KR102445076B1 - Crushing device for extraction raw materials - Google Patents

Abstract

A lower fine grinding ring 24 that is configured to be rotatable about its central axis, grinds the supplied coffee beans while rotating, and sends out coffee powder, which is ground coffee beans, in the radial direction of the central axis, and the lower fine A passage wall ring 25 and a delivery passage 27, disposed so as to surround the entire outer peripheral surface while opposing the outer peripheral surface of the grinding ring 24, and defining a delivery passage 27 through which coffee powder is delivered between the outer peripheral surface and the outer peripheral surface It has a movable wing part 231, collects coffee powder by moving the wing part 231 in the dispensing passage 27, and discharges the coffee powder from the discharge port 251 formed in the passage wall ring 25. , the raw material discharging plate 23 is provided, and the passage wall ring 25 is made of a material that tends to be electrically charged with coffee beans due to the heat of charging.

Description

Crushing device for extraction raw materials

The present invention relates to a grinding device for extraction raw materials, and more particularly, to a grinding device for grinding extraction raw materials such as coffee beans used for extracting beverages, such as coffee, applied, for example, to a cup-type vending machine or beverage dispenser. it's about

Conventionally, for example, the coffee mill proposed in Patent Document 1 is known as a grinding device for extracting raw materials such as coffee beans. This coffee mill is provided with a rotary blade, a fixed blade, a screw, and a rotary blade.

The rotary blade is provided on the tip side of the drive shaft directly connected to the horizontally extending rotary shaft of the motor serving as the drive source. The fixed blade is a ring-shaped thing disposed to face the rotary blade in a state where the driving shaft passes through it. The screw is installed on the outer peripheral surface of the drive shaft, and is for feeding coffee beans between the rotary blade and the fixed blade. The rotary blade is provided on the outer peripheral side of the rotary blade so as to rotate integrally with the rotary blade.

In addition, the coffee mill is provided with a casing constituting the outer shell, and between a predetermined inner wall surface of the casing and the outer peripheral surfaces of the rotary blade and the fixed blade, coffee beans ground by these blades (hereinafter also referred to as coffee powder) ) is sent out and the sending passage through which the rotary blade moves around is partitioned. In addition, an inlet through which coffee beans are fed from above is formed in the casing on the upper side of the screw, and a discharge passage through which coffee powder is discharged downward is formed on the lower side of the dispensing passage.

In such a coffee mill, a motor is driven, and when coffee beans are fed from the inlet before and after this, the coffee beans are fed between the rotating blade and the fixed blade by a rotating screw, and ground between the two blades to form coffee powder. . The coffee powder is sent to the delivery passage by the centrifugal force of the rotary blade, is scraped by the rotary blades moving around the delivery passage, and is discharged downward through the discharge passage.

Patent Document 1: Japanese Patent Laid-Open No. 7-124062

However, in the coffee mill described above, when coffee beans are pulverized by the rotary blade and the fixed blade, and the coffee powder sent to the delivery passage is scraped by the rotary blade, the coffee powder is charged by static electricity. that is known

As a result, coffee powder adheres to the inside of the coffee mill and tends to remain, and the amount of coffee powder to be produced decreases with respect to the amount of coffee beans to be introduced, leading to a decrease in the supply precision of coffee powder.

In view of the above situation, an object of the present invention is to provide a pulverizing apparatus for extracting raw materials capable of reducing the amount of powder raw materials adhering to and remaining inside the apparatus and allowing the powder raw materials to be discharged satisfactorily.

In order to achieve the above object, the grinding device for extracting raw materials according to the present invention is configured to be rotatable about its central axis, and pulverizes while rotating the supplied extracting raw material, and the pulverized raw material for extracting powder A rotary crushing unit for sending out in the radial direction of the central axis, and disposed to surround the entire outer circumferential surface while facing the outer circumferential surface of the rotary crushing unit, a passage dividing a feeding passage through which the powder raw material is sent between the outer circumferential surface A raw material having a wall portion and a movable part movable in the delivery passage, collecting the powdered raw material sent to the delivery passage when the movable part moves in the delivery passage, and discharging the powdered raw material from a discharge port formed in the passage wall portion A pulverizing apparatus for extracting raw materials having a discharge part, wherein the passage wall part is made of a material having a tendency to be close to electrification with the extracting raw material in terms of electrification heat.

In addition, the present invention is characterized in that in the above extraction raw material pulverizing apparatus, the passage wall portion is made of aluminum or polypropylene.

Further, in the present invention, in the pulverizing apparatus of the raw material for extraction, while the discharge port is substantially blocked in a normal state, when the powder material is discharged by the raw material discharge unit, it is elastically deformed by being pressed by the powder material, and the It is characterized in that it is provided with a resistance piece part which opens the discharge port.

In addition, the present invention is characterized in that, in the pulverizing apparatus of the raw material for extraction, a guide member for guiding the powder raw material discharged from the discharge port downward is provided, and the resistance piece is detachably installed on the guide member. .

In addition, the pulverization apparatus of the extraction raw material according to the present invention is configured to be rotatable about its central axis, and pulverizes the supplied extraction raw material while rotating, and the powder raw material, which is the pulverized extraction raw material, is rotated in the radial direction of the central axis. a rotary pulverizing unit for sending to the Extraction having a raw material discharging unit having a movable part movable in the passage, collecting the powdered raw material sent to the dispensing passage when the movable unit moves in the dispensing passage, and discharging the powdered raw material from the discharge port formed in the passage wall portion A raw material pulverizing device comprising a water supply means for supplying a small amount of water to the rotary pulverizing unit.

The present invention is also characterized in that in the pulverizing apparatus of the raw material for extraction, the water supply means supplies the water before pulverization of the raw material for extraction.

According to the present invention, since the passage wall portion is made of a material that tends to be electrically charged with the extraction material in terms of heat of charge, even if the powder raw material passing through the delivery passage comes into contact with the passage wall portion, charge transfer occurs between the two. It becomes difficult, and generation|occurrence|production of static electricity can be reduced. Thereby, it reduces that a powder raw material adheres and remains inside an apparatus, and the effect that a powder raw material can be discharged|emitted favorably is exhibited.

Further, according to the present invention, since the water supply means supplies a small amount of water to the rotary pulverizer, it is possible to reduce the generation of static electricity due to moisture when the powder raw material is produced. Thereby, it reduces that a powder raw material adheres and remains inside an apparatus, and the effect that a powder raw material can be discharged|emitted favorably is exhibited.

1 is a perspective view showing an apparatus for pulverizing an extraction raw material according to an embodiment of the present invention;
2 is a side view showing an apparatus for pulverizing an extraction raw material according to an embodiment of the present invention.
3 is a plan view showing an apparatus for pulverizing an extraction raw material according to an embodiment of the present invention.
4 is a longitudinal cross-sectional view showing an apparatus for pulverizing an extraction raw material according to an embodiment of the present invention.
5 is a perspective view showing the main part of the mill body shown in FIGS. 1 to 4 .
6 is a perspective view illustrating the floating seal shown in FIG. 5 .
7 is an exploded perspective view illustrating the floating mill shown in FIG. 5 .
FIG. 8 is a perspective view illustrating the rotary mill shown in FIG. 5 .
FIG. 9 is a perspective view illustrating the rotary mill shown in FIG. 5 .
10 is an exploded perspective view illustrating the rotary mill shown in FIG. 5 .
Fig. 11 is a perspective view showing the passage wall ring and the guide member shown in Figs.
12 is a cross-sectional view showing a resistance piece provided on a guide member.
13 is a perspective view showing a modified example of the pulverizing apparatus for extraction raw materials according to the embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the apparatus for crushing the raw material for extraction according to the present invention will be described in detail.

1 to 4 are each showing an apparatus for crushing extraction raw materials according to an embodiment of the present invention, and FIG. 1 is a perspective view, FIG. 2 is a side view, FIG. 3 is a plan view, and FIG. 4 is a longitudinal sectional view. The grinding device for an extraction raw material exemplified here is, for example, a coffee mill that is applied to, for example, a cup-type vending machine, a beverage dispenser, and the like to grind coffee beans serving as an extraction raw material. Hereinafter, the grinding device will be described as a coffee mill.

The coffee mill 1 grinds coffee beans supplied from a raw material canister not specified in the drawing to generate coffee powder as a powder raw material, and supplies the coffee powder to an extraction container not specified in the drawing, case 1a to provide

The case 1a constitutes the outer shell of the coffee mill 1, and is formed by assembling a plurality of parts to each other. In this case 1a, a mill body 2 is disposed.

The mill body 2 is disposed in the case 1a with the upper half projecting upward of the case 1a. A motor 3 for driving the mill body 2 is disposed at the rear of the mill body 2 , and is discharged from the mill body 2 in front of the mill body 2 . A powder raw material supply unit 4 for supplying the coffee powder to be to the extraction container is disposed. Such a mill body 2 is configured, as also shown in FIG. 5 , comprising a floating mill 10 that becomes immovable during operation and a rotary mill 20 that rotates during operation.

6 is a perspective view showing the floating mill 10 shown in FIG. 5 , and FIG. 7 is an exploded perspective view showing the floating mill 10 shown in FIG. 5 . As also shown in these FIGS. 6 and 7 , the floating mill unit 10 includes a hopper 11 , a coarse crush ring 12 , and an upper fine crush ring 13 .

The hopper 11 is formed in a cylindrical shape extending in the vertical direction, and receives coffee beans input from above. This hopper 11 contains, for example, a molded article of resin such as plastic, and on its outer peripheral surface, a gear portion 111 is provided at a position slightly higher than the center in the vertical direction. In addition, a male screw part 112 is formed in the lower half of the outer peripheral surface of the hopper 11, and the hopper 11 is attached to the case 1a in a state in which the male screw part 112 is twisted. Accordingly, as shown in Figs. 1 to 4, by properly turning the particle size adjustment screw 5 having the worm gear 5a engaged with the gear unit 111, the floating mill unit 10 is attached to the case 1a. It moves so as to rotate with respect to each other and ascends and descends, so that the gap between the upper fine grinding ring 13 of the floating mill 10 and the lower fine grinding ring 24 which will be described later constituting the rotary mill 20 is adjusted. Thereby, the particle size of the coffee beans ground by the upper fine grinding ring 13 and the lower fine grinding ring 24 can be adjusted.

The coarse grinding ring 12 is screwed to the inner lower part of the hopper 11, and is for grinding coffee beans in a relatively coarse state (hereinafter also referred to as coarse grinding). The coarsely pulverized ring 12 is made of, for example, a predetermined metal such as aluminum or an alloy thereof, and is formed in a cylindrical shape with a relatively thick peripheral wall.

At the bottom of this coarse crushing ring 12, a crushing convex portion 121 extending over the entire circumferential direction and protruding inward is formed. The grinding convex portion 121 is for coarsely grinding coffee beans in cooperation with a raw material feeder 21 to be described later constituting the rotary mill 20, and between the raw material feeder 21, the grain size of coffee beans It is configured to protrude with a smaller predetermined interval.

Further, the grinding convex portion 121 has a predetermined thickness, is formed so that its upper surface is along a plane orthogonal to the raw material feeder 21 , and is continuous to the upper surface and has a distal end surface opposite to the raw material feeder 21 . (122) forms a corner portion forming a right angle with the upper surface. Moreover, in the grinding|pulverization convex part 121, the some concave part 123 formed in the concave shape is formed along the circumferential direction. Each concave portion 123 is formed so as to be open between the upper surface and the tip surface 122 of the grinding convex portion 121 .

A plurality of concave portions 124 are formed on the inner surface of the coarse crushing ring 12 above the crushing convex portion 121 along the circumferential direction. Each concave portion 124 is formed so as to be open from the upper surface to the inner surface of the coarse crushing ring 12, and the inner surface is formed to approximately follow the radial direction of the coarsely crushing ring 12, a triangular-shaped triangular surface ( 124a) and an arcuate face 124b that is continuous to the triangular face 124a and is formed so as to extend in an arc shape.

The upper fine grinding ring 13 is screwed to the lower surface of the coarse grinding ring 12, and cooperates with the lower fine grinding ring 24 to grind the coarsely ground coffee beans into a finer state (hereinafter, fine grinding). also called) for The upper fine grinding ring 13 is made of, for example, a predetermined metal such as stainless steel, has an inner diameter slightly larger than the inner diameter of the grinding convex portion 121 of the coarse grinding ring 12, It has an outer diameter that is slightly larger than the outer diameter.

In addition, the upper fine grinding ring 13 is formed so that the thickness gradually increases from the inside to the outside, and on the grinding surface 13a of the inclined lower surface, each extending in the radial direction and arranged along the circumferential direction, of the blade 131 is formed.

8 and 9 are perspective views each showing the rotary mill 20 shown in FIG. 5 , and FIG. 10 is an exploded perspective view showing the rotary mill 20 shown in FIG. 5 . 8 to 10, the rotary mill 20 includes a raw material feeder 21, a mill gear 22, a raw material discharging plate (raw material discharging unit) 23, and a lower fine grinding ring. A (rotary crushing unit) 24 , a passage wall ring (passage wall portion) 25 , and a guide member 26 are provided and configured.

The raw material feeder 21 is extended in the vertical direction, and is for sending the coffee beans injected|thrown-in to the hopper 11 downward. This raw material feeder 21 contains, for example, a predetermined metal such as aluminum or an alloy thereof, and has a rotating portion 211 and a spiral convex portion 212 .

The rotating part 211 is formed in a cylindrical shape extending a predetermined length in the vertical direction. The spiral convex portion 212 protrudes a predetermined length from the outer circumferential surface of the rotating unit 211 and extends spirally from the upper end to the lower end of the rotating unit 211 so as to circumferentially in the clockwise direction.

In such a raw material feeder 21, a rotating shaft 213 extending in the vertical direction is inserted into the rotating part 211 from below, and a nut (not shown) at the upper end is screwed to the rotating shaft 213 protruding upward from the upper end thereof. By being fastened, it is fixed to the rotating shaft 213 . On the other hand, the rotating shaft 213 is rotatably supported by the bearing 214 fixed to the inside of the case 1a in the position slightly lower than the lower end and the center in the up-down direction.

The mill gear 22 is fixed to the lower part of the rotating shaft 213 of the raw material feeder 21 . The mill gear 22 is constituted by a helical gear having a relatively large diameter, and is fixed between the upper and lower bearings 214 of the rotary shaft 213 as shown in FIG. 4 . Further, the mill gear 22 meshes with an intermediate gear 3b which meshes with a drive gear 3a fixed to the output shaft of the motor 3 .

The raw material discharging plate 23 is fixed above the mill gear 22, and collects and discharges coffee powder that is sent to a dispensing passage 27 to be described later when coffee beans are ground. This raw material discharging plate 23 is formed in a disk shape having a diameter one size larger than the outer diameter of the lower fine grinding ring 24, and on the outer periphery thereof, is arranged at an angle equal to each other along the circumferential direction with respect to the center, and upwards A plurality of wing portions (moving portions) 231 that protrude are provided.

The lower fine grinding ring 24 is screwed onto the raw material discharge plate 23 and cooperates with the upper fine grinding ring 13 to finely grind coarsely ground coffee beans. The lower fine grinding ring 24 is made of, for example, a predetermined metal such as stainless steel, and is formed vertically symmetrically with the upper fine grinding ring 13 . In addition, the lower fine grinding ring 24 is formed so as to gradually increase in thickness from the inside to the outside, and on the grinding surface 24a of the inclined upper surface, each extending in the radial direction and arranged along the circumferential direction, of the day 241 is formed.

The passage wall ring 25 is configured in a cylindrical shape with an inner diameter slightly larger than the outer diameter of the raw material discharge plate 23 . As shown in Fig. 11, the passage wall ring 25 is provided with a discharge port 251 that communicates the inside and outside thereof. The passage wall ring 25 constructed in this way is fixed to the case 1a so that its inner peripheral surfaces face the outer peripheral surfaces of the upper fine grinding ring 13 and the lower fine grinding ring 24, and surround the entire outer peripheral surface. . Thereby, between the outer peripheral surfaces of the upper fine grinding ring 13 and the lower fine grinding ring 24 and the inner peripheral surface of the passage wall ring 25, the coffee powder from the upper fine grinding ring 13 and the lower fine grinding ring 24 The sending passage 27 through which this is sent is partitioned.

The passage wall ring 25 is made of a material that tends to be electrically charged with coffee beans in terms of heat of charge, and specifically, is made of aluminum or polypropylene.

The guide member 26 is made of a resin molded product such as polyacetal, and is attached to the passage wall ring 25 in such a manner as to cover the discharge port 251 . The guide member 26 is for guiding the coffee powder discharged from the discharge port 251 downward to the powder raw material supply unit 4 .

Such a guide member 26 has a resistance piece 28 . The resistance piece 28 is, for example, a flat plate-shaped member made of a predetermined metal such as stainless steel, and as shown in FIG. 12 , its upper end is below the clamping portion 261 of the guide member 26 . The discharge port 251 is substantially blocked by being inserted from and held to be fitted. That is, the resistance piece portion 28 is detachably held by the guide member 26 and the upper end portion is clamped, whereby the portion downward from the center in the vertical direction can be elastically deformed.

The grinding operation of coffee beans in the coffee mill 1 configured as described above will be described. When a predetermined amount of coffee beans is put into the hopper 11 from the raw material canister, the coffee mill 1 drives the motor 3 before and after this, and drives the mill through the drive gear 3a and the intermediate gear 3b. The gear 22 is rotationally driven. As a result, the rotation shaft 213 of the rotary mill 20 rotates counterclockwise as viewed from above, and accordingly, the raw material feeder 21, the raw material discharge plate 23 and the lower fine grinding ring 24 are also viewed from above. rotate counterclockwise.

When the coffee beans in the hopper 11 reach the raw material feeder 21 , they are sent downward by the raw material feeder 21 . In this case, the spiral convex part 212 of the raw material feeder 21 and the grinding convex part 121 of the coarse grinding ring 12 cooperate to coarsely grind coffee beans. Specifically, on the coffee beans around the raw material feeder 21 , the pressing force from above by the spiral convex portion 212 acts, and the coffee beans are moved to the tip of the grinding convex portion 121 of the coarse grinding ring 12 . It is sheared by being pushed from above. Thereby, the coffee beans coarsely ground to a size that can pass between the raw material feeder 21 and the grinding convex portion 121 are passed through the space with the upper fine grinding ring 13 by the raw material feeder 21 . , sent between the upper fine grinding ring 13 and the lower fine grinding ring 24 .

As described above, the coarsely pulverized coffee beans are sent in the radial direction by the centrifugal force of the rotating lower fine grinding ring 24 , while grinding the upper fine grinding ring 13 and the lower fine grinding ring 24 . More finely, finely pulverized by the surfaces 13a and 24a. The coffee powder produced by this fine grinding is sent from between the upper fine grinding ring 13 and the lower fine grinding ring 24 to the sending passage 27 . Also in this case, as the raw material discharging plate 23 rotates, the plurality of blades 231 move around the dispensing passage 27 , and the coffee powder in the discharging passage 27 is transferred by these blades 231 . As it is collected, it is discharged from the discharge port 251 .

When the coffee powder is discharged from the discharge port 251 in this way, the resistance piece portion 28 pressed against the coffee powder is bent and elastically deformed in a manner spaced apart from the discharge port 251 as shown by the broken line in FIG. 12 . Thereby, after the coffee powder is guided to the powder raw material supply part 4 through the guide member 26, it is supplied to the extraction container.

As described above, according to the coffee mill 1, since the passage wall ring 25 is made of aluminum or polypropylene, which is a material that tends to be electrically charged with coffee beans in the heat of charge, the dispensing passage 27 Even if the coffee powder passing through is in contact with the passage wall ring 25, the transfer of electric charges is difficult to occur between the two, and the generation of static electricity can be reduced. Thereby, it can reduce that coffee powder adheres and remains inside an apparatus, and can discharge coffee powder favorably. Moreover, by reducing the generation of static electricity, it is possible to suppress the adhesion of coffee powder and the remaining on the inner wall surface of the powder raw material supply unit 4 or the inner wall surface of the extraction container downstream thereof, and supply to the coffee mill 1 . It can suppress that the supply_amount|feed_rate of the coffee powder to an extraction container falls with respect to the amount of coffee beans used, and it can suppress that an extraction container becomes dirty with the coffee powder which remains.

In particular, while the resistance piece portion 28 provided on the guide member 26 substantially occludes the discharge port 251 in a normal state, when coffee powder is discharged by the raw material discharge plate 23, the coffee powder Since it elastically deforms and opens the discharge port 251 by being pressed, this resistance piece 28 acts as a resistance member for the coffee powder discharged from the discharge port 251, so that the coffee powder and the passage wall ring in the discharge passage 27 It is possible to increase the contact ratio with (25). As a result, it is possible to favorably reduce the generation of static electricity.

In addition, since the resistance piece portion 28 is detachably attached to the guide member 26, the resistance piece portion 28 can be easily exchanged, eliminating the need for a dedicated tool or the like, and the adhesiveness of the resistance piece portion 28 can improve

13 is a perspective view showing a modified example of the pulverizing apparatus for extraction raw materials according to the embodiment of the present invention. The grinding device for an extraction raw material illustrated here is, for example, a coffee mill 1' that is applied to a cup-type vending machine, a beverage dispenser, or the like, and grinds coffee beans serving as an extraction raw material.

In such a coffee mill 1', similarly to the above-mentioned coffee mill 1, the mill main body 2, the motor 3, and the powder raw material supply part 4 are arranged in the case 1a, and are configured, and the mill A water supply unit (water supply means) 30 for supplying a small amount (eg, about 1 gram to 3 gram) of water to the main body 2 is provided. The water supply unit 30 supplies a small amount of water just before a predetermined amount of coffee beans are put into the hopper 11 from the raw material canister.

As described above, when the water supply unit 30 supplies a small amount of water to the mill main body 2 , the coffee powder is generated by the rotation of the lower fine grinding ring 24 constituting the rotary mill 20 , moisture This can reduce the generation of static electricity. Thereby, it can reduce that coffee powder adheres and remains inside an apparatus, and can discharge coffee powder favorably.

In particular, since the water supply unit 30 supplies a small amount of water just before a predetermined amount of coffee beans are put into the hopper 11 from the raw material canister, moisture can be evaporated due to heat during grinding of coffee beans, etc. , it is possible to suppress the occurrence of mold and the like in the mill main body 2 .

As mentioned above, although preferred embodiment of this invention and its modification were demonstrated, this invention is not limited to these, Various changes can be made.

In the above embodiment, aluminum or polypropylene is exemplified as the passage wall ring 25, but in the present invention, the material of the passage wall portion changes depending on the material of the extraction raw material, and tends to be charged with the extraction raw material on the heat of charge. Any material may be used as long as it is close to this material.

In the above-described embodiment, the resistance piece portion 28 is detachably provided on the guide member 26, but in the present invention, the resistance piece portion may be provided other than the guide member.

1: coffee mill 1a: case
2: Mill body part 10: Immovable mill part
11: Hopper 12: Crush ring
13: upper fine grinding ring 20: rotary mill
21: raw material feeder 22: mill gear
23: raw material discharge plate 231: wing portion
24: lower fine grinding ring 25: passage wall ring
251: outlet 26: guide member
27: transmission passage 28: resistance piece part

Claims (6)

a rotary grinding unit configured to be rotatable about its central axis, and pulverizing the supplied extraction raw material while rotating, and sending the powdered raw material, which is the pulverized extraction raw material, in the radial direction of the central axis;
a passage wall portion disposed so as to surround the entire outer circumferential surface while opposing the outer circumferential surface of the rotary crushing unit, and dividing a delivery passage through which the powder raw material is delivered between the outer circumferential surface;
a raw material discharging unit having a movable part movable in the dispensing passage, collecting the powdered raw material sent to the dispensing passage when the movable part moves in the dispensing passage, and discharging the powdered raw material from a discharge port formed in the passage wall portion
As a pulverizing device for extraction raw materials comprising:
The passage wall portion is constituted of a material having a tendency to be close to being charged with the extraction raw material in the phase of electrification,
a guide member for guiding the powder raw material discharged from the discharge port downward;
While the discharge port is closed in a normal state, when the powder raw material is discharged by the raw material discharge unit, the resistance piece part is elastically deformed by being pressed by the powder material to open the discharge port.
to provide
and the resistance piece part is made of metal, wherein the upper end part is inserted into the clamping part of the guide member and is separably clamped. The method of claim 1,
The passage wall portion is made of aluminum or polypropylene. delete delete a rotary grinding unit configured to be rotatable about its central axis, and pulverizing the supplied extraction raw material while rotating, and sending the powdered raw material, which is the pulverized extraction raw material, in the radial direction of the central axis;
a passage wall portion disposed so as to surround the entire outer circumferential surface while opposing the outer circumferential surface of the rotary crushing unit, and dividing a delivery passage through which the powder raw material is delivered between the outer circumferential surface;
a raw material discharging unit having a movable part movable in the dispensing passage, collecting the powdered raw material sent to the dispensing passage when the movable part moves in the dispensing passage, and discharging the powdered raw material from a discharge port formed in the passage wall portion
As a pulverizing device for extraction raw materials comprising:
and a water supply means for supplying a small amount of water to the rotary grinding unit. 6. The method of claim 5,
The water supply means supplies the water before the pulverization of the extraction raw material.

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