KR100480373B1 - Squeezer for juice - Google Patents

Abstract

The present invention is a juice grinder capable of crushing and compressing vegetables and fruits to make juice, or put and crush and put grains and meat, in the process of crushing and extruding vegetables and fruits, or crushing and extruding cereals and meat It is an object of the present invention to provide a juice grinder which can reduce the wear and noise of the battery, improve the juice rate, and enhance the grinding and extrusion functions.

According to the present invention, in the juice grinder for feeding food through the inlet formed in the upper portion of the housing, and crushing and compressing the injected food, the extrusion screw is located in the interior of the housing with a tip having a predetermined diameter. The rear end formed by the cutout, the cutout, and the pulverized part is relatively larger than the diameter of the distal end, and a spiral is formed at the periphery. The middle part is a conical shape connecting the distal end and the rear end, and a radial spiral is formed around the rear end. A grinding rod body having a fixed rotating shaft, a guide tube for pulverizing and juiced foods by rotating the grinding rod body while wrapping the tip, middle, and rear ends of the grinding rod body; a lid fastened to the tip of the housing and having a through hole formed at the center thereof; The grinding nozzle is coupled to the ball end, and is combined with the rotating shaft of the grinding rod body penetrating the rear end of the housing. The juice grinder comprising a driving unit for rotating the body is provided.

Description

Juice Grinder {Squeezer for juice}

The present invention relates to a juice grinder, and more particularly, to increase the juice rate when juiced vegetables or fruits, to improve the fine grinding and extrusion functions when grinding grains and meat, and to correspond to the operation The present invention relates to a juice grinder which can prolong the life of the product by preventing the abrasion of the blades and thus prevents the wear of the blades, and also reduces the noise.

Conventional screw-type juicer, when the outer blade of the grinding rod body and the inner blade of the juice container or grinding barrel collide with each other during operation, the wear of the blade is fast, the problems such as noise is generated and the discharge pressure is low, hard packing juice If it does not discharge the debris, there is a shape in the housing, so the rubber member or juice packing of the juice nozzle should be relatively weak, so that the juice rate is low, and the debris contains a certain amount of moisture.

The present invention has been proposed in order to solve the problems of the prior art as described above, the extrusion screw of the tip of the grinding rod body acts as a rotating shaft of the grinding rod body, thereby preventing the hitting of the blade when the grinding rod body is rotated of the blade The purpose is to significantly reduce the wear and noise and to significantly increase the juice rate by squeezing the juice contained in the residue to the high pressure once more in the extrusion screw.

According to the present invention for achieving the object as described above, in the juice grinder for inputting the food through the inlet formed in the upper portion of the housing, crushing and compressing the injected food, located inside the housing and the front end is a predetermined Extruded screw is formed in the circumference with a cylinder having a diameter, the rear end is relatively larger than the diameter of the front end portion and a spiral is formed in the circumference, and the middle portion is a conical shape connecting the front end and the rear end, and a radial spiral is formed around the rear end. The grinding rod body is fixed to the rotating shaft; A guide passage for wrapping or crushing food by rotation of the grinding rod and surrounding the front end, the middle and the rear end of the grinding rod; A lid fastened to the front end of the housing and having a through hole formed at a center thereof; A nozzle fastened to a tip of the through hole of the lid; And a driving unit coupled to a rotating shaft of the grinding rod body penetrating the rear end of the housing to rotate the grinding rod body.

In addition, the rear end of the grinding rod body is provided with a fine grinding portion formed with finely divided spirals around the finely divided portion formed with a finely divided spiral around the rear portion and an incision portion formed with a cutting spiral around the rear thereof, the spiral of the finely divided portion spiral It is preferable that the angle R3 is larger than the spiral angle R2 of the cutout portion, and the spiral angle R2 of the cutoff portion is larger than the spiral angle R1 of the cutting spiral.

In addition, the guide cylinder is preferably a juice container consisting of an extrusion network formed with a plurality of through holes, a discharge portion formed with a radial projection on the inner wall of the cone, and a grinding net formed with a plurality of triangular cutting blades on the inner wall.

In addition, the through hole is formed in a portion corresponding to the extruded screw portion, the fine grinding portion and the cut portion of the grinding rod body, the diameter of the through hole formed in the fine grinding portion relative to the through hole formed in the extruded screw portion It is preferable that the diameter of the through hole formed in the cutout portion is larger than that of the through hole formed in the fine grinding portion.

In addition, the through hole preferably has an inclined surface formed relatively larger in diameter formed on the outer surface of the juice container than the diameter formed on the inner surface of the juice container.

In addition, the rear end of the juice container is formed with a strainer at a point corresponding to the incision, the strainer is preferably blocking the juice outlet of the housing.

In addition, a plurality of triangular cutting blades are formed on the inner circumferential surface of the guide cylinder along the length of the guide cylinder at equal intervals, and the cutting blades are formed at portions corresponding to the cutting portions of the grinding rod body. It is preferable that the height of the rear end is relatively higher than the height of the front end.

In addition, a radial protrusion is formed on the inner surface of the discharge portion of the guide tube corresponding to the middle portion of the grinding rod body, the rear end height of the radial protrusion is formed relatively higher than the height of the front end, the middle portion of the grinding rod body The formed spiral helix is preferably formed such that the height of the rear end is relatively higher than the height of the front end.

In addition, the spiral direction of the radial projection formed in the discharge portion of the guide cylinder and the spiral direction of the radial spiral formed in the middle portion of the grinding rod body is preferably formed in the opposite direction.

In addition, grooves are formed at equal intervals on the inner surface of the tip portion of the guide cylinder surrounding the extrusion screw of the grinding rod body, the grooves preferably extend in the longitudinal direction of the tip portion of the guide cylinder.

In addition, the cross section of the front end portion of the guide cylinder surrounding the extrusion screw is preferably formed in a polygonal shape.

In addition, the extrusion screw of the grinding rod body is rotatably inserted into one end of the guide cylinder is preferably formed an extrusion network to prevent the shaking of the grinding rod body when the grinding rod body is rotated.

Hereinafter, with reference to the accompanying drawings a preferred embodiment of a juice grinder according to the present invention will be described in detail.

1 is an exploded perspective view of a juice grinder according to an embodiment of the present invention, FIG. 2 is a cross-sectional view of the juice grinder shown in FIG. 1 fastened to a driving unit, and FIG. 3 is a housing shown in FIG. 4A is a front view of the juicer shown in FIG. 2, FIG. 4A is a cross-sectional view taken along line A-A 'of FIG. 4A, and FIG. 4B is 4A is a partial cross-sectional view of the juice container shown in FIG. 4A, (b) of FIG. 4b is a longitudinal cross-sectional view of the line B-B 'of FIG. 4b (a), and (c) of FIG. 4b (c) of FIG. 4b (a). 4c is a side view of the juicer shown in FIG. 4a, FIG. 4d is a perspective view showing the inside of the juicer shown in FIG. 4a, and FIG. 4e is a front perspective view of the juicer shown in FIG. 4a. 5 is a front perspective view of the pulverization container installed in the juice grinder shown in FIG. 1, FIG. 6 is a front view of the pulverizing rod body shown in FIG. 2, and FIG. 7 is a stage of the lid shown in FIG. 2. 8 is a perspective view illustrating embodiments of various nozzles mounted in place of the juice nozzle shown in FIG. 2, FIG. 9 is a cross-sectional view of an embodiment of the juice nozzle shown in FIG. 2, and FIG. 10 is formed in FIG. 4A. It is sectional drawing of the through-hole formed around the juice container.

As shown in Figure 1 and 2, the juice grinder 100 is formed with an inlet (11) on the upper side, juice outlet (12) is formed on the lower side and the housing 10, the lid is fastened to the front and the housing ( 10) the crushing rod 20 for crushing and crushing the vegetables, fruits, cereals, meat (hereinafter collectively referred to as 'food') and put into the inside of the vegetables, fruit and vegetables to produce juice And the juice container 30 and the pulverizing barrel 70 surrounding the circumference of the pulverizing rod body 20 separately according to the case of grains and meat to be pulverized and extruded by the pulverization rod body is fastened to the rear end of the housing 10 It includes a drive unit 60 for rotating the rotary shaft 26 connected to the rear end of the (20).

The following describes the juice grinder in more detail.

As shown in Figure 3, the front end is opened and the rear end of the cylindrical housing 10, the food inlet 11 is formed in communication with the lower portion, the juice outlet 12 is formed in communication with the lower portion. Binding protrusions 14F and 14B are formed at the front and rear ends of the housing 10, the lid 40 is attached to the front binding protrusion 14F, and the reduction gear 61 is accommodated in the binding protrusion 14B at the rear end. The drive unit 60 is bound. In addition, the inner surface of the housing 10 is formed with a guide groove (13 in FIG. 1) in the longitudinal direction, the projections of the juice container 30 or the pulverizing barrel 70 inserted into the housing 10 (37, 77 to be stably positioned in the state inserted into the housing 10 along the guide groove (13).

On the other hand, the juice container 30 and the grinding barrel 70 is not a big difference in its configuration, but the juice container 30 is the juice generated while the food located therein is crushed and pressed by the grinding rod body 20 juice A plurality of through-holes 36 are formed in the circumference so as to be discharged to the outside of the barrel 30, the grinding barrel 70 is the food is crushed by the grinding rod body 20 to the front end of the housing 10 The difference is that the front and rear ends are opened and the circumference is closed so that the lid 40 can be discharged out of the housing 10. In the state in consideration of such a difference, the juice container 30 will be described in detail first, and a detailed description of the grinding container 70 will be omitted.

As shown in Figures 4a to 4e, the shape of the juice container 30 is divided into three large parts along its length, the front end is a cylindrical extrusion network 35, the rear end is a gentle diameter in the rear Larger and tapered cylindrical grinding net 32, the middle portion is formed with a funnel-shaped discharge portion 34 is connected to the rear end of the extrusion network 35 and the front end of the grinding net 32, the diameter sharply increases to the rear end. Then, at the rear end of the grinding net 32 of the juice container 30, a strainer net 31 for closing the juice flow path 18 of the housing 10 is formed.

Several kinds of blades are formed inside the juice container 30. First, a triangular cutting blade 32c is formed inside the grinding net 32, and the cutting blade 32c has a triangular shape, and is parallel to each other along the inner circumferential surface in the longitudinal direction of the inner surface of the grinding net 32. Is formed. In particular, the cutting blade 32c has a height H _B of the cutting blade 32c located at the rear end of the grinding net 32 higher than the height H _F of the cutting blade 32c located at the tip. That is, the taper which is symmetrical with the taper of the grinding | pulverization net 32 is formed.

In addition, a radial spiral protrusion 34c is formed on an inner surface of the discharge part 34. The radial helix projection 34c has a protruding height PB of the helix projection 34c whose protruding height PF of the helix projection 34c located at the distal end thereof, that is, at the distal end of the discharging portion 34, is located at the rear end of the discharging portion 34. It should be relatively higher than) to ensure smooth transfer and discharge (see Figure 4b (b), Figure 4b (c)).

In addition, as shown in Figure 4a (b), the shape of the extrusion network 35 of the juice container 30 is varied. As shown in (a) of Fig. 4a (b), the groove-shaped groove 35h is formed along the inner circumferential surface at equal intervals parallel to the longitudinal direction of the extrusion network 35, and as shown in (b) of Fig. 4a (b). There are polygons having a polygonal cross section of the network 35 and a bent shape which is bent many times along the circumference in the longitudinal direction of the extrusion network 35 as shown in (c) of FIG. 4A (b).

The common point of (a), (b), (c) of Figure 4a (b) is located inside the extrusion network 35 between the extrusion screw 25S in close contact with the inner surface and the inner surface of the extrusion network 35. To form a predetermined space. Food is trapped in the space formed in this way, that is, the groove-shaped groove 35h, the polygonal edge portion, and the bent yaw portion 35s, so that the food does not rotate together with the rotation of the extrusion screw 25S. It is compressed and discharged in the discharge direction. Therefore, food is juiced in the extrusion network 35 which is the tip end of the juice container 30.

On the other hand, as shown in Figure 5, the grinding barrel 70 is the same as the juice container 30 described above, but the extrusion network 35 and the grinding net 32 and the strainer net 31 of the juice container 30 and Likewise, no through hole is formed as a network structure. Therefore, the portions of the pulverization barrel 70 corresponding to the extrusion net 35, the pulverization net 32 and the strainer net 31 of the juice container 30 are connected to the extrusion part 75, the pulverization part 72 and the locking part ( 71).

On the other hand, the crushing rod body 20 as shown in FIG. The grinding rod body 20 also has a shape corresponding to the inside of the juice container 30. Therefore, when looking at the shape of the grinding rod body 20, as the shape of the cylinder, the diameter of the tip portion has a cylindrical shape relatively smaller than the diameter of the rear end, and the middle portion is a conical shape connecting the rear end and the rear end of the tip end portion. do. Here, the tip end of the grinding rod body 20 is an extrusion screw portion 25, the middle portion is a radial discharge portion 24, the rear end portion to the fine grinding portion 23, the cut portion 22 and the cutting portion 21 Are distinguished.

Extruded screw portion 25 of the crushed rod body 20 is located in the extrusion network 35 of the juice container 30, the radial discharge portion 24 is discharged to the discharge portion 34 of the juice container (30) The fine grinding unit 23 and the fine cutting unit 22 are located inside the fine grinding blade 33 and the grinding net 32. In addition, the cutout portion 21 of the grinding rod body 20 is located at a portion corresponding to the food inlet 11 of the housing 10, and the square rotating shaft 26 is fixed to the rear end center of the grinding rod body 20. This rotation shaft 26 is connected to the reduction gear 61 of the drive unit 60 that penetrates the closing surface of the housing 10 and is attached to the rear end of the housing 10.

Several kinds of blades are formed in this grinding rod body 20. An extrusion screw 25S is formed around the tip extrusion screw 25 of the grinding rod 20, and a radial spiral 24S is formed around the radial discharge part 24, and the inside of the juice container 30 is formed. In the rear end of the grinding rod body 20 located in the pulverized grinding portion 23 is formed around the fine grinding spiral 23S, the circumference of the cutting section 22 that is the finely divided spiral 22S is formed , A cutting spiral 21S is formed around the cutout portion 21 corresponding to the inlet 11.

Here, the radial spiral 24S of the grinding rod 20 is in close contact with the radial spiral projection 34c of the juice container 30, and the spiral directions of the radial spiral projection 34c and the radial spiral 24S are opposite to each other. Is formed in the direction. On the other hand, the radial spiral projection 34c of the juice container 30, as described above, the height (P _F ) of the tip is higher than the height (P _B ) of the rear end. The radial spiral 24S also has a height S _F of the tip of the grinding rod 20 higher than the height S _B of the rear end.

The reason why the directions of the radial spiral protrusion 34c and the radial spiral 24S are formed in opposite directions to each other is due to the intersection of the radial spiral 24S of the grinding rod 20 and the radial spiral protrusion 34c of the juice container 30. The food is conveyed to increase the compressive force, the food conveyed by the extrusion screw is passed through the extrusion screw 25, the extrusion force is applied to the maximum to generate a lot of juice.

The reason why the tip is higher than the rear end in the radial spiral protrusion 34c and the radial spiral 24S is that this part is a tapered part in the juice container 30 and the grinding rod 20, and has a short circumferential length. On the other hand, the circumferential length of the rear end is long.

Therefore, the height of the spiral protrusion 34c and the radial spiral 24s of the tip portion must be high. In order for the food at the rear end to be transferred to the front end as it is, as shown in FIGS. 4B and 4B, the width of the passage (a gap between the juice container and the grinding rod) must be the same so that the bottleneck does not occur and is smoothly transferred. .

On the other hand, as shown in Figure 6, the helix angle of the pulverized grinding portion 23, the fine cut portion 22 and the cutting portion 21, which is the rear end of the grinding rod body 20 is the helix angle of the fine grinding spiral 23S ( R3) is the largest, the spiral angle R2 of the cut spiral 22S is the middle, and the spiral angle R1 of the cut spiral 21S is the smallest. In addition, the spiral angle R1 of the cutout portion 21 having a deep spiral length is small, and the spiral angle R3 of the finely divided portion 23 having a shallow depth of the spiral is increased for smooth transportation of food. That is, the depth of the spiral and the angle of the spiral is inversely proportional, so that food is continuously transferred without stagnation. That is, when the helix angle R is large, the helix pitch becomes wider.

On the other hand, the lid 40 is fastened to the binding protrusion 14F formed at the tip of the housing 10. A plurality of guiders 15 forming a plurality of guide grooves 13 are formed at the front end of the housing 10, and a binding protrusion 14F is formed at the front end of each of these guiders 15. As described above, a plurality of protrusions 37 are formed around the rear end of the juice container 30 and inserted into the guide grooves 13 of the housing 10, and the guide grooves are also formed at the rear end of the lid 40. A plurality of protrusions 47 to be inserted into 13 are formed, and the plurality of protrusions 47 are formed with slots 16 to be inserted into the binding protrusions 14F of the guider 15. Accordingly, when the rear end of the lid 40 is inserted into the front end of the housing 10 and rotates at a predetermined angle, the lid 40 is fastened to the front end of the housing 10.

A discharge port is formed in the center of the lid 40 as shown in Figure 7 and the left side thread is formed around the discharge port. Various nozzles 50 are fastened to this outlet. Then, the tip of the extrusion network 35 of the juice container 30 is tightly inserted into the fixing groove 44 formed around the rear end of the inner outlet of the lid 40 is fixed.

On the other hand, as shown in Figure 8, the nozzle 50 is also of various types. As shown in Figure 9, the juice nozzle (50a) is the discharge pipe 51 is located in the center, the female threaded screw fastening portion 52 is located around the discharge pipe 51 is located around the discharge port of the lid 40 It is fastened to the formed left-hand thread, the rubber member 53 is located between the screw fastening portion 52 and the rear end of the discharge pipe (51). On the other hand, the tip end of the extrusion screw 25 of the grinding rod body 20 is in close contact with the funnel-shaped rear end of the discharge pipe 51 of the juice nozzle 50. Therefore, the food conveyed to the front end by the extrusion screw portion 25 is to press the funnel-shaped rear end of the discharge pipe and the rubber member 53 is contracted by this pressing force while the food is discharged from the rear end of the discharge pipe 51 and the extrusion screw portion ( 25) exits between the tip and discharged through the discharge pipe 51 to the tip of the juice nozzle (50a).

When the juice is made by using the juice nozzle (50a), but when grinding and extruding food there are various types of nozzles depending on the application.

For example, as shown in (a) of FIG. 8, the sausage nozzle 50b is fastened to a left-hand thread formed around the outlet of the lid 40 by female threading at its rear end, and in the middle of the sausage nozzle 50b. The long nozzle is formed in the part. Such a sausage nozzle 50b is a nozzle suitable for making a kind of sausage, and when the end is sealed around the long nozzle, food is discharged through the discharge pipe 51 of the sausage nozzle 50b. Sausage is made by filling it inside.

Meanwhile, as illustrated in FIG. 10, the through hole 36 formed around the juice container 30 has an area of one end of the through hole 36 formed inside the juice container 30. It is relatively smaller than the area of the other end of the through-hole 36 formed on the outer surface of the. As such, the reason why the area of the through hole 36 extends from the inner surface of the juice container 30 to the outer surface is to prevent the accumulation of debris accumulated in the through hole to prevent clogging of the juice of vegetables and fruits to the outside of the juice container 30. This is to ensure a smooth discharge. The through hole 36 of such a structure has the purpose for increasing the juice rate.

The operation relationship of the juice grinder configured as described above will be described in detail.

When food, that is, vegetables and fruits, or meat and grains is introduced into the cutout portion 21 of the grinding rod 20 through the inlet 11 of the housing 10, the cutting spiral 21S of the cutout portion 21 rotates. While cutting by the movement to the cutting section 22 of the grinding rod body 20. At this time, when the food is vegetables and fruits, the juice generated in the process of cutting, cutting is moved along the juice flow path 18 formed on the inner lower surface of the housing 10 through the lower strainer 31 to the juice outlet 12 Is discharged through.

On the other hand, the food transferred to the cutting section along the cutting spiral 21S is finely crushed by the intersection of the cutting line 22S of the cutting section 22 and the triangular cutting blade 32c of the juice container 30 in front of the front. It is conveyed to the fine grinding part 23. Juice generated in this process is discharged to the juice flow path 19 through the through hole 36 of the grinding net 32 of the juice container (30).

And, the food conveyed to the fine grinding unit 23 is pulverized between the fine grinding spiral 23S of the grinding rod body and the fine grinding blade 33 of the cutting edge of the juice container 30 and the juice produced in this process A part of is discharged to the juice flow path 19 through the through hole 36 of the grinding net (32).

On the other hand, the residue transported to the radial discharge portion 24 of the grinding rod body 20 along the fine grinding spiral 23S of the fine grinding portion 23 is a radial spiral formed inside the discharge portion 34 of the juice container 30. The protrusion 34c is transferred to the extrusion screw by the intersection of the radial helix 24S of the radial discharge portion 24 of the grinding rod body.

The residue conveyed to the extrusion screw portion 25 is pushed to the tip of the extrusion screw along the groove 35h formed in the extrusion network 35 by the rotation of the extrusion screw. On the other hand, since the tip of the extruded screw 25S is in close contact with the rear end of the discharge pipe 51 of the juice nozzle 50, the residue remains at the tip of the extruded screw 25S. While rotating the debris to the tip to pressurize the discharge pipe 51 of the juice nozzle 50 while increasing the compression force. Then, the rubber member 53 of the juice nozzle 50 is pressed and contracted, and a space is formed at the front end of the extruded screw 25S and the rear end of the discharge pipe 51, and the residue is discharged through the discharge pipe 51 through the space. . In this process, the juice remaining in the residue as the residue is extruded at a high pressure is discharged into the juice flow path 19 through the through hole 36 of the extrusion network (35).

On the other hand, when the food grind grains and meat is replaced with a pulverization barrel 70 in place of the juice container (30). The grains and meats introduced through the inlet 11 of the housing 10 may be chopped, pulverized, and extruded to the outside, as in the above-described crushing and extruding action of the juice container 30 and the grinding rod body 20 described above. Discharged. At this time, the nozzle is selected according to the use and the lid is fastened to the tip.

As described in detail above, the juice grinder of the present invention is inserted into the extrusion screw of the grinding rod body or the extruded portion of the grinding barrel, the rotating shaft is rotated stably, so that the blade formed in the interior of the juice bucket and grinding barrel Since the spirals of the grinding bar do not collide with each other, the wear and tear of the blade can be prevented to extend the life of the juice grinder.

In addition, the juice grinder according to the present invention, as the grinding screw body is rotated by the rotating shaft as described above, so that the blade and the spiral of the grinding rod body are not collided with each other during the idle operation, so that the grinding rod body rotates with the rotating shaft. There is an advantage that can be minimized.

In addition, the juice grinder of the present invention has the advantage of increasing the juice rate by juiced food debris transferred to the extrusion screw unit at a high pressure once again.

In addition, there is an advantage that can greatly reduce the time to make because the extrusion screw portion increases the discharge pressure when pulling sausage or noodles using the juice grinder of the present invention.

Although the technical idea of the juice grinder of the present invention has been described above with the accompanying drawings, this is for illustrative purposes only and is not intended to limit the present invention.

1 is an exploded perspective view of a juice grinder according to an embodiment of the present invention,

Figure 2 is a cross-sectional view of the juice grinder shown in Figure 1 is fastened to the drive unit,

3 is a cross-sectional view of the housing shown in FIG.

(A) of Figure 4a is a front view of the juicer shown in Figure 2,

(A) is sectional drawing of the AA 'line | wire of (a).

(A) of Figure 4b is a partial cross-sectional view of the juice container shown in Figure 4a,

(B) of FIG. 4b is a longitudinal cross-sectional view of the B-B 'line | wire of FIG. 4b (a),

(B) of FIG. 4b is a longitudinal cross-sectional view of the C-C 'line of FIG. 4b (a),

Figure 4c is a side view of the juicer shown in Figure 4a,

Figure 4d is a perspective view showing the interior of the juice container shown in Figure 4a,

Figure 4e is a front perspective view of the juicer shown in Figure 4a,

5 is a front perspective view of the pulverization container installed in the juice grinder shown in FIG. 1,

6 is a front view of the grinding rod body shown in FIG.

7 is a cross-sectional view of the lid shown in FIG. 2,

8 is a perspective view showing embodiments of various nozzles mounted in place of the juice nozzle shown in FIG.

9 is a cross-sectional view of one embodiment of the juice nozzle shown in FIG.

10 is a cross-sectional view of the through hole formed around the juice container formed in FIG. 4A.

       ♠ Explanation of symbols on the main parts of the drawing ♠

  10 housing 11 inlet

  12: juice outlet 13: guide home

  14F, 14B: binding protrusion 15: guider

  16: slot 18, 19: juice

  20: grinding rod 21: cutout

  22: small part 23: pulverized part

  24: radial discharge portion 25: extrusion screw portion

  26: axis of rotation 30: juicer

  31: strainer 32: grinding net

  34: discharge part 33: grinding mill

  35: extrusion network 36: through hole

  37, 77: projection 40: lid

  44: fixing groove 48: slot

  50: nozzle 50a: juice nozzle

  50b: Sausage Nozzle 50c: Tteokbokki Nozzle

  50d: Noodle Nozzle 50e: Kalguksu Nozzle

  51 discharge pipe 52 screw connection

  53: rubber member 60: drive part

  61: reduction gear 70: grinding barrel

  100: juice grinder

Claims (13)

In the juice grinder for inputting food through the inlet formed in the upper portion of the housing, crushing and compressing the injected food, Located inside the housing, the tip end is a cylinder having a predetermined diameter, the extrusion screw is formed on the circumference, the rear end is relatively larger than the diameter of the front end and the spiral is formed around, the middle portion is a cone connecting the front end and the rear end Radial spiral is formed in the circumference of the shape, the rear end and the grinding rod body is fixed to the rotating shaft; A juice container covering the front end, the middle part, and the rear end of the grinding bar body to juice food by the rotation of the grinding bar body; A lid fastened to the front end of the housing and having a through hole formed at a center thereof; A nozzle fastened to a tip of the through hole of the lid; And a driving unit coupled to a rotating shaft of the grinding rod body penetrating the rear end of the housing to rotate the grinding rod body. The method of claim 1, The rear end of the pulverizing rod has a fine grinding part having a fine grinding spiral formed at its periphery, a fine cutting part having a fine cutting spiral formed at its rear periphery, and an incision having a cutting spiral formed at its rear periphery, and has a spiral angle of the fine grinding part spiral ( R3) is larger than the helix angle (R2) of the cut portion, the helix angle (R2) of the cut portion of the juice grinder, characterized in that larger than the helix angle (R1) of the cutting spiral. The method of claim 1, The juice container is a juice grinder consisting of an extrusion network formed with a plurality of through holes, a discharge portion formed with a radial projection on the inner wall of the cone, and a grinding net formed with a plurality of triangular cutting blades on the inner wall. The method of claim 3, wherein The through hole is formed in a portion corresponding to the extruded screw portion, the cut portion and the cut portion of the grinding rod body, the diameter of the through hole formed in the cut portion is relatively larger than the through hole formed in the extruded screw portion, Juicer grinder, characterized in that the diameter of the through-hole formed in the cutting is relatively larger than the through-hole formed in the cut portion. The method according to claim 3 or 4, The through hole has a juice grinder, characterized in that having a slope formed with a relatively larger diameter formed on the outer surface of the juice container than the diameter formed on the inner surface of the juice container. The method of claim 3, wherein A strainer is formed at a rear end of the juice container at a point corresponding to the cutout portion, wherein the strainer blocks the juice outlet of the housing. The method of claim 1, On the inner circumferential surface of the juicer is formed a plurality of triangular cutting blades along the length of the juicer at equal intervals, wherein the cutting blade is formed at a portion corresponding to the cutting portion of the grinding rod body, the tip height of the cutting blade Juicer grinder, characterized in that the height of the rear end is relatively higher. The method of claim 1, Radial protrusions are formed on the inner surface of the discharge portion of the juice container corresponding to the middle portion of the grinding rod body, the rear end height of the radial protrusion is formed relatively higher than the height of the front end, the radial formed in the middle portion of the grinding rod body The spiral is a juice grinder, characterized in that the height of the rear end is formed relatively higher than the height of the tip. The method of claim 8, Spiral direction of the radial projection formed in the discharge portion of the juice container and the spiral direction of the radial spiral formed in the middle portion of the grinding rod body juice extractor, characterized in that formed in the opposite direction. The method of claim 1, Grooves are formed on the inner surface of the tip of the juice container surrounding the extrusion screw of the grinding rod body at equal intervals, the grooves are extended in the longitudinal direction of the tip of the juice container. The method of claim 10, Juicer grinder, characterized in that the cross section of the front end of the juice container surrounding the extrusion screw is formed in a polygonal shape. The method of claim 1, Juicer grinder, characterized in that the extrusion screw of the grinding rod body is rotatably inserted into one end of the juice container to prevent the grinding rod body from shaking when the grinding rod body is rotated. The method of claim 1, The juice grinder is characterized in that the juice grinder is optionally replaced with a grind barrel.