groove ends Assembly and installable ice-out module;

A discharge unit in which the ice-out module is installed and a discharge port is formed: And
an ice forming unit which is replaced and assembled according to the shape of ice by forming a flange coupled to the coupling flange, a discharge body formed in a cylindrical shape outside the flange, and a cylindrical discharge unit connected from the flange to the forming space;
It is an auger-type ice maker comprising a.

According to an embodiment of the present invention for achieving the above object, the spiral flaw of the ice-making module of the auger-type ice maker is an auger-type ice maker, characterized in that at least one guide groove is formed to correspond to the number of augers in the ice-making cylinder. .

The ice-making module of the auger type ice maker according to an embodiment of the present invention for achieving the above object is an auger type ice machine characterized in that it is assembled between the ice making cylinder and the driving unit.

The outlet of the auger type ice maker according to an embodiment of the present invention for achieving the above object,

a coupling flange formed outside the outlet; and a flange fastened to and coupled to the coupling flange, and a discharge body having a cylindrical space communicating with the discharge port is formed inside the inlet of the flange, and the discharge part of the discharge body is opened to form a shape. It is an auger type ice maker including; an ice forming unit that forms a

In order to achieve the above object, the discharge plate of the ice forming unit of the auger type ice maker according to an embodiment of the present invention is an auger type ice machine characterized in that a heart-shaped opening is formed.

In order to achieve the above object, the discharge plate of the ice forming unit of the auger type ice maker according to an embodiment of the present invention is an auger type ice machine characterized in that a pentagonal opening is formed.

In order to achieve the above object, the discharge plate of the ice forming unit of the auger type ice maker according to an embodiment of the present invention is an auger type ice maker characterized in that a star-shaped opening is formed.

As described above, the auger type ice maker according to an embodiment of the present invention can discharge ice of various shapes and shapes by forming the shape of the discharged ice in the longitudinal direction at the end of the outlet.

The auger type ice maker according to an embodiment of the present invention absorbs and buffers the reverse pressure according to the blocking resistance of the discharge plate by the part blocking the partial discharge at the end of the discharge port to some extent, thereby smoothly guiding the discharge of the discharged ice, resulting in relatively low resistance. It is possible to provide an auger-type ice maker having an ice-out module that receives and discharges the ice.

The ice-making module (guide structure) of the auger type ice maker according to an embodiment of the present invention is assembled as a separate assembly module from the ice-making cylinder and forms a cylindrical space with a diameter that gradually narrows at the end of the ice-making cylinder. It is possible to obtain the effect of obtaining the discharged ice with an increased density of ice by strongly compressing the ice after making the ice by concentrating it to shrink.

The auger type ice maker according to an embodiment of the present invention improves the assembly structure of the auger type ice maker by converting the two-purpose guide structure assembled to the ice making cylinder into a separate part as an ice exit module having a guide groove formed in a narrower space.

1 is a perspective view of an auger-type ice maker according to Embodiment 1 of the present invention;
2 is an exploded perspective view of an auger-type ice maker according to Example 1 of the present invention;
3A and 3B are a cross-sectional view of an ice forming unit installed at an outlet installed at an outlet of an auger-type ice maker according to Embodiment 1 of the present invention, and a sectional view taken along line A-A';
4 is a cross-sectional view of a guide module of an auger type ice maker according to Embodiment 1 of the present invention;
5A and 5B are an installation state sectional view and an enlarged sectional view of a modified guide module of the auger type ice maker according to Embodiment 1 of the present invention;
6A to 6C are perspective views of the ice forming unit according to the shape of the discharged ice of the auger type ice maker according to the second embodiment of the present invention;
7a to 7c are perspective views by shape of discharged ice of an auger-type ice maker according to Embodiment 2 of the present invention;
8A to 8C are perspective views of a modified ice forming unit of the auger type ice maker according to Embodiment 2 of the present invention.

Hereinafter, an auger-type ice maker according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

(Example 1)

Of the accompanying drawings, FIG. 1 is a perspective view of an auger-type ice maker according to Embodiment 1 of the present invention, FIG. 2 is an exploded perspective view of an auger-type ice maker according to Embodiment 1 of the present invention, and FIGS. 3A and 3B are an embodiment of the present invention A cross-sectional view of the ice forming unit installed at the outlet installed at the outlet of the auger type ice maker according to 1, and A-A' cross-sectional view, FIG. 4 is a cross-sectional view of the guide module of the auger type ice maker according to Embodiment 1 of the present invention; 5a and 5b are an installed state cross-sectional view and an enlarged cross-sectional view of a modified guide module of the auger-type ice maker according to Embodiment 1 of the present invention.

The auger-type ice maker according to Embodiment 1 of the present invention according to the above drawings largely includes cover members 210 and 220 , an ice-making cylinder 230 , an evaporation tube body 240 , an auger 250 , and a driving unit (shown in the drawings). omitted), an inlet unit 310 , an outlet unit 330 , an ice outlet module 600 , an outlet 320 , and an ice forming unit 100 .

First, the evaporation tube body 240 forms a refrigerant circulation path to which a refrigerant line is connected inside the cover members 210 and 220, and through the refrigerant line and the refrigerant circulation path to a predetermined cooling cycle (A) toward the inside of the refrigerant circulation path. It constitutes a cylindrical cooling unit for cooling (a detailed description of the cooling cycle is omitted).

The ice-making cylinder 230 forms a cylindrical cooling space to which an ice-making water supply line is connected in the evaporator 240, and an outlet 320 through which the ice-making water is discharged at the end of ice making. It is a cylindrical cylinder (a more detailed description is omitted).

The auger 250 forms at least one spiral blade on the rotating shaft inside the cooling space of the ice-making cylinder 230 (a more detailed description will be omitted).

A driving unit (not shown) is connected to the auger 250 and includes a bearing, a sealing member, etc. provided with a bearing and a sealing member, and a driven shaft unit, and a detailed structure and description will be omitted.

The discharging unit 330 forms a discharge port 320 through which ice is discharged after ice making by the auger 250 between the ice making cylinder 230 and the driving unit.

The ice forming unit 100 is exchanged and assembled according to the shape of the ice on the outside of the outlet 320 , and forms a flange 110 coupled to the coupling flange 321 , and discharges cylindrically to the outside of the flange 110 . The body 120 is formed, a fastening hole 112 is formed inside the flange 110, and a discharge space is formed in the flange 110 having an inlet 130 communicating with the outlet 320 of the discharge unit 330. Through this, a cylindrical discharge unit 140 having the same diameter as the discharge port 320 may be formed.

The ice maker 600 has a cylindrical shape, and there is an a-type ice maker 600a ( FIGS. 2 and 4 ) having a discharge body 610 having both ends open, and the outlet end of the discharge body 610 is bent at a right angle to combine. It is possible to implement the b-type ice churning unit 600b ( FIGS. 5A and 5B ) having a flange 612 .

These ice churning units 600, 600a, and 600b form an inner peripheral surface 620 having a diameter gradually decreasing from one open end of the discharge body 610 to the other end in common, and the inner peripheral surface 620 has a certain depth. A helical guide groove 630 for guiding ice-making is formed by the furnace, and the guide groove 630 communicates with the outlet 320 while forming a discharge path 640 at the end of the guide groove 630 .

The b-type ice churning unit 600b extends the discharge body 610 to extend by bending the discharge path 640 side at a right angle, and may form a coupling flange 612 at the discharge side end thereof.

The guide grooves 630 of the ice-making units 600 , 600a and 600b may form at least one guide groove 630 to correspond to the number of originals of the ice-making cylinder 230 . It is preferable that the number of guide grooves 630 corresponding to the number of ice-making spaces between the organ of the auger and the organ is defective. Alternatively, the guide groove 630 may adjust the depth of various grooves, the width and the number of spiral grooves for reducing the pressure of discharging ice and ice, according to the layout design. The ice maker 600 is inserted and assembled between the ice making cylinder 230 and the driving unit, so that the auger type ice maker can be easily assembled. Alternatively, it may be more preferable to be integrally formed at the end position of the ice making cylinder 230 .

As described above, in the auger type ice maker according to the embodiment of the present invention, the ice-making ice passing through the ice-making cylinder 230 is guided along the guide groove 630 of the ice-making module 600 and discharged through the outlet 320 , and simultaneously with the discharge. Since the ice-making pressure of the ice-making module 630 acts greater than the blocking resistance, the ice-making pressure of the ice-making module 630 acts on the discharge resistance of the ice-making ice that may be generated by the pressure acting in the reverse direction according to the blocking resistance of the discharge port 140 that is not opened of the discharge plate 142. This is to enable the smooth discharge of the discharged ice.

The auger-type ice maker according to an embodiment of the present invention allows the ice-making module 600 to be assembled as a separate assembly module from the ice-making cylinder 230, and a cylindrical space with a diameter gradually narrowing at the end position of the ice-making cylinder 230. By doing so, it is possible to improve the crushing of ice by increasing the density of the ice by intensively pressurizing the ice-making ice as if it is shrinking and compressing the ice-making ice.

The auger-type ice maker according to an embodiment of the present invention is an ice-making module for two purposes (various shapes, solid crystallinity) that is assembled into the ice-making cylinder, and separate parts to provide the assembly structure of an existing auger-type ice maker, or an ice-making cylinder It is to provide an auger-type ice maker having a more concise discharging structure of the ice making cylinder through improvement by applying it integrally to the ice maker.

(Example 2)

6A to 6C of the accompanying drawings are perspective views of the ice forming unit according to the shape of the discharged ice of the auger type ice maker according to Embodiment 2 of the present invention, and FIGS. 7A to 7C are views of the auger type ice maker according to Embodiment 2 of the present invention. It is a perspective view for each shape of the discharged ice, and FIGS. 8A to 8C are perspective views of a modified ice forming unit of the auger type ice maker according to the second embodiment of the present invention.

According to the drawings, the ice forming unit 100 of the auger type ice maker according to the embodiment of the present invention is exchanged and assembled according to the shape of the ice, and forms the flange 110 coupled to the coupling flanges 321 and 621, and the Flange ( In 110), a molding space 132 of a predetermined shape is formed up to the discharge part 140 .

Inside the flange 110 , a molding space 132 for discharging tubular ice while blocking the discharge of some ice is formed to the discharge unit 140 .

On the other hand, although not shown, the ice forming unit 100 forms a cylindrical forming space 132 from the inlet 130 to the discharge unit 140 to form ice in the shape shown in FIGS. 7A to 7C on the discharge unit 140 side. A discharge plate 142 for discharging may be formed. The discharge plate 142 may form a heart-shaped opening 144 , may form a pentagonal opening 144 , and may form a star-shaped opening 144 .

In addition, the ice forming unit 100 of the auger type ice maker according to the embodiment of the present invention has an inlet 130 having several forming spaces 132 and a fastening hole 112 as shown in FIGS. 8A to 8C . It can be implemented as an ice forming unit 100 having a flange 110 and a discharge body 120 .

In addition, by varying the opening shape of the discharging plate 142, the shape and shape of the ice have been varied in the past, but the shape and the shape of the ice can be discharged in a variety of ways, so that it can be used for food and beverages for various purposes. will become

The auger-type ice maker according to an embodiment of the present invention uses the blocking resistance that is not opened at the inlet 130 side of the discharge body 120 or the discharge plate 142 of the discharge unit 140 in the ice exit module 600 described in Embodiment 1 ), the ice-making ice compressed by pressing the ice-making ice at the end position of the ice-making cylinder 230 is blocked at the inlet 130 of the ice forming unit 100 at the outlet end, or reverse pressure according to the blocking resistance of the discharge plate 142 It is to provide an auger-type ice maker that smoothly guides the discharge of the discharged ice by absorbing and buffering the ice to some extent.

Although illustrated in the drawings of the present invention described above and described with reference to the preferred embodiments described above, these are exemplary, and those of ordinary skill in the art, such as the present invention, can make various modifications and equivalent other Examples are possible. The technical protection scope of the present invention will be determined by the claims.

100; Ice forming unit, 110; Flange, 112; Fastening hole, 120; Discharge body, 130; Inlet,
132; molding space, 112; fastening hole, 150; discharge space, 140; discharge part, 142; discharge plate,
144; Opening, 210, 220; Cover member (1) (2), 230; Ice making cylinder, 240; Evaporation tube body,
250; Auger, 310; Inlet, 320; Outlet, 330; Discharge unit, 600, 600a, 600b; Ice unit,
610; Exhaust body, 612; Combination flange, 620; Inner circumferential surface, 630; Guide groove, 640; Discharge path,

Claims (7)

delete delete delete In the auger type ice maker,
cover member;
a cylindrical evaporating tube that forms a refrigerant circulation path to which a refrigerant line is connected inside the cover member and cools it toward the inside of the refrigerant circulation path in a predetermined cooling cycle through the refrigerant line and the refrigerant circulation path;
a cylindrical ice-making cylinder having a cylindrical cooling space to which an ice-making water supply line is connected in the evaporator, and an outlet through which the ice-making water is discharged at the end of ice making;
an auger having at least one spiral blade formed on a rotating shaft inside the cooling space of the ice-making cylinder;
a driving unit connected to the auger to transmit driving force;
A discharge body installed between the driving units at the end of ice making position of the ice making cylinder and having both ends open in a cylindrical shape; an ice exit module comprising at least one or more spiral guide grooves corresponding to the number of originals of the ice making cylinder to guide the ice, a discharge path formed at the end of the guide groove, and a coupling flange formed on the side of the discharge path;
The ice-out module is installed, the discharge unit to form a discharge port; And
an ice forming unit which is replaced and assembled according to the shape of ice by forming a flange coupled to the coupling flange, a discharge body formed in a cylindrical shape outside the flange, and a cylindrical discharge unit connected from the flange to the forming space;
Auger type ice maker comprising a. delete delete delete

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