KR200472867Y1 - Vegetables Material Processing Device - Google Patents

Abstract

The present invention relates to a food material processing apparatus, and more particularly, to a food material processing apparatus comprising a housing, a drive unit having a drive shaft installed to be exposed through an upper surface of the housing, a machining rotator coupled to the drive shaft, A plurality of juice frames and a plurality of juice passage holes arranged in parallel with each other in this order, and a juice screen body coupled to the juice frame, and a juice descending protrusion formed on the inner surface of the juice screen so as to be disposed along the length direction of the juice screen body And a guide rib which is disposed so as to surround the machining rotator in a state where the guide rib has a smaller diameter at both ends of the rifle body toward the housing and cooperates with the machining rotator when the machining rotator rotates, A juice passage provided so as to squeeze the food material entering the space between the solids outlet and the juice outlet And a discharge port for discharging the juice and solids generated when the processing rotary body and the juice container are squeezed from the food material through the juice discharge port and the solids discharge port and being supported by the housing, And a feeding portion for feeding the food material, which has been introduced through the material inlet, from the upper side into the region between the juice passing through the processing rotary body and being supported by the juice container, Sectional outer surface section having a smallest cross-sectional area so that a portion having a reduced cross-sectional area does not appear while reaching a section end point from a start point of the section, and a cross-sectional area having a smallest cross- While reaching the section end point Sectional outer surface section so that a transfer operation is performed from an upper end of the rotary body section toward a lower end of the rotary body section, A machining screw formed on an outer surface of the section reducing outer surface section; And the upper juice descending guide rib is formed in a trapezoidal cross-sectional shape in an area opposite to the section increasing outer surface section and is formed so that the height of the trapezoid decreases gradually toward the housing. Thereby, the downward guidance function of the food material can be improved and the processing efficiency can be improved.

Description

[0002] Food materials processing apparatuses

The present invention relates to a food material processing apparatus, and more particularly, to a device for crushing a material such as vegetables and fruits, and finally processing a food in a juice form or a chopped form.

A food material processing apparatus is used in which a material is compressed so as to produce solid matter and juice, and the resulting juice is separated and recovered.

Fig. 24 is a front view of a conventional food material processing apparatus, Fig. 25 is a perspective view of a chopped container unit according to a conventional food material processing apparatus, Fig. 26 is a sectional view of a chopped container unit according to a conventional food material processing apparatus, Sectional view showing the installation state of the chopping container unit according to the processing apparatus.

The conventional food material processing apparatus includes a housing 111 and a drive unit 120 having a drive shaft 121 exposed to the outside of the housing 111 and a drive unit 120 coupled to the drive shaft 121, A juice container section 140 and a chopper container section 190 installed to be supported by the housing 111 and a juice container 160 installed inside the juice container section 140; And an input unit 180 installed to be supported by the juice container unit 140 or the chopper container unit 190.

The housing part 111 has a container part seating surface 111a formed on the upper surface thereof.

The driving unit 120 has a motor (not shown) in addition to the driving shaft 121 and a driving unit (not shown) for transmitting the rotational force of the motor to the driving shaft 121, respectively.

The machining rotation body 130 is installed to be coupled to the drive shaft 121 in the juice container 160.

The juice container portion 140 has a concave shaped discharge tube portion 150 and a solids discharge tube portion 141 and a juice discharge tube portion 142 coupled to the lower end of the discharge tube portion 150.

The juice container portion 140 having such a configuration is installed to be supported by the container portion seating surface 111a through the discharge tube portion 150. [

The chopping container unit 190 has a chopped barrel portion 191 having a concave shape and a supporting skirt portion 192 formed in the chopper barrel portion 191. The chopping barrel discharging pipe portion 193 and the handle portion 194, And a chopping-down guide rib 195 formed on the inner surface of the chopper cylinder 191.

The chopper cylinder 191 is formed to have an inner space in the form of an upper horizontal lowering plate and a chopping revolver passage through hole 191a is formed on the floor surface.

The chopping block 191 is provided with a chopping solids discharge hole 191b at the lower end of the side portion and a chopping juice discharge hole 191c is formed in the upper region of the chopping solids discharge hole 191b so as to be connected to the chopping solids discharge hole 191b Respectively.

The chopper drain pipe portion 193 is formed so as to communicate with the chopped solid matter discharge hole 191b and the chopping juice discharge hole 191c.

The condensed juice discharge hole 191c is formed in a straight shape.

The chopping-down guide ribs 195 are formed in a rectangular cross-sectional shape having a uniform sectional size.

The chopper container unit 190 having such a configuration is installed to be supported by the container unit seating surface 111a through the support skirt unit 192. [

The juice container 160 may be formed to have a juice screen having a plurality of juice passage holes and a juice frame for supporting the juice screen.

The juice container 160 having such a configuration is installed inside the juice container portion 140 so that the juice screen body surrounds the processing rotary body 130.

The charging portion 180 has a cover plate portion 182 and a charging tube portion 181 formed on the upper surface of the cover plate portion 182 so as to stand upright.

The insertion portion 180 having such a configuration is engaged with the upper end of the chopping bar side portion 192 so that the lid plate portion 182 seals the opening region of the discharge cylinder 140.

A method of using a conventional food material processing apparatus having the above-described configuration will be described below.

Hereinafter, the method of using the juice-shaped food to be processed will be described.

First, the juice container unit 140, the juice bottle 160, the processing rotary body 130, and the input unit 180 are sequentially installed. Here, the charging unit 180 may be coupled to the juice container 140 through an engagement protrusion (not shown) formed on the upper surface of the outer surface of the discharge tube 150.

Next, when the on-off switch (not shown) is turned on to supply power to the driving unit 120, the driving shaft 121 rotates.

When the drive shaft 121 rotates, the machining rotation body 130 rotates.

Next, food ingredients (such as vegetables) are fed through the feed pipe 181.

The introduced food materials are squeezed by the processed rotator 130 and the juice bottle 160, thereby producing juice and solids.

The resulting juice and solids are separated by the juice bottle 160.

The separated juice is discharged to the outside through the juice discharge pipe portion 142, and the separated solids are discharged to the outside through the solids discharge pipe portion 141.

Hereinafter, a description will be given of a method of using the food to be processed in the form of chopped food.

First, the charging unit 180, the rotating body 130, the juice container 160, and the juice container unit 140 are sequentially separated.

Next, the chopping container unit 190, the processing rotary body 130, and the loading unit 180 are sequentially installed. Here, the mounting of the machining rotation body 130 is made to be coupled to the drive shaft 121 through the multiplying rotary body passing hole 191a. The charging unit 180 may be coupled to the chopping container unit 190 through a latching protrusion 191d formed on the upper surface of the outer surface of the chopper cylinder 191. [

Next, when the on-off switch (not shown) is turned on to supply power to the driving unit 120, the driving shaft 121 rotates.

When the drive shaft 121 rotates, the machining rotation body 130 rotates.

Next, a food material (such as garlic) is injected through the inlet tube portion 181.

The introduced food material is squeezed by the machining rotator 130 and the chopper cylinder 191, thereby producing juice and solids.

The food material is guided in the downward direction, that is, toward the housing 111, by the chopping-down descending guide rib 195. [

The generated solids pass through the agglomerated solids discharge hole 191b and are discharged to the outside through the agitator discharge pipe portion 193 (a part of the generated solids is discharged to the outside through the agitator discharge pipe portion through the agitator discharge hole Lt; / RTI >

The generated juice passes through the chop juice outlet hole 191c and is discharged to the outside through the chopper outlet pipe portion 193 (a part of the generated juice passes through the chopper solids discharge hole and is discharged to the outside through the chopper outlet pipe portion Lt; / RTI >

A conventional food material processing apparatus having the above-described configuration is disclosed in Utility Model Registration Application No. 1138 (name of design: an auxiliary container for compaction of a vertical type electric drink maker) in 2011.

However, according to the conventional food material processing apparatus, the chopper cylinder portion 191 is formed to have an inner space of a shape of a supersonically lowered shape, and the chopping-down descending guide ribs 195 are formed in a rectangular cross- There is a problem that the guiding function of the food material in the downward direction is deteriorated by the chopping-down descending guide rib 195 (the chopping barrel is formed to have an inner space of a shape of a supersonic chimney and the chopping descending guide rib has a rectangular cross- The degree of inclination of the upper surface of the chopping-down descending guide rib with respect to the rotating shaft becomes larger, and the amount of the crushed food material moving upward in the upper surface of the chipping descent guide rib is increased by the working rotating body).

When the downward guidance function of the food material by the ribbed lowering guide ribs 195 is lowered, a secondary problem arises that the chipping efficiency is lowered.

Therefore, the object of the present invention is to provide a food material processing apparatus capable of improving the downward guidance function of food materials.

According to an aspect of the present invention, there is provided a driving device for a vehicle, comprising: a housing; a driving unit having a driving shaft installed to be exposed through an upper surface of the housing; a working rotating body coupled to the driving shaft; A plurality of juice frames arranged so as to be parallel to each other and a plurality of juice passage holes formed therein and having a juice screen coupled to the juice frame and a juice descending guide rib formed to protrude from the inner surface of the juice screen to be disposed along the length direction of the juice screen, Is disposed so as to surround the machining rotator in a state that a smaller diameter of the both ends of the juice net is directed toward the housing, and when the machining rotator rotates, it cooperates with the machining rotator, A juice passage provided so as to press the incoming food material, a solid material outlet and an juice outlet, A discharge port and a material inlet formed to discharge the juice and the solid generated when the juice container and the juice barrel squeeze the food material through the juice discharge port and the solids discharge port and to be supported by the housing, And a feeding portion which is provided so that the food material introduced through the feed passage enters the area between the feed passage and the feed passage and is supported by the feed passage, wherein the feed passage has a cross sectional area And a cross sectional area of the cross sectional area of the cross sectional area of the cross sectional area of the cross sectional area of the cross sectional area of the cross sectional area of the cross sectional area of the cross sectional area of the cross sectional area, The cross-sectional area increases Sectional outer surface section and an outer surface section of the cross-sectional reduced outer surface section so that a transfer operation is performed from the upper end of the rotary body section to the lower end of the rotary body section, A processing screw formed on the outer surface of the section; Wherein the ribs are formed in a trapezoidal cross-sectional shape in an area opposed to the cross-sectional increase outer surface section and are formed such that the height of the trapezoid gradually decreases toward the housing. Material processing apparatus.

Here, the food material which is not guided downward by the juice descending guide ribs while maintaining the function of the juice descending guide ribs for increasing the strength of the juice descending guide ribs and guiding the food material in the downward direction, The upper juice descending guide rib is formed such that the side where the machining rotator passes first among the two non-parallel trapezoidal sides is referred to as a line passing side and the other side is referred to as a rear passing side, And the rear passage is formed to have an obtuse angle with respect to the inner surface of the juice screen.

It is preferable that the upper and lower raising guide ribs are formed in a curved shape having a convex shape along the upper and lower direction so that the food material introduced through the inlet tube portion can easily enter the periphery of the processing rotary body.

[0011] According to another aspect of the present invention, there is provided a motorcycle comprising: a housing; a drive unit having a drive shaft installed to be exposed through an upper surface of the housing; a machining rotation body coupled to the drive shaft; A plurality of pipe-shaped side portions bent from the peripheral edge portion of the bottom surface portion and formed with a plurality of pouring solids discharge holes at the lower end thereof and having a pouring juice discharge hole connected to the pouring solids discharge hole in the upper region of the pouring solids discharge hole; A chimney barrel discharge portion formed in the chimney bar side portion so as to communicate with the chimney barrel discharging hole and a chopper lowering guide rib protruding from the inner surface of the chimney bar side portion so as to be disposed along the longitudinal direction of the chimney bar side portion And the bottom of the housing And the chopper barrel side surface portion surrounds the machining rotator and cooperates with the machining rotator when the machining rotator rotates to press the food material that enters between the machining rotator and the chafers, And the juice and the solid generated when the machining rotator and the chopper barrel squeeze the food material are respectively discharged through the chopper solids discharge hole and the chopper discharge hole and the chopper discharge pipe section is communicated with the juice discharge port And a food material inlet through which the food material is introduced is provided from the upper side to the area between the cigarette and the processing rotary body and is supported by the discharge cylinder A food material processing apparatus having a charging portion, Sectional surface area having a smallest cross-sectional starting point and a cross-sectional area decreasing during a period from the start point of the section to the end point of the section, and a cross-sectional area extending from the cross- A rotation body body portion having a section reducing outer surface section formed so as to prevent a portion where the cross-sectional area increases from reaching the section end point from the section start point; and a conveyance operation from the upper end of the rotation body body portion toward the lower end of the rotation body body portion And a processing screw formed on an outer surface of the cross-sectional increase outer surface section and the cross-sectional reduction outer surface section; Wherein the ramp-down guide ribs are formed in a trapezoidal cross-sectional shape in an area opposed to the cross-sectional increase outer surface section and are formed so that the height of the trapezoid decreases gradually toward the housing. Material processing apparatus.

Therefore, according to the present invention, the upper juice descending guide rib or the upper chopping descending guide rib is formed so as to have a trapezoidal cross-sectional shape in an area opposed to the outer surface section increase in cross section and gradually decreasing in the height of the trapezoid toward the housing. The downward guide rib or the downward guide rib can be formed so that the downward guide function of the food material can be improved when the juice passage chopper is formed to have an inner space of a shape of a supersonic lower end, Can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an exploded perspective view of a chopper according to an embodiment of the present invention,
FIG. 2 is an exploded perspective view of a processing rotary body, a discharge cylinder, a juice extractor, and an inlet section of a chopper for combined use according to an embodiment of the present invention;
FIG. 3 is a bottom view of a discharge cylinder according to an embodiment of the present invention; FIG.
Fig. 4 is a plan view showing a coupled state of a processed rotary body, a discharge cylinder, and a juice bottle according to an embodiment of the present invention;
5 is a sectional view taken along the line AA in Fig. 4,
6 is a perspective view of a juice bottle according to an embodiment of the present invention,
7 is a plan view of a juice bottle according to an embodiment of the present invention;
8 is a sectional view taken along the line AA in Fig. 7,
9 is a sectional view taken along line BB of Fig. 7,
10 is a partial cross-sectional view of the juice bottle according to the embodiment of the present invention;
Fig. 11 is an exploded perspective view of a machining rotator, a discharge cylinder, a chopper cylinder, and a charging section of a chopper combined with a chopper according to an embodiment of the present invention;
FIG. 12 is a sectional view showing a combined state of a machining rotary body, a discharge cylinder, and a chopper cylinder according to an embodiment of the present invention;
FIG. 13 is a perspective view of a multifunctional barrel according to an embodiment of the present invention;
Figs. 14 and 15 are views showing the bottom area of the multifunctional barrel according to the embodiment of the present invention, Fig.
FIGS. 16 and 17 are views showing a cap member according to an embodiment of the present invention;
FIG. 18 is a sectional view showing the installation state of the stopper member and the departure-avoiding bracket according to the embodiment of the present invention;
Fig. 19 is a plan view of a multi-cylinder according to an embodiment of the present invention; Fig.
20 is a sectional view taken along the line AA in Fig. 19,
Fig. 21 is a sectional view taken along line BB of Fig. 19,
FIG. 22 is a partial cross-sectional view of the multifunctional barrel according to the embodiment of the present invention; FIG.
23 is a perspective view of a machining rotary body according to an embodiment of the present invention;
Fig. 24 is a front view of the conventional chopper /
25 is a perspective view of a chopper container unit according to a conventional chopper /
Fig. 26 is a sectional view of the chopper container unit according to the conventional chopper /
Fig. 27 is a cross-sectional view showing an installation state of the chopper container unit according to the conventional chopper / juicer.

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

Fig. 1 is an exploded perspective view of a chopper according to an embodiment of the present invention. Fig. 2 is an exploded perspective view of a processing rotary body, a discharge cylinder, a juice extractor, FIG. 3 is a bottom view of a discharge cylinder according to an embodiment of the present invention, FIG. 4 is a plan view showing a coupled state of a processed rotary body, a discharge cylinder, and a juice bottle according to an embodiment of the present invention, Fig. 5 is a sectional view taken along the line AA in Fig. 4, Fig. 6 is a perspective view of the juice bottle according to the embodiment of the present invention, Fig. 7 is a plan view of the juice bottle according to the embodiment of the present invention, Fig. 10 is a partial cross-sectional view of the juice bottle according to the embodiment of the present invention, and Fig. 11 is a sectional view of the working rotator of the chopper for a chopper / Fig. 12 is an exploded perspective view of the discharge cylinder, the chopper cylinder, Fig. 13 is a perspective view of a multifunctional cylinder according to an embodiment of the present invention, and Figs. 14 and 15 are enlarged views of an embodiment of the present invention 16 and 17 are views showing a cap member according to an embodiment of the present invention, and Fig. 18 is a perspective view showing a cap member and an escape prevention bracket according to an embodiment of the present invention 20 is a sectional view taken along the line AA in Fig. 19, Fig. 21 is a sectional view taken along the line BB in Fig. 19, and Fig. 22 is a cross- FIG. 23 is a perspective view of a machining rotary body according to an embodiment of the present invention; FIG.

As shown in these drawings, the food material processing apparatus according to the embodiment of the present invention includes a housing 11, a drive unit 20 having a drive shaft 21 exposed to the outside of the housing 11, A cleaning rotary body 70 and a charging unit 80 which are installed in the discharge cylinder 40 so as to be rotatable with respect to the rotary cylinder 21, A stopper member 101 coupled to the bottom of the chopper cylinder 90 and a shelf 15 mounted to be supported by the housing 11 and a push lever 50 mounted to be supported by the support wall 12.

The housing 11 has a discharge tube seating surface 11a formed on the upper surface thereof and a supporting wall portion 12 formed on the peripheral surface of the discharge tube seating surface 11a.

A pair of lever operating grooves (12a) are formed on the outer surface of the support wall portion (12).

The driving unit 20 includes a sub shaft 22 and a motor (not shown) and a driving unit (not shown) for transmitting the rotational force of the motor to the driving shaft 21 and the sub shaft 22, And a cleaning rotary body driving gear 23 coupled to the auxiliary shaft 22. [ Here, the driving unit (not shown) uses a plurality of gear assemblies to drive the driving shaft 21 and the auxiliary shaft 22 so that the driving shaft 21 and the auxiliary shaft 22 rotate in opposite directions, Respectively.

The drive shaft 21 is installed to be exposed through the upper surface of the housing hill portion 11b and enter the discharge cylinder 40 through a discharge cylinder bottom surface portion 41 described later.

The auxiliary shaft 22 is installed to be exposed through the discharge tube receiving surface 11a.

The machining rotating body 30 includes a rotating shaft 31, a rotating body 32 coupled to the rotating shaft 31, machining screws 33 formed on the rotating body 32, And a solids conveying screw 35 for the solids.

The rotating body 32 has a section increasing outer surface section 32a and a section reducing outer surface section 32b formed from the section increasing outer surface section 32a.

The section increase outer surface section 32a is formed such that the section having the smallest cross-sectional area does not appear while the section starting point has the smallest cross-sectional area and reaches the section end point from the section start point.

The section reduction outer surface section 32b is formed so that the section end point has the smallest cross sectional area and the portion where the cross section increases is not displayed while the section end point reaches the section end point.

The rotary body 32 has a shaft support groove (not shown) formed at the lower end thereof.

Each solids conveyance screw 35 is formed on the outer surface of the reduced-section outer surface section 32b.

The working rotator 30 having such a configuration is coupled to the drive shaft 21 through the rotator body 32 in the discharge cylinder 40 and rotates through the rotator shaft 31, (82a).

The discharge cylinder 40 has a discharge cylinder bottom face portion 41 and a discharge cylinder side face portion 42 bent from the discharge cylinder bottom face portion 41 so as to be concave in cooperation with the discharge cylinder bottom face portion 41 have.

A discharge cylinder hill portion 41d is formed in the central region of the discharge cylinder bottom surface portion 41 and a rotary shaft passage hole 41e is formed in the discharge cylinder hill portion 41d.

In the discharge cylinder bottom surface portion 41, auxiliary shaft connecting holes 41c, juice guide grooves 41j, solids guide grooves 41i, seating grooves 41f and alignment grooves 41h are formed.

 The solids guide groove 41i is formed to penetrate along the thickness direction of the discharge cylinder bottom surface portion 41 and to communicate with the solids discharge port 42b.

The seating groove 41f is formed to have a plurality of straight seating sections 41g. Here, the straight seating section 41g is formed so as to correspond to the lower frame straight line section 62d and the smaller-diameter floor straight section 91d described later.

The alignment grooves 41h are formed at two places.

The discharge cylinder side surface portion 42 is formed with a juice discharge port 42a and a solid discharge port 42b at the lower end thereof and a charging portion fixing claw 42c at the upper end thereof.

The juice outlet 42a is formed to be connected to the juice guide groove 41j.

The solids discharge port 42b is formed to be connected to the solids guide groove 41i.

A pressure regulating member 103 for regulating the discharge pressure of the solids is fixed to the fixing protrusion 41k formed on the bottom surface of the discharge cylinder bottom surface portion 41 in the solids discharge port 42b.

In the discharge cylinder 40 having such a configuration, the housing hill portion 11b is inserted into the discharge cylinder hill portion 41d, the rotary shaft 31 passes through the rotary shaft passage hole 41e, 41 are mounted on the discharge tube receiving surface 11a.

The discharge cylinder 40 is installed so that the rotating body 32 is supported on the upper surface of the discharge cylinder bottom surface portion 41. Accordingly, juice and solid matter generated when the processed rotator 30 and the juice container 60 press the food material can be discharged through the juice discharge port 42a and the solids discharge port 42b, respectively.

The juice extractor 60 includes a juice extractor 61 in which a plurality of juice passage holes 61a are formed, a juice extractor frame 62 coupled to the juice extractor 61, Descending guide ribs 65 protruded from the inner surface of the juice protector 61 so as to be disposed on the inner surface of the juice frame 62 and a juice bottle alignment protrusion 63 coupled to the bottom surface of the juice frame 62.

The juice protector 61 is formed so that the cross-section gradually decreases along the longitudinal direction.

The juice frame 62 is constituted by an upper frame 62a, an intermediate frame 62b and a lower frame 62c formed in a ring shape, respectively.

The upper frame 62a is larger in diameter than the intermediate frame 62b and the intermediate frame 62b is larger in diameter than the lower frame 62c.

The lower frame 62c is formed to have a plurality of lower frame rectilinear sections 62d on its outer surface and is coupled to the lower end of the juice extractor 61. [

The lower end frame 62c has a guide groove locking projection 62h formed on the bottom surface thereof.

Further, the lower frame 62c has a solid passage hole 62i formed to penetrate therethrough along the thickness direction.

The juice descending guide rib 65 is constituted by the upper juice descending guide rib 65a.

The upper juice descending guide ribs 65a are formed in a trapezoidal cross-sectional shape in an area opposed to the section increasing outer surface section 32a, and are formed such that the height of the trapezoid decreases gradually toward the housing 11. [

The upper drop descending guide ribs 65a are formed so that when one side of the two trapezoidal parallel non-parallel sides passing through the processing rotary body 30 is referred to as a line passing side A and the other side is referred to as a rear passing side B, The passage side A is formed to be 85 degrees to 90 degrees with respect to the inner surface of the juice protector 61 and the rear side B is formed to be an obtuse inclined surface with respect to the inner surface of the juice protector 61.

If the angle of the line passing side A with respect to the inner surface of the juice protector 61 is less than 85 degrees, the function of the upper juice descending guide rib 65a for guiding the food material in the downward direction is lowered, The food material which is not guided downward is prevented from moving along the rotating direction of the processing rotary body 30.

The upper dropping guide rib 65a is formed in a curved shape (see "R" in Fig. 8) whose upper end is convex along the vertical direction. In this specification, the vertical direction means a direction connecting the charging unit 80 and the housing 11.

Two juice container alignment protrusions 63 are formed on the bottom surface of the lower frame 62c.

The juice extractor 60 having such a configuration is configured such that the juice extractor 61 surrounds the processing rotary body 30, the lower frame 62c is seated in the seating groove 41f, Is inserted into the groove 41i so that the solenoid passage hole 62i communicates with the solids guide groove 41i and the guide groove locking hole portion 62h is inserted into the solids guide groove 41i. If the juice bottle 60 is provided by aligning the juice bottle alignment protrusions 63 with the alignment grooves 41i, the installation work is facilitated.

The juice bin 60 installed in this manner can cooperate with the machining rotator 30 to press the food material entering the machining rotator 30 when the machining rotator 30 rotates.

The chopper barrel 90 has a chopper barrel bottom surface portion 91, a chopper barrel side surface portion 92 formed by bending from the peripheral edge portion of the chopper barrel bottom surface portion 91 and a chopper barrel discharge pipe portion 93 Down guide ribs 94 formed on the inner surface of the chopper barrel side portion 92 and a chopper barrel alignment protrusion 95 formed on the bottom surface of the chopper barrel bottom portion 91. [

The condenser bottom portion 91 is formed on the outer surface of the condenser bottom portion 91 so as to have the same shape as the lower end frame rectilinear section 62d and has a longitudinal center line 91d.

The lower end of the chopper cylinder bottom surface portion 91 is formed with a member seating projection 91c and a member seating hill portion 91b in the shape of a letter C.

The chopping barrel side surface portion 92 is provided with a chopping solids discharge hole 92a at the lower end thereof and a chopping juice discharge hole 92d is formed in the upper region of the chopping solids discharge hole 92a so as to be connected to the chopping solids discharge hole 92a Respectively.

The chopper drain pipe portion 93 is formed to communicate with the chopper solids discharge hole 92a and the chopping juice discharge hole 92d.

The chopping-down guide rib 94 has an upper chopper lowering guide rib 94a and a lower chopper lowering guide rib 94b extending from the lower end of the upper chopper lowering guide rib 94a.

The upper chopper lowering guide rib 94a is formed in a trapezoidal cross-sectional shape in an area opposed to the cross section increasing outer surface section 32a and is formed so that the height of the trapezoid decreases gradually toward the housing 11. [

The upper chipping lowering guide rib 94a is formed in such a manner that when one side of the two trapezoidal parallel non-parallel sides passing through the processing rotary body 30 is referred to as a line passing side A and the other side is referred to as a rear passing side B, The passage side A is formed at 85 degrees to 90 degrees with respect to the inner surface of the chambers 92 and the rear passage B is formed to be an obtuse angle with respect to the inner surface of the side wall 92 of the chambers.

Here, when the angle of the line passing side A with respect to the inner surface of the chopping barrel side portion 92 is less than 85 degrees, the function of the upper chopping downward descending guide rib 94a for guiding the food material in the downward direction is lowered, The food material that is not guided downward is disturbed from moving along the rotating direction of the processing rotary body 30.

Further, the upper polygon lowering guide rib 94a is formed in a curved shape (see "R" in Fig. 20) whose upper end is convex along the vertical direction. In this specification, the vertical direction means a direction connecting the charging unit 80 and the housing 11.

The lower chipping lowering guide rib 94b is formed in a rectangular cross-sectional shape having a constant section size in a region opposed to the section reducing outer surface section 32b.

Two cage sorting aligning projections 95 are formed.

The chopper cylinder 90 having such a configuration is configured such that the chopper cylinder side surface portion 92 surrounds the working rotary body 30 and the chopper cylinder bottom surface portion 91 is seated in the seating groove 41f, And is held by the bottom surface portion 41 of the discharge cylinder through the chamfered bottom surface portion 91 and the chopper cylinder vent pipe portion 93 is installed so as to communicate with the juice outlet port 42a.

The chopper cylinder 90 is installed so that the rotary shaft 31 passes through the rotary shaft passing hole 91a.

The multifunctional barrel 90 installed in this manner can press the food material that enters the processing rotary body 30 in cooperation with the processing rotary body 30 when the processing rotary body 30 rotates.

The stopper member 101 is formed with a pore 101b at the center thereof and a pore 101a of a C shape is formed in the peripheral region of the pore 101b.

The stopper member 101 having such a constitution is made of an elastic material such as silicone rubber and is coupled to the member seat hill portion 91b and the member seat projection 91c through the stone pores 101b and the hill hole 101a.

The stopper member 101 has a shape that can be brought into close contact with the circumferential edge of the solids guide groove 41i when the clamper 90 is installed to be supported by the discharge cylinder bottom surface portion 41 through the cage bottom surface portion 91 .

The nipple passing through the solids guide groove 41i can be prevented from being pressed by the stopper member 101 coupled to the member seating hill 91b and the member seating protrusion 91c in the state where the chopper cylinder 90 is installed inside the discharge cylinder 40 .

The cleaning rotary body 70 includes a circular support ring 71, a vertical frame 72 standing upright on the support ring 71, a horizontal frame 73 in the form of a ring coupled to the vertical frame 72, A cleaning brush 74 fixed to the frame 72 and a cleaning rotary gear 75 formed on the bottom surface of the supporting ring 71. [

The cleaning rotation full gear 75 is formed so as to engage with the cleaning rotation body driving gear 23.

The cleaning rotary drive gear 23 is installed on the discharge cylinder bottom surface portion 41 so as to rotate together with the auxiliary shaft 22 through the auxiliary shaft connection hole 41c.

The cleaning rotary body 70 having such a configuration is installed such that the cleaning rotary gear 75 is engaged with the cleaning rotary drive gear 23 and the cleaning brush 74 is contacted with the juice extractor 61.

The charging section 80 has a charging tube section 81, a cover plate section 82 coupled to the lower end of the charging tube section 81 and a guide plate section 83 coupled to the upper end of the charging tube section 81 .

The upper end of the inlet pipe portion 81 becomes the material inlet 81a.

The cover plate portion 82 has a rotor support groove 82a formed on the bottom surface thereof.

The input unit 80 having such a configuration is configured such that a fixed rib (not shown) formed on the bottom surface of the cover plate portion 82 engages with the input unit fixing jaw 42c formed in the discharge tube side portion 42 40).

The opening portion of the discharge cylinder side surface portion 42 is closed by the cover plate portion 82 in the state where the charging portion 80 is coupled to the discharge cylinder 40 and the material injected through the injection tube portion 81 flows into the juice bottle 60 ) And the machining rotary body 30 or between the machining rotary body 90 and the machining rotary body 30.

The pressure lever 50 includes an elevating rail portion 51, a pressing arm 52 bent from the elevating rail portion 51, and a support arm portion 52 for pulling the elevating rail portion 51 toward the housing 11 And a tension spring (not shown)

The pressing lever 50 having such a configuration is installed so that the elevating rail portion 51 enters the lever operating groove 12a.

Accordingly, when the pressure lever 50 is pulled upward, the pressure lever 50 is raised to the separation position (a position where the pressure arm is separated from the cover plate portion so as to separate the charging portion from the discharge cylinder) and the pressure lever 50 The pressing lever 50 is lowered to the pressing position (the position at which the pressing arm presses the cover plate portion downward) by the elastic force accumulated in the tension spring (not shown).

A method of using a food material processing apparatus according to an embodiment of the present invention having such a configuration will now be described.

Hereinafter, the method of using the juice-shaped food to be processed will be described.

First, the juice container 60, the processing rotary body 30, and the charging unit 80 are sequentially installed.

Next, when the on-off switch (not shown) is turned on to supply power to the driving unit 20, the driving shaft 21 rotates.

When the drive shaft 21 rotates, the machining rotation body 30 rotates.

Next, a food material (vegetables, etc.) is injected through the feeding tube portion 81.

The introduced food material is squeezed by the processing rotary body 30 and the juice bottle 60, thereby producing juice and solids.

The food material is guided in the downward direction, that is, toward the housing 11, by the upper juice descending guide rib 65a during the pressing operation of the processing rotary body 30 and the juice bottle 60. [

The resulting juice and solids are separated by a juice bottle (60).

The separated juice drops through the juice guide grooves 41j and the juice guide holes 42a into a cup (not shown) provided on the cup-receiving plate 13, and the separated juice drops through the solids guide groove 41i and the solids discharge port (42b).

On the other hand, when the cleaning rotary body 70 is rotated in the direction opposite to the processing rotary body 30, the solid material caught in the juice passage hole 61a is removed by the cleaning brush 74.

Hereinafter, a description will be given of a method of using the food to be processed in the form of chopped food.

First, the charging unit 80, the processing rotary body 30, and the cleaning rotary body 70 are sequentially separated.

Next, the chopper cylinder 90, the processing rotary body 30, and the charging unit 80 are sequentially installed. Here, the mounting of the processing rotary body 30 is performed such that the machining rotary body 30 is coupled to the drive shaft 21 through the rotary shaft passing hole 91a.

Next, when the on-off switch (not shown) is turned on to supply power to the driving unit 20, the driving shaft 21 rotates.

When the drive shaft 21 rotates, the machining rotation body 30 rotates.

Next, a food material (such as garlic) is injected through the feeding tube portion 81.

The introduced food material is squeezed by the processing rotary body 30 and the chopper cylinder 90, thereby producing juice and solids.

The food material is guided in the downward direction, that is, toward the housing 11, by the chopping-down descending guide ribs 94 during the pressing operation of the processing rotary body 30 and the chopper cylinder 90. [

The resulting solid material passes through the agglomerated solid matter discharging hole 92a and drops into a receiving cup (not shown) provided on the cup receiving plate 13 through the agitator discharging pipe portion 93 and the juice guide hole 42a Some of the solids can be discharged to the outside through the chimney drain pipe portion through the chimney drainage hole).

The generated juice passes through the chopping juice discharge hole 92d and drops into a cup (not shown) provided on the cup chopping plate 13 through the chopper tube discharge pipe portion 93 and the juice guide hole 42a A portion of the juice may be discharged to the outside through the agitator discharge pipe portion through the agitator discharge hole).

As described above, according to the embodiment of the present invention, the trapezoidal cross-sectional shape is formed in the area opposed to the cross-sectional increase outer surface section 32a, and the height of the trapezoid is gradually decreased toward the housing 11, By constituting the juice descending guide rib 65 or the chipping descending guide rib 94 so as to include the guide ribs 65a or the upper chipping guide descending ribs 94a, (The upper surface of the upper drop descending guide rib or the upper sloping down guide rib is inclined with respect to the upper surface of the upper rotation shaft) So that the amount of the crushed food material moving upward in the upper surface of the upper juice descending guide rib or the upper surface of the upper chipping guide rib is reduced).

The processing efficiency (juicing efficiency and chipping efficiency) can be improved if the downward guidance function of the food material by the juice descending guide ribs 65 or the chipping and descending guide ribs 94 is improved.

Of the trapezoidal side wall portion (92) of the line passing passage mutually intersects with the inner surface of the side wall portion (92) Down guiding ribs 65 or the ramp-down guiding ribs 94 to increase the strength of the juice-down guiding ribs 65 or the cooking-down guiding ribs 94 for guiding the food material in the downward direction, The food material which is not guided downward by the juice descending guide rib 65 or the chipping and descending guide ribs 94 while maintaining the function of the rotary shaft 65 or the chipping and descending guide ribs 94 is rotated So that it can be easily moved along the direction.

The upper dropping guide ribs 65a and the upper dropping down guide ribs 94a are curved along the vertical direction so that the food material to be introduced through the dropping tube portion 81 is supplied to the processing rotary body 30, So that it can be easily entered into the vicinity.

11, 111: housing 12: support wall portion
20, 120: driving part 21, 121:
30, 130: machining rotor 31: rotating shaft
32: rotating body 33: machining screw
40: discharge cylinder 41 discharge cylinder bottom surface
42: discharge cylinder side part 50: pressure lever
60: Juice bottle 61:
62: a juice frame 65: a juice descending guide rib
70: cleaning sweep whole
80, 180: input section 81, 181: input tube section
82, 182: cover plate portion 83: guide plate portion
90: Chipper 91: Chipper bottom
92: chopper cylinder side part 93: chopper cylinder exhaust pipe part
94: chopping descent guide rib 95: chopper sorting projection
140: Juice container part 141:
142: Solids discharge pipe section 143: Juice discharge pipe section
190: chopper container portion 191: chopper barrel portion
192: support skirt portion 193: chopper drain pipe portion

Claims (6)

A drive unit having a housing and a drive shaft installed to be exposed through an upper surface of the housing; a machining rotator coupled to the drive shaft; and a plurality of juice frames arranged in a ring shape having different diameters, And a juice descending guide rib formed on the inner surface of the juice screen so as to be disposed along the length direction of the juice screen, wherein a diameter of both ends of the juice screen And a smaller one of the small diameter side portions is arranged to surround the machining rotation body in a state of being oriented toward the housing and is provided to press the food material entering into the space between the machining rotation body and the work piece cooperating with the machining rotation body when the machining rotation body rotates A juice passage, a solids discharge port and a juice discharge port are formed, A food material inlet through which a juice and a solids generated when the material is squeezed are discharged through the juice outlet and the solids outlet port and installed to be supported by the housing, And a feeding portion which is provided so as to enter the region between the rotatable processed rotors and to be supported by the juice bottle,
Wherein the machining rotation body has a sectional area having a smallest sectional starting point and is formed so as to extend from a sectional increased outer surface section so that a portion having a reduced sectional area does not appear while the sectional starting point reaches the sectional end point, And a lower end portion of the body portion of the rotary body from the upper end of the body portion of the rotary body so as to prevent a portion having an increased cross-sectional area from appearing during a period from the start point of the section to the end point of the section, And a processing screw formed on an outer surface of the cross-sectional increase outer surface section and the cross-sectional reduction outer surface section so that the transfer operation is performed toward the cross-sectional increase outer surface section;
Wherein the ribs are formed in a trapezoidal cross-sectional shape in an area opposed to the cross-sectional increase outer surface section and are formed such that the height of the trapezoid gradually decreases toward the housing. Material processing apparatus. The method according to claim 1,
Wherein the upper juice descending guide rib has a line passing-through side and a remaining side passing-through side of the trapezoidal two non-parallel sides, 85 degrees to 90 degrees, and the post passage side is formed so as to form an obtuse inclined surface with respect to the inner surface of the juice. 3. The method according to claim 1 or 2,
And wherein the upper juice descending guide rib is formed in a curved surface shape whose upper end is convex along the vertical direction. A drive shaft having a drive shaft installed to be exposed through an upper surface of the housing; a machining rotator coupled to the drive shaft; a plurality of chambers formed in the center of the chambers, Shaped solid side discharge port formed at the lower end of the chopped solid discharge port and formed with a chop discharge port to be connected to the chopped solid discharge port in the upper area of the chopped solid discharge port, And a chipping tank discharge pipe portion formed on the chaff tank side surface portion so as to communicate with the chipping juice discharge hole and a chipping and descending guide rib protruding from the inner surface of the chaff tank side portion to be disposed along the longitudinal direction of the chipping tank side surface portion, And a support member A chopper passage and a juice discharge port are formed to cooperate with the processing rotary body so as to press the food material entering into the space between the rotary body and the processing rotary body when the rotary body rotates around the rotary body The juice and the solids generated when the processed rotary body and the chopper cylinder press the food material are respectively discharged through the chopper solids discharge hole and the chop juice discharge hole and the chopper drain pipe is connected to the housing A food material having an inlet for feeding the food material through the material inlet and an inlet for feeding the food material from the upper side into the area between the upper and lower chambers and supported by the discharge cylinder, In the material processing apparatus,
Wherein the machining rotation body has a sectional area having a smallest sectional starting point and is formed so as to extend from a sectional increased outer surface section so that a portion having a reduced sectional area does not appear while the sectional starting point reaches the sectional end point, And a lower end portion of the body portion of the rotary body from the upper end of the body portion of the rotary body so as to prevent a portion having an increased cross-sectional area from appearing during a period from the start point of the section to the end point of the section, And a processing screw formed on an outer surface of the cross-sectional increase outer surface section and the cross-sectional reduction outer surface section so that the transfer operation is performed toward the cross-sectional increase outer surface section;
Wherein the ramp-down guide ribs are formed in a trapezoidal cross-sectional shape in an area opposed to the cross-sectional increase outer surface section and are formed so that the height of the trapezoid decreases gradually toward the housing. Material processing apparatus. 5. The method of claim 4,
Wherein the upper end of the upper chopper lowering guide rib is formed of a pair of trapezoidal descending guide ribs, And the rear passage is formed to be inclined at an obtuse angle with respect to the inner surface of the side wall of the condenser barrel. The method according to claim 4 or 5,
Wherein the upper chopping down guide rib is formed in a curved surface shape whose upper end is convex along the vertical direction.

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