KR101198036B1 - Juicer - Google Patents

Abstract

The present invention relates to a juicer, comprising: a drive unit having a housing, a drive shaft installed to be exposed to the outside of the housing, a material processing cylinder installed to be supported by the housing in front of the drive shaft, and standing on an upper surface of the material processing cylinder. In a juicer having a material input pipe formed and a material processing body installed inside the material processing cylinder to be coupled to the drive shaft, the drive shaft is a screw drive shaft, the shaft hole is formed over the entire length section and the screw in the shaft hole A cutting blade drive shaft installed to pass the drive shaft; The driving unit is a screw driving shaft to rotate the rotational force of the motor so that the screw driving shaft and the cutting blade driving shaft is rotated in the opposite direction between the motor and the shaft of the motor and the screw driving shaft, and between the shaft and the cutting blade driving shaft of the motor. And a power transmission unit configured to transmit the cutting blade drive shaft. The material processing cylinder is formed in a tubular shape, a material inlet is formed in the pipe wall, the material inlet is directed upward and the grinding cylinder portion is installed so that the screw drive shaft enters through one side opening, and a juice outlet is formed at the bottom. The juice discharge port is directed downward with a discharge container support plate extending from the discharge container body part to form a tubular discharge container body part and one side opening of the discharge container body part, and having a waste discharge port formed at one area. A discharge cylinder portion installed at the front of the pulverization cylinder portion and a tubular shape in which the front section is tapered, and a plurality of juice through holes are formed in the pipe wall, and the compression opening portion is installed so that the front opening communicates with the waste discharge port; The material processing body has a rod-shaped screw body portion formed to have a straight section having the same simple area and a tapered section tapered to gradually reduce the cross-sectional area, and a spiral screw formed over the straight section and the tapered section of the screw body section. A screw processing body coupled to the screw driving shaft so that the straight section of the screw body portion is disposed below the material inlet, a workpiece support plate having an axial coupling hole in the center, and a circumferential direction in the circumferential region of the shaft coupling hole. A cutting blade processing body having a cutting blade formed on the workpiece support plate so that the cutting blade is coupled to the cutting blade driving shaft through the shaft coupling hole so as to surround a straight section of the screw body at a lower side of the material inlet; Characterized in that. Thereby, the quantity of the material which can be juiced per hour can be increased, and the grinding | pulverization of a processed material can be made well.

Description

Juicer {Juicer}

The present invention relates to a juicer, and more particularly, to an apparatus for milling materials such as vegetables, fruits and the like, and finally processing the food in juice form.

Recently, once the process of grinding the material, the juicer for processing food in the form of juice is widely used.

Fig. 10 is an exploded perspective view of a conventional juicer, and Fig. 11 is a sectional view of main parts of a conventional juicer.

The conventional juicer, as shown in these figures, a drive unit 112 having a housing 111 installed perpendicular to the support surface, a drive shaft 112a provided to be exposed through the front portion of the housing 111, and a housing; A pair of support shafts 113 coupled to the front portion of the 111 and the moving material processing body 120 coupled to the drive shaft 112a and the moving material processing body 120 so as to rotate in engagement with each other. Installed driven material processing body 180, the material processing cylinder 130 detachably coupled to the support shaft 113, the material input pipe 191 formed in the material processing cylinder 130, and the material processing cylinder 130 It has a protective cover 115 that is installed to surround ().

The housing 111 is formed with a driven post prevention paper groove 111a in an adjacent region of the front drive shaft 112a.

The drive unit 112 includes a drive motor (not shown) and a reducer (not shown).

Each support shaft 113 has a predetermined separation section from the free end, and cover support grooves 113a are formed one over the entire circumference section.

The prime mover 120 has a helical helical gear portion 121 having a plurality of helical helical gears 121a formed thereon, and a motive screw portion 122 coupled to the front end of the helical helical gear portion 121.

The moving material processing body 120 having such a configuration is coupled to the driving shaft 112a through the driving helical gear portion 121 and supported by the driving force preventing paper groove (not shown) which the front end of the driving screw 122 is described later. It is installed as possible.

The driven material processing body 180 includes a driven helical gear part 181 having the same number of driven helical gears 181a as the driven helical gear 121a, and a driven gear shaft coupled to the rear end of the driven helical gear part 181. 182 and a driven screw portion 183 coupled to the front end of the driven helical gear portion 181.

In the driven material processing body 180 having the above configuration, the driven gear shaft 182 is supported by the driven prevention preventing groove 111a, and the driven pre-preventing groove groove (not shown) whose front end of the driven screw unit 183 is described later. It is installed to be supported on.

In addition, the driven material processing body 180 is installed so that the driven helical gear part 181 is engaged with the helical helical gear part 121 and the driven screw part 183 is engaged with the motive screw part 122 to rotate. .

The material processing cylinder 130 may include a grinding cylinder portion 131 detachably coupled to the pair of support shafts 113, a pair of grinding cylinder fixing grooves 132 formed on both sides of the grinding cylinder portion 131, respectively; And a pressurized cylinder portion 134 integrally formed in the grinding cylinder portion 131, and a discharge cylinder portion 140 detachably coupled to the pair of support shafts 113 in front of the pressurized cylinder portion 134.

The grinding cylinder portion 131 is formed with a workpiece receiving space that is shaped to fit the moving material processing body 120 and the driven material processing body 180.

In each grinding cylinder fixing groove 132, a grinding cylinder fixing groove 132a having an arc cross section is formed along the longitudinal direction of the grinding cylinder portion 131.

The pressing section 134 has a tapered front section, and a plurality of juice passing holes 134a are formed in the pipe wall.

The discharge barrel 140 has a juice discharge port 141a is formed in the bottom area, and the fixed tube portion 141b is formed on each side.

And the discharge cylinder portion 140 is formed in the front of the waste discharge outlet 141c, the left surface of the inner surface discharge outlet (141c), respectively, the nuclear power prevention prevention groove (not shown) and the driven power prevention prevention groove (not shown) Each of which is formed.

The material input pipe 191 is standing up on the upper surface of the discharge cylinder 140.

The protective cover 115 has a pair of engaging pins 115a formed on an inner surface thereof, and a guide tube 115b formed on an upper surface thereof.

The protective cover 115 having such a configuration is installed in the circumferential region of the material processing cylinder 130 such that the guide tube 115b communicates with the material injection tube 191.

Referring to the method of using a conventional juicer having such a configuration as follows.

First, the grinding shaft 131 is installed so that the support shaft 113 is inserted into the grinding barrel fixing groove 132a.

Next, the discharge cylinder 140 is installed so that the support shaft 113 passes through the fixed tube portion 141b.

Next, the protective cover 115 is installed so that each locking pin 115a is inserted into the cover support groove 113a of the support shaft 113.

In the state in which the protective cover 115 is installed, the installation state of the pulverization cylinder part 131 and the discharge cylinder part 140 may be stably maintained by the locking action between the locking pin 115a and the cover support groove 113a.

Next, a storage cup (not shown) is installed below the juice discharge port 141a of the discharge barrel 140.

Next, when power is supplied to the drive unit 112, the drive shaft 112a rotates.

When the drive shaft 112a rotates, the moving material processing body 120 and the driven material processing body 180 rotate while being engaged.

When the moving material processing body 120 and the driven material processing body 180 rotate, the material (vegetable or fruit) is introduced into the guide pipe part 115b.

The material introduced into the guide tube section 115b is put into the engaging region of the helical helical gear 121a and the driven helical gear 181a through the material input tube 191, and then pulverized.

The material pulverized by the primary material processing body 120 and the driven material processing body 180 is compressed by the interaction of the primary screw part 122, the driven screw part 183, and the pressing tube part 134, and the discharge cylinder part ( To 140).

Juice generated during the pressing operation is discharged through the juice discharge port 141b of the discharge cylinder 140, the compressed residue is discharged to the outside through the waste discharge port (142c).

However, according to the conventional juicer, since a space for entering the material is formed between the helical helical gear 121a and the driven helical gear 181a, the material input space is small, and thus the amount of material that can be juiced per hour is reduced. There was a problem.

In addition, since the processing material is pulverized by the engagement operation of the helical helical gear 121a and the driven helical gear 181a, and the rotational force is not transmitted from the driving unit 112 to the driven processing body 180, the processing material is not crushed well. There was a problem.

It is therefore an object of the present invention to provide a juicer which can increase the amount of juiceable material per hour and allow the grinding of the processed material to be performed well.

According to the present invention, the object is a drive unit having a housing, a drive shaft provided to be exposed to the outside of the housing, a material processing cylinder installed to be supported by the housing in front of the drive shaft, and the upper surface of the material processing cylinder In the juicer having a standing material injection tube and a material processing body installed inside the material processing cylinder to be coupled to the drive shaft, the drive shaft is a screw drive shaft, the shaft hole is formed over the entire length of the shaft hole and the A cutting blade driving shaft installed to pass the screw driving shaft; The driving unit is a screw driving shaft to rotate the rotational force of the motor so that the screw driving shaft and the cutting blade driving shaft in the opposite direction interposed between the motor and the shaft of the motor and the screw driving shaft and between the shaft and the cutting blade driving shaft of the motor. And a power transmission unit configured to transmit the cutting blade drive shaft. The material processing cylinder is formed in a tubular shape, a material inlet is formed in the pipe wall, the material inlet is directed upward and the grinding cylinder portion is installed so that the screw drive shaft enters through one side opening, and a juice outlet is formed at the bottom. The juice discharge port is directed downward with a discharge container support plate extending from the discharge container body part to form a tubular discharge container body part and one side opening of the discharge container body part, and having a waste discharge port formed at one area. A discharge cylinder portion coupled to the pulverization cylinder portion, and formed in a tubular shape in which the front section is tapered, and a plurality of juice through-holes are formed in the pipe wall, and the compression opening portion is installed so that the front opening communicates with the waste discharge port; The material processing body has a rod-shaped screw body portion formed to have a straight section having the same simple area and a tapered section tapered to gradually reduce the cross-sectional area, and a spiral screw formed over the straight section and the tapered section of the screw body section. A screw processing body coupled to the screw driving shaft so that the straight section of the screw body portion is disposed below the material inlet, a workpiece support plate having an axial coupling hole in the center, and a circumferential direction in the circumferential region of the shaft coupling hole. A cutting blade processing body having a cutting blade formed on the workpiece support plate so that the cutting blade is coupled to the cutting blade driving shaft through the shaft coupling hole so as to surround a straight section of the screw body at a lower side of the material inlet; It is achieved by a juicer characterized in that.

Wherein the screw has a first linear section screw formed in a straight section of the screw body portion and a linear section of the screw body section so as to be parallel with the primary linear section screw so that the feeding pressure applied to the processing material is increased and thus the juice amount is increased. A secondary linear section screw formed on the first connection screw, a primary connecting screw formed in a straight line so as to reach a tapered section of the screw body portion from the front end of the primary linear section screw, and the screw body portion from the front end of the secondary linear section screw. A secondary connecting screw formed to reach a tapered section and parallel to the primary connecting screw, a primary tapered section screw formed to reach a front end of the screw body from the front end of the primary connecting screw, and the secondary connecting screw Secondary taper sections formed to reach the front end of the screw body portion from the front end And a primary auxiliary screw formed parallel to the primary connecting screw between the right side region of the primary connecting screw and the secondary connecting screw, and between the right side region of the secondary connecting screw and the primary connecting screw. It is preferable to include a secondary auxiliary screw formed to be parallel to the secondary connection screw.

The secondary linear section screw is preferably started at least one time later than the primary linear section screw so that the space to which the material can be added is increased to increase the juice amount.

In addition, the primary auxiliary screw has a separation distance between each forming start point and the secondary linear section screw is adjacent to the primary connecting screw so that the pressing operation by the primary auxiliary screw and the secondary auxiliary screw can be made efficiently. A plurality of sides are formed so as to be larger; The secondary auxiliary screw is preferably formed in plural so that the distance between each forming start point and the primary linear section screw is larger adjacent to the secondary connecting screw.

In addition, a pair of cutting blades are formed with a phase difference of 180 degrees, and a material input opening is formed in front of each of the cutting blades so as to increase the amount of juice to increase the amount of material to be added. It is preferable.

Therefore, according to the present invention, a space through which the material can enter between the screw and the cutting blade is formed, thereby increasing the material input space, thereby increasing the amount of juiceable material per hour.

In addition, since the processing material is pulverized by the cutting operation of the cutting blade and the rotational force is transmitted from the driving unit to the screw processing body and the cutting blade processing body, the processing material may be crushed well.

1 is a perspective view of the juicer in accordance with an embodiment of the present invention,
2 is an exploded perspective view of a juicer according to an embodiment of the present invention;
3 and 4 are each a detailed view of the screw processing body shown in FIG.
Figure 5 is a perspective view of the cutting blade shown in Figure 2,
6 and 7 are views showing the operating state of the power transmission unit of the juicer according to the embodiment of the present invention, respectively;
8 is an exploded perspective view of the discharge container and the waste discharge control region of the juicer according to the embodiment of the present invention;
9 is a cross-sectional view of the combined discharge outlet and the waste discharge control region of the juicer according to an embodiment of the present invention;
10 is an exploded perspective view of a conventional juicer,
11 is a sectional view of main parts of a conventional juicer.

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

1 is a combined perspective view of a juicer according to an embodiment of the present invention, Figure 2 is an exploded perspective view of a juicer according to an embodiment of the present invention, Figures 3 and 4 of the screw processing body shown in Figure 2, respectively 5 is a perspective view of the cutting blade processing body shown in Figure 2, Figure 6 and Figure 7 is a view showing the operating state of the power transmission unit of the juicer according to an embodiment of the present invention, Figure 8 Is an exploded perspective view of the discharge container and the waste discharge control region of the juicer according to an embodiment of the present invention, Figure 9 is a cross-sectional view of the combined discharge container and waste discharge control region of the juicer according to an embodiment of the present invention.

The juicer according to the embodiment of the present invention, as shown in these figures, the drive unit 20 having a housing 11, a drive shaft 21 provided to be exposed to the outside of the housing 11, and the housing 11 A pair of support tubes 12 installed at the front of the support shaft, one support shaft 13 installed at each support tube 12, a lock lever 14 coupled to the front end of the support shaft 13, and a support tube ( 12, a stopper member 15 coupled to the rear end, a pressurizing member 16 coupled to the rear end of the support shaft 13, a power supply switch 19 provided on the outer surface of the housing 11, and a drive shaft ( The material processing cylinder 30 is installed to be supported by the housing 11 in front of the 21, the material introduction tube 91 standing on the upper surface of the material processing cylinder 30, and the material to be coupled to the drive shaft 21 The material processing body 60 provided in the common 30 and the waste discharge | release control part 50 provided in the material processing cylinder 30 are included.

The drive unit 20 includes a motor 22 and a power transmission unit 23 that transmits the rotational force of the motor 22 to the drive shaft 21 in addition to the drive shaft 21.

The drive shaft 21 has a screw drive shaft 21a and a cutting blade drive shaft 21b in which shaft holes 21c are formed over the entire length section.

The screw drive shaft 21a is installed to pass through the shaft hole 21c.

The motor 22 has a motor shaft 22a.

The power transmission unit 23 has a helical motor shaft gear 23a formed at the end of the motor shaft 22a, a cutting blade drive shaft gear 23b formed on the outer surface of the cutting blade drive shaft 21b, and a screw drive shaft ( The first auxiliary shaft 23c and the second auxiliary shaft 23d installed inside the housing 11 so as to be arranged side by side with 21a) and the first auxiliary shaft 23c so as to be engaged with the motor shaft gear 23a. Helical type first auxiliary shaft gear 23e, driven first auxiliary shaft gear 23f provided to the first auxiliary shaft 23c in front of the first first auxiliary shaft gear 23e, and driven first auxiliary shaft 23e. 23 d of screw drive shaft gears 23g provided in the screw drive shaft 21a so as to mesh with the shaft gear 23f, and the second auxiliary shaft 23d to be engaged with the cutting blade drive shaft gear 23b and the driven first auxiliary shaft gear 23f, respectively. ) Has a second auxiliary shaft gear (23h).

The operation of the power transmission unit 23 having such a configuration is as follows.

First, when the motor shaft 22a rotates in the counterclockwise direction (see 1 in FIGS. 6 and 7), the primary first auxiliary shaft gear 23 e rotates in the clockwise direction (see 2 in FIGS. 6 and 7).

When the primary first auxiliary shaft gear 23e rotates clockwise, the driven first auxiliary shaft gear 23f rotates clockwise (see 3 in FIGS. 6 and 7).

When the driven first auxiliary shaft gear 23f rotates in the clockwise direction, the screw drive shaft gear 23g rotates in the counterclockwise direction (see? In FIGS. 6 and 7).

When the screw drive shaft gear 23g rotates in the counterclockwise direction, the screw drive shaft 21a rotates in the counterclockwise direction (see? In FIGS. 6 and 7).

On the other hand, when the driven first auxiliary shaft gear 23f rotates clockwise, the second auxiliary shaft gear 23h rotates counterclockwise (see 6 in FIGS. 6 and 7).

When the second auxiliary shaft gear 23h rotates counterclockwise, the cutting blade drive shaft gear 23b and the cutting blade drive shaft 21b rotate clockwise (see? And 8 in Figs. 6 and 7).

Accordingly, the power transmission unit 23 is interposed between the shaft of the motor 22 and the screw driving shaft 21a, and between the shaft of the motor 22 and the cutting blade driving shaft 21b, and the cutting blade driving shaft 21a and the cutting blade driving shaft ( The rotational force of the motor 22 can be transmitted to the screw drive shaft 21a and the cutting blade drive shaft 21b so that 21b) rotates in the opposite direction.

Each support tube 12 is installed to be parallel to the drive shaft 21.

Both ends of the support shaft 13 are exposed to the outside of each support tube 12, and are installed to be rotatable with respect to each support tube 12.

The lock switch lever 17a extends from the lock lever body portion 14a and the lock lever body portion 14a so as to be disposed perpendicularly to the lock lever body portion 14a.

The lock lever 14 having this configuration is coupled to the front end of each support shaft 13 through the lock lever body portion 14a so that the lock lever body portion 14a is disposed along the longitudinal direction of the support shaft 13. .

The locking piece 14b is formed to slide along the entrance guide surface 33c when the lock lever body portion 14a rotates toward the discharge cylinder portion 40.

The stopper member 15 is implemented using a nut that is screwed to the support tube 12. The stopper member 15 prevents the support tube 12 from being separated from the housing 11.

The power supply switch 19 opens and closes between the driver 20 and a predetermined power voltage.

The material processing cylinder 30 has a tubular grinding cylinder 31, a discharge cylinder 40 installed in front of the grinding cylinder 31, and a pair of grinding cylinders formed on each side of the grinding cylinder 31, respectively. A fixed groove portion 32, a pair of discharge cylinder fixing grooves 33 formed on both sides of the discharge cylinder portion 40, and a crimping cylindrical portion of the tubular shape interposed between the grinding cylinder portion 31 and the discharge cylinder portion 40 Has 34.

The grinding cylinder part 31 is provided with the material inlet 31a in the pipe wall.

The grinding cylinder part 31 which has such a structure is provided so that the material inlet 31a may face upward and the screw drive shaft 21a may enter through one side opening.

The discharge cylinder part 40 has a discharge cylinder body part 41 of a tubular shape, and the discharge cylinder support plate 42 extended from the discharge cylinder body part 41 so that the one side opening of the discharge cylinder body part 41 may be sealed. .

The discharge barrel body 41 has a juice discharge port 41a formed at the bottom thereof.

The discharge bin support plate 42 is formed with a waste discharge port 42a in the center region.

The waste discharge outlet 42a is formed in a pair with a phase difference of 180 degrees.

The discharge cylinder portion 40 having such a configuration is provided in front of the grinding cylinder portion 31 so that the juice discharge port 41a faces downward.

In each grinding cylinder fixing groove 32, a grinding cylinder fixing groove 32a is formed along the longitudinal direction of the grinding cylinder portion 31 in the form of an arc cross section.

Each discharge cylinder fixing groove 33 is formed with a discharge cylinder fixing groove 33a and a locking groove 33b.

The discharge cylinder fixing groove 33a is formed to be aligned with the grinding cylinder fixing groove 32a in the form of an arc cross section.

The locking groove 33b extends upward from the grinding cylinder fixing groove 32a so as to communicate with the grinding cylinder fixing groove 32a.

In addition, the engaging groove 33b is formed with an entry guide surface 33c inclined downward from the outer surface of the discharge cylinder fixing groove 33 toward the front end of the lock lever body portion 14a.

The pressing section 34 has a tapered front section, and a plurality of juice passing holes 34a are formed in the pipe wall.

The crimping cylindrical portion 34 having such a configuration is provided so that the front opening communicates with the waste outlet 42a.

The material input pipe 91 is standing up on the upper surface of the discharge cylinder portion 40 so as to communicate with the material inlet 31a.

The material processing body 60 has the screw processing body 70 couple | bonded with the screw drive shaft 21a, and the cutting blade processing body 80 couple | bonded with the cutting blade drive shaft 21b.

The screw processing body 70 has a rod-shaped screw body portion 71 and a screw 72 formed on the screw body portion 71.

The screw body portion 71 is formed to have a straight section 71a having the same simple area and a tapered section 71b tapered to gradually reduce the cross-sectional area.

The screw body 71 is formed with a screw support groove 71c at the front end.

The screw 72 is screwed from the front end of the primary linear section screw 72a and the secondary linear section screw 72b and the primary linear section screw 72a formed in the straight section 71a of the screw body portion 71. The taper section 71b of the screw body portion 71 from the front end of the primary connecting screw 72c and the linear straight section screw 72b formed so as to reach the tapered section 71b of the body portion 71. The secondary connecting screw 72d formed to reach the upper side, the primary auxiliary screw 72e formed between the right side region of the primary connecting screw 72c and the secondary connecting screw 72d, and the secondary connecting screw 72d. Secondary auxiliary screw 72f formed between the right side region of the primary connection screw 72c and the primary taper section screw formed so as to reach the front end of the screw body portion 71 from the front end of the primary connecting screw 72c. 72g and a secondary tapered section screw 72h formed to reach the front end of the screw body portion 71 from the front end of the secondary connecting screw 72d. It has.

The secondary straight section screw 72b is formed to start at least one turn later than the primary straight section screw 72a and parallel with the primary straight section screw 72a.

The secondary connecting screw 72d is formed to be parallel to the primary connecting screw 72c.

The primary auxiliary screw 72e is formed to be parallel to the primary connecting screw 72c.

Further, a plurality of primary auxiliary screws 72e are formed such that the separation distance between each forming start point and the secondary linear section screw 72b becomes smaller as the distance from the primary connecting screw 72c becomes smaller (1 in Fig. 3). 〉 ②〉 ③ in order.

The secondary auxiliary screw 72f is formed to be parallel to the secondary connecting screw 72d.

Further, a plurality of secondary auxiliary screws 72f are formed such that the distance between each forming start point and the primary linear section screw 72a becomes smaller as the distance from the secondary connecting screw 72d becomes smaller (4 in Fig. 4). 〉 ⑤〉 ⑥ in big order).

The screw processing body 70 having such a configuration is coupled to the screw drive shaft 21a so that the straight section of the screw body portion 71 is disposed below the material inlet 31a, and the screw support groove 71c and the bush 73 are disposed. It is installed to be supported by the screw rod narrow diameter portion (51b) to be described later through).

The cutting blade processing body 80 includes a workpiece support plate 81 having an axial coupling hole 81a formed at the center thereof, and a workpiece support plate 81 so as to be disposed along the circumferential direction in the circumferential region of the axial coupling hole 81a. It has the cutting blade 82 formed in it.

A pair of cutting blades 82 are formed with a phase difference of 180 degrees, and material injection openings 82a are formed in front of the rotation direction of each cutting blade 82, respectively.

The cutting blade processing body 80 having such a configuration includes a cutting blade driving shaft through the shaft coupling hole 81a so that the cutting blade 82 surrounds the straight section of the screw body 71 at the lower side of the material inlet 31a. 21b).

Waste discharge control unit 50 is a screw rod (51) installed to pass through the discharge barrel support plate 42 in the space between the waste discharge outlet (42a), the fastening member 52 and the stopper coupled to the screw rod (51) It has the member 53.

The threaded rod 51 is formed with a screw thread in the front region of the outer surface, and a threaded rod supporting plate 51a and a threaded rod narrow portion 51b are formed at the rear end thereof.

The screw rod 51 having such a configuration is installed so that the screw rod support plate 51a is supported on the front surface of the placement tube support plate 42, and the screw rod narrow diameter portion 51b enters the discharge cylinder portion 40.

The tightening member 52 is formed in a tubular shape having a tapered section in the rear region, and is screwed to the screw rod 51 through the inner surface of the tapered section.

The fastening member 52 having such a configuration serves to prevent the stopper member 53 from moving along the direction away from the waste discharge port 42a.

The closure member 53 is a pair of wing portions extending from the closure member body portion 53a so as to cooperate with the closure member body portion 53a of the tubular shape and the closure member body portion 53a to form an approximately bow tie shape ( 53b).

The closure member 53 having such a configuration is installed in the screw rod 51 such that the closure member body portion 53a is inserted into the screw rod 51 and the wing portion 53b seals the residue outlet 42a, respectively.

The closure member 53 having such a configuration is manufactured using an elastic material such as silicone rubber.

Referring to the operation of the juicer according to an embodiment of the present invention having such a configuration as follows.

First, in the state in which the screw processing body 70 and the cutting blade processing body 80 are installed, the grinding tube part 31 is installed so that the support tube 12 is inserted into the grinding cylinder fixing groove 32a.

Next, the pressing cylinder part 34 is provided so that the screw processing body 70 may enter into the inside of the pressing cylinder part 34.

Next, the discharge cylinder portion 40 is installed so that the lock lever body portion 14a is inserted into the discharge cylinder fixing groove 33a.

Next, the locking lever 14 is rotated so that the locking piece 14b enters the locking groove 33b along the entry guide surface 33c. When the locking piece 14b moves along the entrance guide surface 33c, the discharge cylinder portion 40 is pressed toward the housing 11.

In the state where the engaging piece 14b enters the engaging groove 33b, the installation state of the grinding cylinder part 31 and the discharge cylinder part 40 is stably established by the engaging action between the engaging piece 14b and the engaging groove 33b. Can be maintained.

Next, when power is supplied to the drive unit 20 by operating the power supply switch 19, the drive shaft 21 rotates.

As the drive shaft 21 rotates, the screw processing body 70 and the cutting blade processing body 80 rotate in opposite directions to each other.

When the screw processing body 70 and the cutting blade processing body 80 rotate in opposite directions to each other, a material (vegetable or fruit) is introduced through the material input pipe 91.

The processing material introduced through the material input pipe 91 is supplied to the cutting blade 80 through the material inlet 31a.

The processing material supplied to the cutting blade processing body 80 enters the material injection opening 82a, and the processing material entering the material injection opening 82a is crushed by the cutting operation of the cutting blade 82.

Next, the processing material pulverized by the cutting blade 82 is conveyed toward the pressing cylinder portion 34 by the primary straight section screw 72a.

When the processing material reaches the secondary straight section screw 72b, it is conveyed toward the crimping cylinder 34 by the primary straight section screw 72a and the secondary straight section screw 72b. While being transported by the primary straight section screw 72a and the secondary straight section screw 72b, the processing material is crushed by the interaction with the pressing barrel 34, and the juice is partially produced during the pulverizing operation.

When the processing material reaches the primary connecting screw 72c and the secondary connecting screw 72d, the primary connecting screw 72c, the secondary connecting screw 72d, the primary auxiliary screw 72e and the secondary auxiliary screw ( Due to the interaction between 72f) and the pressing barrel portion 34, the processing material is pressed, and juice is produced during the pressing operation.

The primary connecting screw 72c is formed such that the separation distance between each forming start point and the secondary linear section screw 72b becomes smaller as the primary auxiliary screw 72e moves away from the primary connecting screw 72c. The processing material passing through the right side region of the N) is evenly distributed in the left and right regions of the primary auxiliary screw 72e, and thus, the pressing operation by the primary auxiliary screw 72e can be efficiently performed.

Since the secondary auxiliary screw 72f is formed to be smaller from the secondary connecting screw 72d, the separation distance between each forming start point and the primary linear section screw 72a becomes smaller. The processing material passing through the right region of 72d) is evenly distributed in the left and right regions of the secondary auxiliary screw 72f, respectively, whereby the pressing operation by the secondary auxiliary screw 72f can be efficiently performed.

The resulting juice is passed through the juice through hole (34a) and then dropped through the juice outlet (41a) is collected in a storage cup (not shown).

Meanwhile, the remaining processed material residue is conveyed by the first tapered section screw (72g) and the second tapered section screw (72h) and then discharged through the dregs outlet (42a).

As described above, according to the embodiment of the present invention, a space for entering the material is formed between the screw 72 and the cutting blade 82, thereby increasing the material input space, thereby increasing the amount of material that can be juiced per hour. You can do it.

And the processing material is pulverized by the cutting operation of the cutting blade 82 and because the rotational force is transmitted from the drive unit 20 to the screw processing body 70 and the cutting blade processing body 80, the processing material can be crushed well. Will be.

In addition, by forming the screw 72 to include the primary secondary screw 72e and the secondary secondary screw 72f, the conveying pressure applied to the processing material is increased, thereby increasing the juice amount.

In addition, by allowing the secondary linear section screw 72b to be started at least one time later than the primary linear section screw 72a, the space for the input of the material is increased to increase the juice amount.

In addition, a plurality of primary auxiliary screws 72e are formed so that the distance between each formation starting point and the secondary linear section screw 72b becomes larger adjacent to the primary connecting screw 72c. The right area of the primary connecting screw 72c is formed by forming a plurality of secondary auxiliary screws 72f such that the distance between the straight line section screws 72a becomes larger adjacent to the secondary connecting screw 72d. The processing material passing through is evenly distributed in the left and right regions of the primary auxiliary screw 72e, and the processing material passing through the right region of the secondary connecting screw 72d is equally distributed in the left and right regions of the secondary auxiliary screw 72f, respectively. In this way, the pressing operation by the primary auxiliary screw 72e and the secondary auxiliary screw 72f can be efficiently performed.

In addition, by forming the material input opening 82a in front of the rotational direction of each cutting blade 82, the space to put the material is increased to increase the amount of juice.

11, 111: housing 12, 112: support tube
13, 113: support shaft 14, 114: lock lever
20, 112: drive unit 23: power transmission unit
30, 130: material processing cylinder 31, 131: grinding cylinder
32, 132: grinding cylinder fixing groove 33, 133: discharge cylinder fixing groove
34, 134: compression cylinder 40, 140: discharge cylinder
50: residue discharge control unit 60: material processing body
70: screw processing body 71, 171: screw body
72, 172: screw 80: cutting blade
81: workpiece support plate 82: cutting blade

Claims (5)

A drive unit having a housing, a drive shaft installed to be exposed to the outside of the housing, a material processing cylinder installed to be supported by the housing in front of the drive shaft, a material introduction tube standing on an upper surface of the material processing cylinder, and the drive shaft In the juicer having a material processing body installed inside the material processing cylinder to be coupled to,
The drive shaft includes a screw drive shaft and a cutting blade drive shaft is formed in the shaft hole is formed over the entire length and the screw drive shaft passes through the shaft hole;
The driving unit is a screw driving shaft to rotate the rotational force of the motor so that the screw driving shaft and the cutting blade driving shaft is rotated in the opposite direction between the motor and the shaft of the motor and the screw driving shaft, and between the shaft and the cutting blade driving shaft of the motor. And a power transmission unit configured to transmit the cutting blade drive shaft.
The material processing cylinder is formed in a tubular shape, a material inlet is formed in the pipe wall, the material inlet is directed upward and the grinding cylinder portion is installed so that the screw drive shaft enters through one side opening, and a juice outlet is formed at the bottom. The juice discharge port is directed downward with a discharge container support plate extending from the discharge container body part to form a tubular discharge container body part and one side opening of the discharge container body part, and having a waste discharge port formed at one area. A discharge cylinder portion installed at the front of the pulverization cylinder portion and a tubular shape in which the front section is tapered, and a plurality of juice through holes are formed in the pipe wall, and the compression opening portion is installed so that the front opening communicates with the waste discharge port;
The material processing body has a rod-shaped screw body portion formed to have a straight section having the same simple area and a tapered section tapered to gradually reduce the cross-sectional area, and a spiral screw formed over the straight section and the tapered section of the screw body section. A screw processing body coupled to the screw driving shaft so that the straight section of the screw body portion is disposed below the material inlet, a workpiece support plate having an axial coupling hole in the center, and a circumferential direction in the circumferential region of the shaft coupling hole. A cutting blade processing body having a cutting blade formed on the workpiece support plate so that the cutting blade is coupled to the cutting blade driving shaft through the shaft coupling hole so as to surround a straight section of the screw body at a lower side of the material inlet; Juicer, characterized in that. The method of claim 1,
The screw is a first straight section screw formed in a straight section of the screw body portion, a second straight line section screw formed in a straight section of the screw body portion parallel to the first straight section screw, and a shear of the first straight section screw. A first connection screw formed in a straight line to reach a tapered section of the screw body from the second connection, and a second connection formed to reach a tapered section of the screw body section and parallel to the first connecting screw from a front end of the second straight section screw. A screw, a primary tapered section screw formed to reach the front end of the screw body portion from the front end of the primary connecting screw, and a secondary tapered section screw formed to reach the front end of the screw body part from the front end of the secondary connecting screw; And the primary connection between the right side region of the primary connecting screw and the secondary connecting screw. And a secondary auxiliary screw formed to be parallel to the secondary connection screw between the primary auxiliary screw formed to be parallel to the screw, and the right connection region of the secondary connection screw and the primary connection screw. The method of claim 2,
And said second straight section screw starts at least one turn later than said first straight section screw. The method according to claim 2 or 3,
The primary auxiliary screws are formed in plural such that the distance between each forming start point and the secondary linear section screw becomes smaller as the distance from the primary connecting screw becomes smaller;
The secondary auxiliary screw is a plurality of juicers, characterized in that formed so that the distance between each forming start point and the first linear section screw becomes smaller as the distance from the secondary connecting screw. 4. The method according to any one of claims 1 to 3,
The pair of cutting blades are formed with a phase difference of 180 degrees, the juicer, characterized in that the material injection opening is formed in front of the rotation direction of each cutting blade.

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