JP5428043B2 - Powder and particle feeder - Google Patents

Description

  The present invention relates to a granular material supply apparatus capable of discharging a granular material downward from a granular material container.

  As this kind of conventional powder supply device, the powder is discharged from the powder outlet through the bottom wall of the powder container by rotating the rotating body inside the container inside the powder container. What discharged | emitted the body is known (for example, refer patent document 1).

Japanese Patent Laid-Open No. 7-41083 (paragraph [0006], FIG. 2)

  However, in the above-mentioned conventional granular material supply device, the granular material discharge port is always open, so even if the rotating body in the container is stopped, the granular material leaks due to vibration of the granular material container, etc. There was something to do. In order to solve this problem, it is conceivable to close the powder outlet by attaching a cap after finishing the supply, but when resuming the supply of the powder, the cap must be removed. The work of attaching and detaching was troublesome.

  This invention is made | formed in view of the said situation, and aims at provision of the granular material supply apparatus which can open and close a granular material discharge port more easily than before.

In order to achieve the above object, the granular material supply device according to the invention of claim 1 includes a granular material container that accommodates the granular material and a central portion of the bottom wall of the granular material container in the vertical direction. a circular particulate material outlet penetrating into, contact or away from the lower to the opening edge of the powder or granular material discharge port, you can open and close the powder or granular material discharge port, it a reduced diameter conically upward A rotating body in the container for discharging the granular material from the granular material outlet, and rotating in the granular material container with the granular material outlet being opened, and the granular material outlet A power transmission shaft which is disposed on the central axis and extends in the up-down direction, and the in-container rotating body is fixed to the middle portion of the up-down direction so as to be integrally rotatable, and the valve body is fixed to the lower end portion of the valve body so as to be integrally movable. , A linear motion drive source for applying axial force to the power transmission shaft, and opening and closing the granular material outlet with the valve body, and the granular material outlet opening And in by applying a torque to the power transmission shaft, a rotational drive source for rotating the container rotation body, provided in an opening edge of the powder or granular material outlet, abuts a valve seat in the conical slope of the valve body, Standing up from the conical slope of the valve body, it is arranged in a discharge path extending vertically from the upper surface of the bottom wall of the powder container to the powder outlet, and can be swung in a state adjacent to the inner surface of the discharge path And a valve body fixed rotating body .

The invention of claim 2 includes a powder container containing powder, a circular powder outlet through the center of the bottom wall of the powder container, and a powder discharge. A valve body that can be opened and closed with respect to the opening edge of the outlet to open and close the powder outlet, and rotates in the powder container with the powder outlet open. A container rotating body for discharging powder particles from the outlet and a central axis of the powder particle discharging port and extending in the vertical direction, and the container rotating body can be rotated integrally with the middle part in the vertical direction A power transmission shaft that is fixed and fixed to the lower end so that the valve body can be moved linearly, and a linear motion drive that opens and closes the particulate discharge port by applying an axial force to the power transmission shaft. a source, by applying a torque to the power transmission shaft in a state of powder or granular material discharge port is opened, a rotary drive source for rotating the container rotation body, granular From the upper surface of the bottom wall of the container to the powder or granular material discharge port is disposed in a discharge passage extending vertically, and a screw portion formed of a helical ridge or helical grooves or helical coil integrally provided on the power transmission shaft And a granular material rotation guide that collects the granular material on the bottom wall of the granular material container and guides the granular material in the discharge path .

The invention of claim 3 includes a powder container containing powder, a circular powder outlet through the center of the bottom wall of the powder container, and a powder discharge. A valve body that can be opened and closed with respect to the opening edge of the outlet to open and close the powder outlet, and rotates in the powder container with the powder outlet open. A container rotating body for discharging powder particles from the outlet and a central axis of the powder particle discharging port and extending in the vertical direction, and the container rotating body can be rotated integrally with the middle part in the vertical direction A power transmission shaft that is fixed and fixed to the lower end so that the valve body can be moved linearly, and a linear motion drive that opens and closes the particulate discharge port by applying an axial force to the power transmission shaft. Source and a rotational drive source for applying torque to the power transmission shaft in a state where the granular material discharge port is opened to rotationally drive the rotating body in the container. A shaft movable rotating body having a non-circular through hole which is provided with a non-circular rotary connecting shaft portion in the middle of the power transmission shaft, and which is relatively non-rotatably fitted to the rotary connecting shaft portion. Is provided as a rotating body in a container.

According to a fourth aspect of the present invention, in the granular material supply device according to the third aspect, the shaft movable rotating body is sandwiched between the fixed body of the granular material container and the bottom wall of the granular material container, and the shaft It is characterized in that a linear motion restricting member that allows the rotation of the movable rotating body and restricts the vertical movement of the shaft movable rotating body is provided.

The invention of claim 5 is directed to the inside of the discharge passage extending in the vertical direction from the upper surface of the bottom wall of the powder container to the powder discharge port in the powder supply apparatus according to claim 3 or 4. And a scraper that protrudes downward from the shaft movable rotating body and scrapes off the granular material from the inner surface of the discharge path.

The invention of claim 6 includes a powder container containing powder, a circular powder outlet opening vertically through the center of the bottom wall of the powder container, and powder discharge. A valve body that can be opened and closed with respect to the opening edge of the outlet to open and close the powder outlet, and rotates in the powder container with the powder outlet open. A container rotating body for discharging powder particles from the outlet and a central axis of the powder particle discharging port and extending in the vertical direction, and the container rotating body can be rotated integrally with the middle part in the vertical direction A power transmission shaft that is fixed and fixed to the lower end so that the valve body can be moved linearly, and a linear motion drive that opens and closes the particulate discharge port by applying an axial force to the power transmission shaft. Source and a rotational drive source for applying torque to the power transmission shaft in a state where the granular material discharge port is opened to rotationally drive the rotating body in the container. A work case having a closed space isolated from the outside is provided, and the powder container is accommodated in the closed space of the work case and suspended from the ceiling wall of the work case, and a rotational drive source and a linear drive source are provided. A torque transmission magnet coupling that is arranged outside the work case and magnetically couples the rotation output part of the rotational drive source and the power transmission shaft via the wall of the work case so that they can rotate integrally or interlocked with each other, and direct drive It has a feature in that it includes an axial force transmission magnet coupling that magnetically couples the linear motion output portion of the source and the power transmission shaft via the wall portion of the work case so as to be capable of linear motion integrally.

According to a seventh aspect of the present invention, in the granular material supply device according to the sixth aspect, the inner surface of the granular material container has a conical inner surface whose diameter is increased upward from the granular material discharge port. It is characterized in that an axially fixed rotating body that extends along a generatrix of the inner surface and that can turn in a state adjacent to the inner surface of the cone is provided as a rotating body in the container.

The invention of claim 8 is the granular material supply apparatus according to claim 6 or 7, wherein the powder body supply apparatus is disposed inside the work case, and is fixed so as to rotate integrally with the power transmission shaft and to move integrally with the power transmission shaft. A coupling inner magnet and a cup that is disposed outside the work case and is magnetically coupled to the coupling inner magnet via the wall of the work case so as to rotate integrally with the coupling inner magnet and to move integrally with the inner magnet. An integral linear motion rotation type magnet coupling consisting of an outer magnet for the ring is provided as a torque coupling magnet coupling and an axial force transmission magnet coupling, and the coupling outer magnet and the rotational output portion of the rotational drive source Are coupled by a spline mechanism that allows mutual linear motion and transmits rotation. A linearly driven biasing means that keeps the powder particle discharge port closed by always biasing the power transmission shaft upward by providing a magnetic body to be attracted fixed to the magnet, and attracted by being energized by energization It is characterized in that a magnetic body is magnetically attracted downward against the urging force of the direct acting urging means, and a solenoid capable of opening the powder body discharge port is provided as a direct drive source.

A ninth aspect of the present invention provides the granular material supply device according to any one of the second to eighth aspects, wherein the valve body has a conical shape with a diameter reduced upward, and the granular material discharge port It is characterized in that a valve seat that abuts on the conical slope of the valve body is provided at the opening edge.

[Invention of Claims 1 , 2, 3, 6 ]
According to the first , second, third , and sixth inventions, when supplying the granular material, a downward axial force is applied to the power transmission shaft by the linear motion drive source so that the valve body is the granular material discharge port. In this state, a torque is applied to the power transmission shaft by the rotational drive source to rotate the in-container rotating body. Thereby, a granular material can be discharged | emitted from a granular material discharge port. When the supply of the granular material is finished, the application of torque to the power transmission shaft is stopped, and an upward axial force is applied to the power transmission shaft by the direct drive source to remove the valve body from the granular material. Touch the opening edge of the outlet. Then, since a valve body obstruct | occludes a granular material discharge port, the leakage of a granular material can be prevented. Thus, according to this invention, compared with the conventional structure which opens and closes a granular material discharge port by removing a cap, a granular material discharge port can be opened and closed easily.

Further, according to the first aspect of the present invention, since a toward the valve body upwards reduced diameter conical, granular material when the open state is prevented from being deposited on the valve body In the closed state, it is possible to prevent a situation in which a gap is formed by biting the granular material between the valve body and the valve seat. Furthermore, when the valve body fixed rotator rotates in the discharge path, the powder particles in the discharge path flow, and clogging due to arch formation and aggregation of the powder particles can be prevented. Moreover, the granular material adhering to the inner surface of the discharge path can be dropped.

According to the second aspect of the present invention, the screw part rotates in the discharge path, so that the granular material in the discharge path can be smoothly fed toward the granular material discharge port. Further, it is possible to rotate and drive the granular material rotation guide by the torque applied to the power transmission shaft from the rotational drive source, collect the granular material on the bottom wall of the granular material container and guide it into the discharge path. it can.

According to the invention of claim 3, for example, even if the shaft movable rotating body is buried in the powder and cannot move in the vertical direction, the power transmission shaft can move directly with respect to the shaft movable rotating body. It is possible to reliably open and close the powder outlet.

According to the invention of claim 6, the granular material container is accommodated in the closed space of the work case and discharges the granular material into the closed space, while the rotational drive source and the direct drive source are the Since it can be arranged outside, it is possible to prevent damage and contamination of the rotational drive source and the linear motion drive source due to the temperature, pressure, gas atmosphere and powder in the work case.

[Invention of claim 4 ]
According to the invention of claim 4 , since the vertical movement of the shaft movable rotating body in the powder container is restricted, it is possible to suppress the rising of the powder body due to the vertical movement of the shaft movable rotating body.

[Invention of claim 5 ]
According to invention of Claim 5, the granular material adhering to the inner surface of the discharge path can be scraped off.

[Invention of Claim 7 ]
According to invention of Claim 7 , a granular material is guided to the cone inner surface of a granular material container, and moves toward a granular material discharge port with dead weight. And the granular material adhering to the cone inner surface can be scraped off by rotating in a state where the shaft-fixed rotating body is adjacent to the cone inner surface. Further, since the shaft-fixed rotating body causes the powder particles to flow, clogging due to arch formation and aggregation of the powder particles can be prevented.

[Invention of Claim 8 ]
According to the invention of claim 8, the torque of the rotational drive source is applied to the power transmission shaft via the coupling outer magnet and the coupling inner magnet. In addition, the magnetic force to be attracted is linearly moved in the vertical direction by the excitation of the solenoid provided as the linear drive source or the biasing force of the linear biasing means, and the axial force associated with the linear motion is applied to the outer magnet for coupling. And it can give to a power transmission shaft through the inner magnet for coupling, and a granular material discharge port can be opened and closed by a valve body. According to the present invention, since one integral linear motion rotation type magnet coupling composed of an inner magnet for coupling and an outer magnet for coupling can transmit both torque and axial force, The number of parts can be reduced and the structure can be simplified as compared with the axial force transmission and separate magnet couplings.

[Invention of claim 9 ]
According to the invention of claim 9, since the valve body has a conical shape whose diameter is reduced upward, it is possible to prevent the powder particles from being deposited on the valve body when opened. When it is in the closed state, it is possible to prevent a situation in which a gap is formed by biting the granular material between the valve body and the valve seat.

The front view of the granular material supply apparatus which concerns on 1st Embodiment of this invention. Side cross-sectional view of powder supply device Perspective view of powder rotation guide (A) Side view of valve body and screw part, (B) Side view of screw part according to modified example, (C) Side view of screw part according to modified example (A) Side sectional view of solenoid and magnet coupling in closed state, (B) Side sectional view of solenoid and magnet coupling in opened state (A) Side sectional view of a state in which the valve body closes the granular material discharge port, (B) Side sectional view of a state in which the valve body opens the granular material discharge port Front view of granular material supply device and replenishment device according to second embodiment Partial side sectional view of replenishing device Side view of supply drum The front view of the granular material supply measurement system which concerns on 3rd Embodiment Perspective view of the weighing instrument as seen from above Partial enlarged cross-sectional view of powder supply device Side view of granular material supply apparatus according to fourth embodiment Side cross-sectional view of powder supply device Partial cross-sectional view of the powder container Partial side sectional view of the powder supply device in the open state (A) Side cross-sectional view of a state in which the valve body closes the granular material discharge port, (B) Side cross-sectional view of the state in which the valve body opens the granular material discharge port (A) Partial expanded sectional view of the granular material supply apparatus according to the modification, (B) Partial enlarged sectional view of the granular material supply apparatus according to the modification. The top view of the granular material supply measurement system concerning a modification Sectional drawing of the granular material supply apparatus which concerns on a modification

[First Embodiment]
Hereinafter, the granular material supply apparatus 10 which concerns on 1st Embodiment of this invention is demonstrated based on FIGS. As shown in FIG. 1, the powder supply apparatus 10 includes a supply drum 11 (corresponding to the “powder container” of the present invention) that can store powder in a closed space in the work case 100. ing.

  The work case 100 has, for example, a box structure having an opening 101 only on one side surface thereof, and includes a door 102 that can close the opening 101 and an intake / exhaust pipe 103. The intake / exhaust pipe 103 communicates with the inside and outside of the work case 100 and protrudes to the side, so that a pump or a gas supply source (not shown) can be connected thereto. Further, when the door 102 is closed, the closed space in the work case 100 can be hermetically sealed, and the work case 100 has a special atmosphere (for example, a predetermined pressure or a pressure different from the atmospheric pressure) Gas atmosphere different from the atmosphere).

  As shown in FIG. 1, the supply drum 11 is suspended from the ceiling wall 110 in the closed space of the work case 100. As shown in FIG. 2, the supply drum 11 includes a storage cylinder portion 12 and a discharge cylinder portion 13 having a smaller diameter than the storage cylinder portion 12, and is provided between a lower end portion of the storage cylinder portion 12 and an upper end portion of the discharge cylinder portion 13. Are connected by an intermediate step wall 14. The discharge cylinder part 13 protrudes vertically downward from the center part of the intermediate step wall 14, and the granular material accommodated in the accommodation cylinder part 12 extends perpendicularly to the intermediate step wall 14 inside the discharge cylinder part 13. It is discharged downward through the discharge path 13A. Note that the intersection of the inner peripheral surface of the discharge passage 13A and the upper surface 14A of the intermediate step wall 14 is inclined in a mortar shape.

  The upper end of the accommodating cylinder portion 12 is open and is closed by a drum cap 15. The drum cap 15 is screwed onto the outer peripheral surface of the upper end of the housing cylinder portion 12.

  A shaft insertion hole 15B is formed through the center of the drum cap 15, and a cylindrical screwing wall 15C stands from a side position of the shaft insertion hole 15B. A male spiral is formed on the outer peripheral surface of the cylindrical screwing wall 15C, and a stepped cylindrical cap 17 is screwed into the male spiral.

  The stepped cylindrical cap 17 has a cylindrical structure in which the lower end is open and the upper end is closed. The stepped cylindrical cap 17 is gradually reduced in diameter from the lower end portion toward the upper end portion, and the largest lower end cylindrical portion 17C is screwed and coupled to the outside of the cylindrical screwing wall 15C.

  In the center of the ceiling wall 110 of the work case 100, a case hollow protrusion 111 that receives the stepped cylindrical cap 17 is formed. As shown in FIG. 2, the case hollow protrusion 111 protrudes from the upper surface of the ceiling wall 110, the upper end is closed, and the lower surface is opened inside the work case 100. The case hollow protrusion 111 has a cylindrical structure in which the upper cylinder portion 112 with respect to the middle position in the vertical direction has a stepped small diameter with respect to the lower cylinder portion 113. Hereinafter, the upper cylindrical portion is referred to as “small-diameter cylindrical portion 112”, and the lower cylindrical portion is referred to as “large-diameter cylindrical portion 113”.

  The stepped cylindrical cap 17 is inserted from the lower end opening (opening on the inner surface of the ceiling wall 110) of the case hollow protrusion 111 into the cylindrical space inside. The outer side of the intermediate cylinder part 17B located immediately above the lower end cylinder part 17C in the stepped cylinder cap 17 is surrounded by the large diameter cylinder part 113, and the outer side of the upper end cylinder part 17A located immediately above the intermediate cylinder part 17B. Is surrounded by the small diameter cylindrical portion 112.

  A housing 120 is fixedly placed on a stepped wall formed between the large-diameter cylindrical portion 113 and the small-diameter cylindrical wall 112 in the case hollow protrusion 111. The housing 120 has a cylindrical structure having the same diameter as the large-diameter cylindrical portion 113, and a fitting hole 121 is formed through the center of the lower end wall. The small-diameter cylindrical portion 112 is fitted into the fitting hole 121, and the housing 120 is positioned coaxially with the case hollow protrusion 111. The upper end of the housing 120 is closed, and a motor 50 (corresponding to the “rotation drive source” of the present invention) is fixed to the upper end surface.

  A rotation output shaft 52 (corresponding to the “rotation output portion” of the present invention) is connected to a rotor (not shown) of the motor 50. The rotation output shaft 52 protrudes from the lower surface of the motor 50 and extends through the upper end wall of the housing 120 into the internal space.

  A power transmission shaft 20 is accommodated inside the supply drum 11 and the stepped cylindrical cap 17. The power transmission shaft 20 passes through the shaft insertion hole 15B of the drum cap 15, is disposed on the center axis of the stepped cylindrical cap 17 and the supply drum 11, and extends in the vertical direction. The power transmission shaft 20 is connected in a non-contact state with a rotation output shaft 52 of a motor 50 disposed outside the work case 100, and rotates upon receiving torque from the motor 50.

  Inside the stepped cylindrical cap 17 is accommodated a bearing member 60 that supports the power transmission shaft 20 so as to be rotatable and linearly movable. The bearing member 60 is accommodated in the stepped cylindrical cap 17 so as not to be rotatable and to be linearly movable inside the intermediate cylinder portion 17B.

  The bearing member 60 has a hollow cylindrical structure in which openings at both ends of a cylindrical body portion 63 fitted inside the intermediate cylindrical portion 17B are closed with an upper end bearing disc 61 and a lower end bearing disc 62. Circular bearing holes 61A and 62A are formed through the respective center portions of the upper end bearing board 61 and the lower end bearing board 62, and the outer peripheral surface of the power transmission shaft 20 extends in the circumferential direction and the shaft through these bearing holes 61A and 62A. It penetrates in a state where it can slide in the direction. A gap is formed between the outer peripheral surface of the power transmission shaft 20 and the inner peripheral surface of the cylinder body 63. A hanging cylinder 64 projects downward from the peripheral edge of the bearing hole 62 </ b> A of the lower end bearing board 62, and the hanging cylinder 64 is fitted inside the shaft insertion hole 15 </ b> B of the drum cap 15.

  An inner drum holding magnet 65 is fixed at a position near the upper end of the cylindrical body 63 in the bearing member 60. The inner drum holding magnet 65 has a structure in which a plurality of magnet rings 65R are coaxially stacked, and each magnet ring 65R is provided with different magnetic poles alternately arranged in the circumferential direction. Specifically, it is equally divided into a plurality of magnetic poles in the circumferential direction. Further, the plurality of magnet rings 65R are stacked such that different magnetic poles are adjacent to each other in the axial direction (vertical direction) of the bearing member 60, and the overlapping magnet rings 65R are fixed to each other by magnetic force.

  On the other hand, the upper surface of the ceiling wall 110 of the work case 100 is magnetically coupled to the inner drum holding magnet 65 with the case hollow protrusion 111 (large diameter cylindrical portion 113) and the stepped cylindrical cap 17 (intermediate cylindrical portion 17B) interposed therebetween. The outer drum holding magnet 115 is fixed. The outer drum holding magnet 115 has a cylindrical structure larger in diameter than the inner drum holding magnet 65 and is fitted to the outside of the large diameter cylindrical portion 113 in the case hollow protrusion 111. Similar to the inner drum holding magnet 65, the outer drum holding magnet 115 has a structure in which a plurality of magnet rings 115R are coaxially stacked. Each magnet ring 115R is provided with different magnetic poles arranged alternately in the circumferential direction. Specifically, it is equally divided into the same number of magnetic poles as the magnet ring 65R. The plurality of magnet rings 115R are overlapped so that different magnetic poles are adjacent to each other in the axial direction of the case hollow protrusion 111, and the overlapping magnet rings 115R are fixed to each other by magnetic force.

  The magnet rings 65R of the inner drum holding magnet 65 are arranged inside the magnet rings 115R of the outer drum holding magnet 115, and their opposing surfaces in the radial direction are different magnetic poles. Thereby, the inner drum holding magnet 65 and the outer drum holding magnet 115 are magnetically coupled, and the supply drum 11 is held in a suspended state from the ceiling wall 110 of the work case 100 by the magnetic coupling force. Note that the supply drum 11 is gripped and pulled directly below to cancel the magnetic coupling between the inner drum holding magnet 65 and the outer drum holding magnet 115, and the supply drum 11 together with the stepped cylindrical cap 17 and the work case 100. It can be removed from the ceiling wall 110.

  Here, a pin 17P protrudes upward from an annular stepped surface formed between the lower end cylindrical portion 17C and the intermediate cylindrical portion 17B in the stepped cylindrical cap 17. The pins 17P are provided at two locations that are 180 degrees apart from each other in the circumferential direction of the stepped cylindrical cap 17. On the other hand, a pair of pin holes 110 </ b> P and 110 </ b> P are formed on the inner surface of the ceiling wall 110 of the work case 100 and in the vicinity of the lower end opening of the case hollow protrusion 111. When the pins 17P and the pin holes 110P engage with each other in the vertical direction, relative rotation of the supply drum 11 with respect to the ceiling wall 110 and movement in the horizontal direction are prohibited.

  The rotation output shaft 52 and the power transmission shaft 20 of the motor 50 are connected in a non-contact state by an integral linear motion rotation type magnet coupling MC1 (hereinafter simply referred to as “magnet coupling MC1”) according to the present invention. Has been. The magnet coupling MC1 has the following configuration.

  As shown in FIG. 5, a movable coupler 70 is connected to the rotation output shaft 52 by a spline mechanism. That is, the movable coupler 70 can move directly in the axial direction of the rotation output shaft 52 and cannot rotate relative to the rotation output shaft 52. The movable coupler 70 has a cylindrical wall portion 71 having an open lower end, and the cylindrical wall portion 71 is loosely fitted inside the housing 120. From the lower end opening of the cylindrical wall portion 71, a small-diameter cylindrical portion 112 in a case hollow projection 111 formed in the work case 100 enters, and the movable coupler 70 is free to rotate with respect to the small-diameter cylindrical portion 112. It is fitted. A cylindrical coupling outer magnet 73 (hereinafter simply referred to as “outer magnet 73”) is fixed to a portion near the lower end of the cylindrical wall portion 71 so as to be integrally rotatable.

  The outer magnet 73 has a structure in which a plurality of magnet rings 73R are coaxially stacked. As shown in FIG. 5, each magnet ring 73R includes a plurality of magnetic poles alternately arranged in the circumferential direction. Specifically, it is equally divided into a plurality of magnetic poles in the circumferential direction. The plurality of magnet rings 73R are overlapped so that different magnetic poles are adjacent to each other in the axial direction (vertical direction) of the outer magnet 73, and the overlapping magnet rings 73R are fixed to each other by magnetic force.

  On the other hand, a coupling inner magnet 74 (hereinafter simply referred to as “inner magnet 74”) is fixed to the upper end portion of the power transmission shaft 20 so as to be integrally rotatable. The inner magnet 74 has a cylindrical shape loosely fitted inside the upper end cylindrical portion 17 </ b> A of the stepped cylindrical cap 17.

  The inner magnet 74 has a structure in which a plurality of magnet rings 74R are stacked on the same axis. As shown in FIG. 5, each magnet ring 74R includes a plurality of magnetic poles alternately arranged in the circumferential direction. Specifically, it is equally divided into the same number of magnetic poles as the magnet ring 73R in the circumferential direction. Further, the plurality of magnet rings 74R are stacked such that different magnetic poles are adjacent to each other in the axial direction of the inner magnet 74, and the overlapping magnet rings 74R are fixed to each other by a magnetic force.

  The outer magnet 73 surrounds the inner magnet 74 with the small-diameter cylindrical portion 112 of the case hollow protrusion 111 and the upper cylindrical portion 17A of the stepped cylindrical cap 17 sandwiched therebetween. Specifically, the magnet rings 74R of the inner magnet 74 are arranged inside the magnet rings 73R of the outer magnet 73, and their opposing surfaces in the radial direction are different magnetic poles. That is, the outer magnet 73 and the inner magnet 74 are magnetically coupled so as to be integrally rotatable in a non-contact state. As a result, the torque of the motor 50 disposed above the work case 100 (the upper surface of the housing 120) is accommodated inside the work case 100 (specifically, inside the stepped cylindrical cap 17 and the supply drum 11). It is possible to transmit to the power transmission shaft 20.

  As shown in FIG. 2, in the portion of the power transmission shaft 20 accommodated in the supply drum 11, more precisely in the accommodating cylinder portion 12, an in-container disk 30 and a granular material rotation guide 21 are provided. It is attached.

  The in-container disc 30 is disposed at the center of the lower end portion of the storage cylinder portion 12, is loosely fitted inside the storage cylinder portion 12, and covers the upper end opening of the discharge cylinder portion 13. That is, the container inner disk 30 is a flat disk having a diameter smaller than the inner diameter of the accommodating cylinder part 12 and larger than the inner diameter of the discharge cylinder part 13.

  A non-circular through hole (not shown) (for example, a hexagonal hole) (not shown) is formed in the central portion of the inner disc 30. A connecting shaft portion 20A (corresponding to the “rotating connecting shaft portion” of the present invention) formed in the power transmission shaft 20 and having a non-circular cross section (for example, a hexagonal cross section) is fitted in the noncircular through hole. Yes. As a result, the container disc 30 can move linearly and cannot rotate with respect to the power transmission shaft 20, and rotates integrally with the power transmission shaft 20 within the housing cylinder 12 and descends by its own weight. ing.

  An upper surface standby guide 31 is provided inside the housing cylinder portion 12. The upper surface standby guide 31 extends from the upper end wall of the drum cap 15 toward the intermediate step wall 14 and the vertical plate 31A extends from the lower end portion of the vertical plate 31A toward the center of the housing cylinder portion 12 and extends into the container disc 30. It is comprised from the horizontal plate 31B arrange | positioned adjacent to the upper surface of this, and has comprised the substantially L shape.

  By attaching the horizontal plate 31B in contact with the side surface of the power transmission shaft 20, the horizontal plate 31B is inclined with respect to the rotation direction of the in-container disc 30, and the granular material deposited on the in-container disc 30 is horizontal. Guided by the plate 31B and pushed toward the edge of the in-container disc 30. Further, the horizontal plate 31B extends to a position adjacent to the side wall of the containing cylinder portion 12, and the granular material pushed out by the horizontal plate 31B is formed between the outer edge portion of the container inner disk 30 and the side wall of the containing cylinder portion 12. Drop to the middle step wall 14 from between.

  Here, the granular material deposited on the upper surface 14 </ b> A of the intermediate step wall 14 forms a pile of powdered fluid having a predetermined angle of repose between the outer edge of the inner disc 30 and the intermediate step wall 14. The angle of repose of the pile of particles is constant depending on the particles, and the pile of particles does not collapse unless external force is applied.

  A granular material rotation guide 21 is provided to apply an external force to the granular particle crest to break it up and send the granular material into the discharge cylinder portion 13 (discharge path 13A). The granular material rotation guide 21 is provided in a state of being sandwiched between the container disc 30 and the intermediate step wall 14, and as shown in FIG. The wings 23 and the dust wings 24 are extended.

  A non-circular through hole 25A (for example, a hexagonal hole) is formed in the central portion of the connecting plate 25, and the connecting shaft portion 20A of the power transmission shaft 20 is fitted therein. Thereby, the granular material rotation guide 21 is attached to the power transmission shaft 20 so as to be linearly movable and non-rotatable so as to rotate integrally with the power transmission shaft 20 in the housing cylinder portion 12 and to drop by its own weight. It has become. In other words, the powder collection blades 23 and the dust distribution blades 24 in the granular material rotation guide 21 are rotatable in a horizontal plane while being in sliding contact with the upper surface of the intermediate step wall 14. The granular material rotation guide 21 corresponds to the “in-container rotating body” and the “shaft movable rotating body” of the present invention.

  The dust collection blades 23 have a bent structure in which a plurality of flat plates are connected so as to swell on the opposite side to the rotation direction of the powder particle rotation guide 21, while the dust collection blades 24 are arranged in the rotation direction of the particle particle rotation guide 21. In an inclined state, the connecting plate 25 extends straight toward the side wall of the housing cylinder portion 12. Moreover, the dust collection blade | wing 23 is extended to the position where the front-end | tip was adjacent to the side wall of the accommodating cylinder part 12, and the dust collection blade | wing 24 is shorter than it.

  The granular material deposited on the upper surface 14A of the intermediate step wall 14 is guided to the center side of the intermediate step wall 14 covered with the in-container disk 30 by the powder collection blades 23 and sent into the discharge passage 13A. Moreover, the granular material which did not enter into the discharge path 13A is pushed back to the outside of the intermediate step wall 14 by the dust wings 24, and is taken into the discharge path 13A when the powder collection wings 23 pass next.

  As shown in FIG. 6, a scraper 26 extends downward from the connecting plate 25 of the granular material rotation guide 21. The scraper 26 has a "<" shape that is bent in the middle along the inner peripheral surface on the upper end side of the discharge passage 13A, and turns in a state adjacent to the inner peripheral surface of the discharge passage 13A. Thereby, while the granular material in the discharge cylinder part 13 is made to flow, the granular material adhering to the internal peripheral surface of 13 A of discharge paths can be scraped off.

  A screw portion 27 is provided in a portion of the power transmission shaft 20 that is disposed in the discharge path 13 </ b> A of the supply drum 11. As shown in FIG. 4A, the screw portion 27 is a spiral protrusion that extends so as to roll up as it goes forward in the rotational direction of the power transmission shaft 20 (clockwise as viewed from the axial upper end of the power transmission shaft 20). The strip 27A is integrally formed on the outer surface of the cylinder of the power transmission shaft 20, so that the powder particles in the discharge passage 13A are sent downward (powder particle discharge port 35) by the spiral protrusion 27A. It has become.

  As shown in FIG. 4B, the screw portion 27 has a structure in which a spiral groove 27 </ b> B extending on the front side in the rotational direction of the power transmission shaft 20 is provided on the cylindrical outer surface of the power transmission shaft 20. Alternatively, as shown in FIG. 4C, it may be constituted by a wire rod extending so as to wind up toward the front in the rotational direction of the power transmission shaft 20, that is, a spiral coil 27C.

  A valve body 28 is integrally formed at the lowest end of the power transmission shaft 20 below the screw portion 27. The valve body 28 has a truncated cone shape having a conical inclined surface 28A having a diameter reduced toward the upper side.

  On the other hand, as shown in FIG. 6, a valve seat nut 34 is screwed onto the outer peripheral surface of the discharge cylinder portion 13 in the supply drum 11. The bottom wall of the valve seat nut 34 is abutted against the lower end surface of the discharge cylinder 13, and a granular material discharge port 35 communicating with the discharge path 13 </ b> A is formed through the center of the bottom wall. The granular material discharge port 35 has a circular shape, and an annular edge portion 35E (corresponding to the “valve seat” of the present invention) having a right angle is formed over the entire circumference of the opening edge.

  The diameter of the annular edge portion 35E is the same as that of the middle part of the conical slope 28A of the valve body 28. Then, as shown in FIG. 6 (A), when the conical slope 28A of the valve body 28 comes into contact with the annular edge portion 35E, the granular material discharge port 35 is closed, and as shown in FIG. 6 (B), the annular edge When the conical slope 28A of the valve body 28 is separated from the portion 35E, the granular material discharge port 35 is opened.

  In this manner, the solenoid 80 is fitted and fixed to the outside of the housing 120 in order to open and close the granular material discharge port 35 by bringing the valve body 28 into and out of contact with the annular edge portion 35E. A plunger 81 (corresponding to the “attractable magnetic body” of the present invention) that moves up and down with respect to the rotation output shaft 52 when the solenoid 80 is excited and stopped is integrally fixed (see FIG. 5). Here, the plunger 81 and the rotation output shaft 52 are also connected by a spline mechanism. The plunger 81 moves linearly in the axial direction of the rotation output shaft 52, that is, in the vertical direction, and with respect to the rotation output shaft 52. The relative rotation is impossible.

  The plunger 81 and the upper end wall of the housing 120 are connected by a tension spring (not shown) (corresponding to the “linear motion urging means” of the present invention), and when the excitation of the solenoid 80 is stopped, the plunger 81 is connected. The movable coupler 70 is pulled by the tension spring and is disposed at a position closer to the upper end wall of the housing 120 (state shown in FIG. 5A).

  At this time, the entire power transmission shaft 20 connected to the movable coupler 70 by the outer magnet 73 and the inner magnet 74 is held at the upper end position of the linear motion stroke on the inner side of the stepped cylindrical cap 17 and the supply drum 11. The conical slope 28A of the valve body 28 provided at the lower end portion of the transmission shaft 20 is in contact with the annular edge portion 35E, that is, the granular material discharge port 35 is closed (the state shown in FIG. 6A). A disc-shaped magnet 19 is fixed to the inner surface of the upper end wall of the stepped cylindrical cap 17 (see FIG. 5), and the disc-shaped magnet 19 and the inner magnet 74 with the power transmission shaft 20 positioned at the upper end position. The uppermost magnet ring 74R attracts each other and cooperates with the tension spring to hold the power transmission shaft 20 at the upper end position.

  On the other hand, when the solenoid 80 is energized and excited, the plunger 81 (and the movable coupler 70) is magnetically attracted downward against the urging force of the tension spring. At this time, the entire power transmission shaft 20 connected to the movable coupler 70 by the outer magnet 73 and the inner magnet 74 is held at the lower end position of the linear motion stroke inside the stepped cylindrical cap 17 and the supply drum 11, The conical slope 28A of the valve body 28 provided at the lower end portion of the transmission shaft 20 is in a state of being separated from the annular edge portion 35E, that is, the granular material discharge port 35 is opened (state of FIG. 6B). The solenoid 80 and the tension spring correspond to the “linear motion drive source” of the present invention.

  The above is the description regarding the configuration of the present embodiment, and the operation in the case where the granular material is supplied by the granular material supply device 10 of the present embodiment will be described in detail below. When supplying the granular material to the receptacle 130 set in the work case 100, first, the solenoid 80 is energized to be in an excited state. Then, as shown in the change from FIG. 5 (A) to FIG. 5 (B), the plunger 81 and the movable coupler 70 move downward against the tension spring and are connected to the movable coupler 70 in a non-contact state. The transmission shaft 20 moves vertically downward inside the stepped cylindrical cap 17 and the supply drum 11. Then, as shown in the change from FIG. 6 (A) to FIG. 6 (B), the valve body 28 moves away from the annular edge 35E and moves below the powder discharge port 35, and the powder discharge port. 35 becomes an open state. Here, as shown in the change from FIG. 6 (A) to FIG. 6 (B), the powder rotation guide 21 and the container inner disk 30 are restricted from moving downward by the intermediate step wall 14. The power transmission shaft 20 moves linearly with respect to the granular material rotation guide 21 and the container inner disk 30. That is, even if the granular material rotation guide 21 and the container inner disk 30 become unable to move further downward by the intermediate step wall 14, only the power transmission shaft 20 is moved further downward. Thus, the particulate discharge port 35 can be opened reliably.

  As shown in FIG. 6B, when the granular material discharge port 35 is in an open state, the motor 50 is turned on, and the power transmission shaft 20 connected in a non-contact state with the rotation output shaft 52 is connected to the rotation output shaft 52. And rotate together. Then, in the supply drum 11, the powder particles are guided from the inner disk 30 to the intermediate step wall 14 by the upper surface standby guide 31, and the powder particles deposited on the upper surface 14 </ b> A of the intermediate step wall 14 are powder particles. The granular material guided to the discharge path 13 </ b> A by the rotation guide 21 and further guided into the discharge path 13 </ b> A is sent downward by the rotation of the screw portion 27 and discharged from the granular material discharge port 35.

  Here, the excitation of the solenoid 80 is intermittently repeated in a short cycle, so that the power transmission shaft 20 is vibrated up and down with the powder discharge port 35 being opened, and the powder is formed by the uneven shape of the screw portion 27. It may be discharged.

  When the supply of the powder is finished, the motor 50 is turned off and the excitation of the solenoid 80 is stopped. Then, as shown in the change from FIG. 5 (B) to FIG. 5 (A), the plunger 81 and the movable coupler 70 are pulled by the tension spring and moved upward, and are connected to the movable coupler 70 in a non-contact state. The entire transmission shaft 20 is lifted upward inside the stepped cylindrical cap 17 and the supply drum 11. At this time, as shown in the change from FIG. 6 (B) to FIG. 6 (A), the valve body 28 moves upward to approach the granular material discharge port 35, and the conical slope 28A becomes the annular edge portion 35E. In contact with each other, the particulate discharge port 35 is closed. Thereby, leakage of a granular material can be prevented. Here, as shown in the change from FIG. 6B to FIG. 6A, the powder rotation guide 21 and the container disc 30 are restricted from moving upward by the upper surface standby guide 31. The power transmission shaft 20 moves linearly with respect to the granular material rotation guide 21 and the container inner disk 30. That is, even if the granular material rotation guide 21 and the container inner disk 30 become unable to move further upward by the upper surface standby guide 31, only the power transmission shaft 20 can be moved further upward. The granular material discharge port 35 can be closed reliably. The upper surface standby guide 31 corresponds to the “linear motion restricting member” of the present invention.

  Thus, the granular material supply apparatus 10 of this embodiment is provided with the valve body 28 at the lower end portion of the power transmission shaft 20 extending in the vertical direction inside the supply drum 11 and the stepped cylindrical cap 17, and the power transmission shaft. The valve body 28 is brought into contact with and separated from the powder discharge port 35 by moving the valve 20 in the vertical direction by the solenoid 80 and the tension spring, so that the powder discharge port 35 can be opened and closed. Thereby, compared with the conventional structure which opens and closes a granular material discharge port by attaching or detaching a cap, the granular material discharge port 35 can be opened and closed easily.

  Further, since the valve body 28 includes the conical slope 28A whose diameter is reduced upward, it is possible to prevent the powder particles from being deposited on the valve body 28 when the valve body 28 is opened. And when it is set as a closed state, the situation (occlusion defect) where a granule is bitten between valve body 28 and annular edge part 35E and a gap is formed can be prevented. Moreover, since the screw part 27 rotates in the discharge path 13A, the powder particles can be discharged smoothly. Further, the scraper 26 can flow the powder particles in the discharge passage 13A to prevent arch formation and aggregation, and the powder particles attached to the inner surface of the discharge passage 13A can be scraped off. Furthermore, since the power transmission shaft 20 can move directly with respect to the granular material rotation guide 21 and the container disc 30, the granular material discharge port 35 can be reliably opened and closed by the valve element 28.

  The power transmission shaft 20 and the solenoid 80 and the motor 50 are magnetically coupled by a magnet coupling MC1 (an inner magnet 74 and an outer magnet 73), and the solenoid 80 and the motor 50 are connected to the work case 100 in which the supply drum 11 is accommodated. Since it can be arranged outside, the solenoid 80 and the motor 50 can be prevented from being damaged or contaminated by the temperature, pressure, gas atmosphere or powder in the work case 100.

  Furthermore, since both the torque and the axial force can be transmitted with one magnet coupling MC1, the number of parts is reduced compared to those with separate magnet couplings for torque transmission and axial force transmission. In addition, the structure can be simplified.

[Second Embodiment]
Hereinafter, a second embodiment of the present invention will be described with reference to FIGS. In the second embodiment, a replenishing device 200 is added to the granular material supply device 10 of the first embodiment. Hereinafter, the same components as those in the first embodiment are denoted by the same reference numerals, and redundant description is omitted.

  As shown in FIG. 7, a fixed base 310 is fixedly placed on the upper surface of the ceiling wall 110 of the work case 100. The fixed base 310 has a structure in which a pair of side plates 310B and 310B hang down from both sides of the horizontal base plate 310A toward the ceiling wall 110.

  The replenishing device 200 includes a replenishing drum 211 that can accommodate powder particles, and a motor 250 that is provided at a position directly above the replenishing drum 211. The supply drum 211 and the motor 250 are coaxially attached via a bracket 312 fixed to the base plate 310A of the fixed base 310.

  As shown in FIG. 8, the bracket 312 has a structure in which a sleeve 314 is fixed to the lower ends of a pair of side plates 313 and 313 suspended from the lower surface of the base plate 310A. The upper and lower ends of the sleeve 314 are open and the inside is partitioned vertically by a partition wall 315 provided in the middle in the axial direction.

  A motor 250 is fixed to the upper end of the sleeve 314 so as not to rotate. An output shaft 252 is connected to the rotor of the motor 250, and the output shaft 252 extends vertically toward the partition wall 315 inside the sleeve 314.

  The replenishing drum 211 can accommodate the powder particles in a sealed space in which the upper end opening of the accommodating cylinder portion 212 is closed with the large diameter cap 215, and the replenishing drum 211 has A small diameter cap 217 is screwed onto the outer peripheral surface. In the small-diameter cap 217, the lower half screwed into the cylindrical screwing wall 215C has a stepped larger diameter than the upper half, and the boss portion 217B projects from the center of the inner surface of the upper end wall.

  The portion above the step portion of the small diameter cap 217 is received inside the sleeve 314 and can be inserted / removed from the lower end opening of the sleeve 314. An uneven engagement portion is provided between the lower end surface of the sleeve 314 and the step portion of the outer peripheral surface of the small diameter cap 217, and relative rotation of the supply drum 211 with respect to the bracket 312 is prohibited.

  The rotation transmission shaft 220 is connected to the output shaft 252 of the motor 250 so as to be integrally rotatable in a non-contact state. The rotation transmission shaft 220 extends along the central axis inside the supply drum 211. The upper end portion of the rotation transmission shaft 220 extends through the large diameter cap 215 and inside the small diameter cap 217.

  A magnetic coupling between an upper coupler 253 fixed to the output shaft 252 and a lower coupler 240 fixed to the rotation transmission shaft 220 is provided between the output shaft 252 of the motor 250 and the rotation transmission shaft 220 of the supply drum 211. They are connected so that they can rotate together.

  The upper coupler 253 has a cylindrical shape and is fixed to the output shaft 252 so as to be integrally rotatable. A plurality of coupling magnets 254 are embedded in the lower end portion of the upper coupler 253 side by side in the circumferential direction. These coupling magnets 254 are flush with the lower end surface of the upper coupler 253 and are exposed downward. The plurality of coupling magnets 254 are arranged so that the magnetic poles of the exposed surfaces are alternately inverted in the circumferential direction of the upper coupler 253. Further, the upper coupler 253 is not in contact with the inner peripheral surface of the sleeve 314 and the partition wall 315 so that frictional resistance is not generated.

  On the other hand, the lower coupler 240 is fixed to a portion of the rotation transmission shaft 220 that protrudes upward from the large-diameter cap 215 and is accommodated inside the small-diameter cap 217. The lower coupler 240 has a cylindrical shape, and the rotation transmission shaft 220 is inserted and fitted into the center thereof from the lower end side, and the boss portion 217B of the small diameter cap 217 is inserted from the upper end side. Further, the lower coupler 240 is sandwiched between the upper end wall of the small-diameter cap 217 and the bearing 216 and is prohibited from moving in the axial direction (vertical direction).

  A plurality of coupling magnets 241 as many as the coupling magnets 254 provided in the upper coupler 253 are embedded in the upper end portion of the lower coupler 240 side by side in the circumferential direction. These coupling magnets 241 are flush with the upper end surface of the lower coupler 240 and are exposed upward. Further, the plurality of coupling magnets 241 are arranged so that the magnetic poles of the exposed surfaces are alternately inverted in the circumferential direction of the lower coupler 240.

  The coupling magnet 241 of the lower coupler 240 is attracted and magnetically coupled with the coupling magnet 254 of the upper coupler 253 with the upper end wall of the small diameter cap 217 and the partition wall 315 of the sleeve 314 interposed therebetween. Thus, it is possible to transmit the torque of the motor 250 (rotation output shaft 52) to the rotation transmission shaft 220 in a non-contact manner while the supply drum 211 is suspended from the bracket 312.

  A supply pipe 213 hangs from the center of the bottom wall 214 of the supply drum 211. The supply pipe 213 passes through the ceiling wall 110 of the work case 100, and the lower end portion that has entered the work case 100 is in a non-contact state with the normally open supply port 15 </ b> A formed in the drum cap 15 of the supply drum 11. Inserted (see FIG. 9). That is, the sealed space in the supply drum 211 communicates with the inside of the work case 100 via the supply pipe 213. Here, a portion of the ceiling wall 110 of the work case 100 through which the supply pipe 213 passes is sealed in an airtight state by the seal member 218.

  In the replenishing drum 211, similarly to the supply drum 11, a granular material rotation guide 221, an in-container disk 230, and an upper surface waiting guide 231 are accommodated. The granular material rotation guide 221 and the in-container disc 230 can rotate together with the rotation transmission shaft 220. The granular material deposited on the side of the container inner disk 230 in the bottom wall 214 of the replenishing drum 211 is bottomed by the granular material rotation guide 221 rotating between the container inner disk 230 and the bottom wall 214. It is guided to the center side of the wall 214 and fed into the upper end opening of the supply pipe 213. The lower end opening of the supply pipe 213 is positioned above the container disc 30 in the supply drum 11, and the granular material discharged from the lower end opening of the supply pipe 213 is separated from the intermediate step wall 14 of the supply drum 11 and It falls on the disc 30 in the container.

  Here, the flow assisting plate 222 extends from the lower end of the rotation transmission shaft 220. The flow assisting plate 222 is formed by cutting a flat plate into a crank shape, and is inserted into the supply pipe 213. The flow-down auxiliary plate 222 is rotated in the supply pipe 213 by the motor 250 to flow down the powder particles in the supply pipe 213 while stirring.

  Further, a receiving plate 219 is integrally provided at the lower end of the supply pipe 213. The receiving plate 219 is disposed to face the lower end opening of the supply pipe 213 with a gap therebetween, and the space between the receiving plate 219 and the lower end portion of the supply pipe 213 is open to the side. And the granular material which flowed down the supply pipe 213 is once received by the receiving plate 219.

  A rotating blade piece 222H is integrally provided at the lower end portion of the flow-down auxiliary plate 222. As shown in FIG. 9, the rotary blade 222 </ b> H protrudes from the lower end opening of the supply pipe 213 and protrudes laterally, and rotates on the upper surface of the receiving plate 219. And the granular material received by the receiving plate 219 is pushed out to the side and dropped from the receiving plate 219.

  As shown in FIG. 8, the replenishing device 200 includes a hopper 270 and a cylindrical chute 271 extending from the lower end portion thereof. The hopper 270 has a conical shape with an open top, and is disposed above the base plate 310A of the fixed base 310 (see FIGS. 7 and 8). On the other hand, the lower end of the chute 271 passes through the large-diameter cap 215 of the supply drum 211 and is inserted into the supply drum 211. Here, a portion of the large-diameter cap 215 through which the chute 271 passes is sealed in an airtight state by the seal member 273.

  In the chute 271, valves 272 and 272 are provided at an intermediate position in the vertical direction and a position near the lower end, respectively. The valves 272 and 272 can be switched between an open state and a closed state by manually operating a lever.

  An air supply port 274 connected to a pump (not shown) is provided at an intermediate position between the pair of valves 272 and 272 in the chute 271. For example, by operating the pump with the upper valve 272 closed and the lower valve 272 open, the work case 100 communicates with the supply drum 211 via the supply drum 211 and the supply pipe 213. A predetermined gas can be supplied to the gas, and the internal pressure can be adjusted by the gas.

  The above is the description regarding the structure of the replenishing device 200. Next, the operation of the replenishing device 200 will be described. When supplying powder particles to the supply drum 11, the motor 250 of the supply device 200 is turned on. When the motor 250 is turned on, the output shaft 252 and the rotation transmission shaft 220 connected in a non-contact state by the coupling magnets 241 and 254 rotate integrally, and the granular material rotation guide 221 rotates inside the supply drum 211. The granular material is guided to the supply pipe 213 by the granular material rotation guide 221, flows down in the supply pipe 213, and falls into the supply drum 11. As described above, according to the present embodiment, when supplying the granular material to the supply drum 11, it is not necessary to take out the supply drum 11 from the work case 100, so that the granular material can be easily supplied. The atmospheric state of the work case 100 can be maintained.

[Third Embodiment]
In the third embodiment, a measuring instrument 300 (for example, an electronic balance or a platform scale) is added to the configuration of the second embodiment to configure a powder supply and measurement system. The weight of the discharged granular material can be measured. Hereinafter, although this embodiment is described based on FIGS. 10-13, about the same structure as 1st and 2nd embodiment, the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted.

  As shown in FIG. 10, the measuring instrument 300 is placed on the upper surface of the base plate 310 </ b> A of the fixed base 310.

  A movable base 320 that can move up and down in a state of being separated from the ceiling wall 110 is provided above the work case 100. The movable base 320 has a vertically long rectangular frame structure. As shown in FIG. 11, in the movable base 320, the central portion of the upper horizontal bar 322 </ b> A extending in the horizontal direction is placed on the mounting table 301 of the measuring instrument 300. Of the movable base 320, a pair of side bars 321 and 321 extending in the vertical direction penetrates the base plate 310 </ b> A in a non-contact manner and hangs down to a position near the ceiling wall 110 of the work case 100. The lower horizontal plate 322 </ b> B that connects the lower ends of the pair of side bars 321 and 321 extends in the horizontal direction at a position spaced above the ceiling wall 110. In addition, a central through hole 322B1 is formed at the center of the lower horizontal plate 322B in the horizontal direction, and the case hollow protrusion 111 provided in the ceiling wall 110 of the work case 100 penetrates the central through hole 322B1 in a non-contact state. (See FIG. 12).

  An outer drum holding magnet 115 is fixed on the upper surface of the lower horizontal plate 322B so as to surround the central through hole 322B1. The outer drum holding magnet 115 is loosely fitted on the outer side of the case hollow protrusion 111 (large diameter cylindrical portion 113). Then, the change in the weight of the entire supply drum 11 including the contents of the supply drum 11 (powder and powder rotation guide 21) is transmitted from the inner drum holding magnet 65 to the outer drum holding magnet 115. A change in the weight of the entire supply drum 11 applied to the outer drum holding magnet 115 is transmitted to the measuring device 300 via the movable base 320. Thereby, it is possible to measure the weight of the granular material discharged from the supply drum 11 (supplied to the receiver 130) by a so-called “loss-in-weight method”.

[Fourth Embodiment]
Hereinafter, the granular material supply apparatus 400 which concerns on 4th Embodiment of this invention is demonstrated based on FIGS. The granular material supply apparatus 400 according to the present embodiment is configured by assembling a granular material storage tube 410 (corresponding to “a granular material container” of the present invention), solenoids 450 and 460 and a motor 470 to a fixed base 401. .

  As shown in FIG. 13, the powder particle storage tube 410 is held at the tip of a storage tube holding part 403 protruding in the horizontal direction from the main body 402 of the fixed base 401. The granular material accommodation tube 410 is integrally provided with a vertical tube portion 411 extending in the vertical direction and an inclined tube portion 412 inclined with respect to the vertical direction. Specifically, the inclined cylindrical portion 412 extends obliquely upward from the side opening 411A (see FIGS. 14 and 15) penetrating the cylindrical wall of the vertical cylindrical portion 411, and the internal space and the inclined cylindrical portion of the vertical cylindrical portion 411 are extended. The internal space 412 communicates with the side opening 411A. The inclined cylinder part 412 includes a branch cylinder part 413 with an open top end integrally formed with the vertical cylinder part 411, a connection cylinder part 415 screwed into the upper end of the branch cylinder part 413, and a branch cylinder via the connection cylinder part 415. The detachable cylinder part 414 is detachably connected to the part 413, and the openings of the detachable cylinder part 414 and the branch cylinder part 413 are opposed to each other.

  The branch cylinder part 413 and the connection cylinder part 415 and the connection cylinder part 415 and the detachable cylinder part 414 are screwed together. In addition, packing 416,416 is pinched | interposed between each open end of the branch cylinder part 413 and the attachment / detachment cylinder part 414, and the back wall of the connection cylinder part 415, and the inside of the granular material accommodation cylinder 410 is an airtight state. .

  The bottom wall inner surface 411B of the granular material accommodation tube 410 (vertical tube portion 411) is a horizontal plane, and the discharge passage 13A extends vertically downward from the center of the bottom wall inner surface 411B. The discharge path 13A is formed on the same axis as the central axis of the vertical cylinder portion 411. The granular material accommodated in the granular material accommodation cylinder 410 is discharged | emitted from the granular material discharge port 35 (refer FIG. 17 (B)) of the lower end part through the discharge path 13A.

  A partition wall 430 is provided at a central position in the axial direction (vertical direction) of the vertical cylinder portion 411. The partition wall 430 divides the internal region of the vertical cylinder part 411 into a powder and particle storage region R1 that communicates with the inside of the inclined tube part 412 below the partition wall 430 and a magnet storage region R2 above the partition wall 430. . In addition, a circular protrusion 430 </ b> A protruding in a stepped shape is formed at the center of the upper surface of the partition wall 430, and the center of the partition wall 430 is thicker than the outer edge.

  A power transmission shaft 420 is provided inside the vertical cylinder portion 411. The power transmission shaft 420 is disposed on the central axis of the vertical cylinder portion 411, that is, on the central axis of the granular material discharge port 35, and extends in the vertical direction. Further, the power transmission shaft 420 passes through the central portion of the partition wall 430 and is accommodated in both the granular material accommodation region R1 and the magnet accommodation region R2. The partition wall 430 functions as a “sliding bearing”, holds the power transmission shaft 420 on the central axis of the vertical cylinder portion 411, and can slide in the axial direction and the circumferential direction.

  The power transmission shaft 420 is connected to a rotor (not shown) of the motor 470 by a torque transmission magnet coupling MC2, and is rotatable inside the vertical cylindrical portion 411. The power transmission shaft 420 is connected to a plunger 461 that linearly moves the hollow portion 460A of the solenoid 460 in the vertical direction by the axial force transmission magnet coupling MC3, and the axial direction inside the vertical cylinder portion 411, that is, It can move in the vertical direction.

  The details are as follows. A motor 470 for applying torque to the power transmission shaft 420 is disposed outside the granular material storage tube 410. The motor 470 is fixed to the tip of a cantilevered motor holding portion 404 that protrudes from the main body 402 of the fixed base 401 toward the granular material accommodation tube 410. The rotation output shaft 471 fixed to the rotor of the motor 470 protrudes from the lower surface of the motor 470, passes through the motor holding portion 404, and extends parallel to the power transmission shaft 420 at a position offset to the side of the power transmission shaft 420. Yes. An outer magnet gear 472 is fixed to the rotation output shaft 471 so as to be integrally rotatable.

  On the other hand, an inner magnet gear 440 is fixed to a portion of the power transmission shaft 420 that passes through the partition wall 430 of the vertical cylinder portion 411 and is disposed in the magnet housing region R2. The inner magnet gear 440 is magnetically coupled to the outer magnet gear 472 in a non-contact manner with the cylinder wall of the vertical cylinder portion 411 interposed therebetween.

  The inner magnet gear 440 has a cylindrical shape. A spline hole is formed through the center of the inner magnet gear 440, and a spline shaft portion provided in the power transmission shaft 420 is inserted into and engaged with the spline hole. That is, the inner magnet gear 440 and the power transmission shaft 420 are coupled so as to be able to move directly and not to rotate. The inner magnet gear 440 and the outer magnet gear 472 constitute a torque transmission magnet coupling MC2. At the center of the lower end surface of the inner magnet gear 440, a circular depression 440A that can receive the circular protrusion 430A formed at the center of the upper surface of the partition wall 430 is formed.

  The above is the torque transmission magnet coupling MC2, and the axial force transmission magnet coupling MC3 is as follows.

  First, the solenoid 460 for applying an axial force to the power transmission shaft 420 is disposed outside the powder-containing container 410. The solenoid 460 is held at the tip of a cantilever-like solenoid holding portion 405 protruding from the main body 402 of the fixed base 401 to a position directly above the vertical cylinder portion 411. The solenoid 460 has a hollow portion 460 </ b> A disposed on the same axis as the power transmission shaft 420, and is configured such that the plunger 461 moves in the vertical direction on the same axis as the power transmission shaft 420. The plunger 461 has a coupling outer magnet 462 (hereinafter simply referred to as “outer magnet 462”) fixed to a lower end portion of the plunger 461 that protrudes from the lower end surface of the solenoid 460. The outer magnet 462 is an electromagnet, and can reverse the polarity by reversing the direction of the current. The lower surface of the solenoid 460 and the outer magnet 462 are connected by a tension spring (not shown) (corresponding to the “linear motion urging means” of the present invention). When the solenoid 460 is excited, the tension spring When the excitation is stopped, the plunger 461 and the outer magnet 462 move vertically upward by the biasing force of the tension spring.

  On the other hand, a coupling inner magnet 441 (hereinafter simply referred to as “inner magnet 441”) that is magnetically coupled to the outer magnet 462 via the upper end wall of the vertical cylinder portion 411 is fixed to the upper end portion of the power transmission shaft 420. ing. The inner magnet 441 is a ring-shaped permanent magnet, and is fixed on a fixed plate 442 fixed to the upper end portion of the power transmission shaft 420.

  When the solenoid 460 is energized with the outer magnet 462 and the inner magnet 441 repelling each other, the power transmission shaft 420 moves vertically downward inside the vertical cylinder portion 411. On the other hand, when the excitation of the solenoid 460 is stopped in a state where the outer magnet 462 and the inner magnet 441 are attracted to each other, the power transmission shaft 420 vertically moves inside the vertical cylinder portion 411. The outer magnet 462 and the inner magnet 441 constitute an axial force transmission magnet coupling MC3.

  A holding magnet 443 is fixed to the inner surface of the upper end wall of the vertical cylinder portion 411. The holding magnet 443 can be loosely fitted in the center hole of the ring-shaped inner magnet 441. Even when the magnetic force of the outer magnet 462 disappears in a state where the holding magnet 443 is disposed at the center of the inner magnet 441, the inner magnet 441 and the holding magnet 443 attract each other, so that the power transmission shaft 420 is attracted. Can be held at the upper end position.

  Here, when the power transmission shaft 420 is rotationally driven, the inner magnet gear 440 is separated from the inner magnet 441 so that the magnetic force acting between the inner magnet 441 and the inner magnet gear 440 does not hinder the rotation. Let Therefore, the inner magnet gear 440 can be directly moved with respect to the power transmission shaft 420, and the outer magnet gear 472 can also be directly moved with respect to the rotation output shaft 471.

  Specifically, the outer magnet gear 472 is connected to the rotation output shaft 471 of the motor 470 by a spline mechanism. That is, the outer magnet gear 472 can move linearly and cannot rotate with respect to the rotation output shaft 471. In addition, a solenoid 450 as a direct drive source of the outer magnet gear 472 is fixed to the motor holding portion 404.

  The solenoid 450 is fixed at a position near the base end of the motor holding unit 404. A plunger 451 that is linearly movable in the axial direction, that is, the vertical direction is inserted into the hollow portion 450A of the solenoid 450. A rotation support plate 452 is fixed to a lower end portion of the plunger 451 protruding from the lower surface of the solenoid 450. The rotation support plate 452 extends to a position near the cylinder wall of the vertical cylinder portion 411, and a support hole 453 is formed through the extension line of the rotation output shaft 471 in the rotation support plate 452.

  On the other hand, a bearing fitting cylinder portion 473 is formed at the lower end of the outer magnet gear 472, and this bearing fitting cylinder portion 473 is fitted inside a bearing 454 fitted in the support hole 453. That is, the outer magnet gear 472 is rotatably supported between the rotation output shaft 471 and the rotation support plate 452.

  The solenoid 450 and the rotation support plate 452 are connected by a tension spring (not shown). When the solenoid 450 is excited, the plunger 451 and the rotation support plate 452 are moved vertically downward against the urging force of the tension spring. When the excitation is stopped, the plunger 451 and the rotation support plate 452 move vertically upward by the urging force of the tension spring.

  That is, the outer magnet gear 472 moves downward with respect to the rotation output shaft 471 by the excitation of the solenoid 450, and the inner magnet gear 440 magnetically coupled to the outer magnet gear 472 is connected to the power transmission shaft 420 in the magnet housing region R2. On the other hand, it moves downward. Further, when the excitation of the solenoid 450 is stopped, the outer magnet gear 472 moves upward with respect to the rotation output shaft 471, and the inner magnet gear 440 that is magnetically coupled to the outer magnet gear 472 is within the magnet housing region R2. Move upwards.

  Here, since the inner magnet gear 440 cannot be moved further downward by contacting the partition wall 430, the magnetic coupling with the outer magnet gear 472 is eliminated, and the inner magnet gear 440 The situation of falling to the bottom of 411 can be prevented.

  Now, of the power transmission shaft 420 that is rotatable and linearly movable inside the vertical cylindrical portion 411 as described above, the portion disposed in the granular material containing region R1 has a non-circular cross section (for example, a hexagonal cross section). A connecting shaft 420A is provided. A granular material rotation guide 421 for feeding the granular material to the discharge passage 13A is attached to the connecting shaft portion 420A so as to be linearly movable and non-rotatable. The granular material rotation guide 421 is lowered by its own weight, and the power transmission shaft 420 is rotated by the torque applied from the motor 470, thereby rotating in the horizontal plane while being in sliding contact with the bottom wall inner surface 411B.

  An upright plate 422 that extends along the cylinder wall inner surface 411C of the vertical cylinder portion 411 and turns around the cylinder wall inner surface 411C is integrally formed with the powder particle rotation guide 421. When the upright plate 422 rotates inside the vertical cylinder portion 411, the powder particles can be flowed to prevent aggregation or to be agitated.

  A portion of the power transmission shaft 420 disposed inside the discharge path 13 </ b> A is provided with a screw portion 423. The screw portion 423 is formed of a helical coil that is wound around the power transmission shaft 420 and fixed so as not to rotate. The screw portion 423 extends so as to wind up toward the front in the rotation direction of the power transmission shaft 420 by the motor 470 (clockwise direction as viewed from the axial upper end side of the power transmission shaft 420). , The powder particles in the discharge passage 13 </ b> A are sent downward, that is, to the powder particle discharge port 35.

  Next, the operation of this embodiment will be described. Prior to starting the supply of the powder particles, the powder particles are first filled into the powder particle storage cylinder 410. Specifically, as shown in FIG. 15, the power transmission shaft 420 is held at the upper end position, and the granular material discharge port 35 is closed by the valve body 28, and the granular material previously arranged in the removable cylinder portion 414. The detachable tube portion 414 is quickly screwed into the connecting tube portion 415 while pouring the body into the branch tube portion 413. The granular material slides down from the removable cylindrical portion 414 to the branched cylindrical portion 413 and the vertical cylindrical portion 411 due to the inclination of the inclined cylindrical portion 412.

  Next, a current is passed through the outer magnet 462 to repel the inner magnet 441 so that the solenoids 450 and 460 are excited together. When the plunger 461 moves downward due to the excitation of the solenoid 460, the power transmission shaft 420 moves vertically downward inside the vertical cylinder portion 411 due to the repulsive force between the inner magnet 441 and the outer magnet 462, and the valve body 28. Moves below the granular material discharge port 35 and the granular material discharge port 35 opens.

  When the plunger 451 is moved downward by the excitation of the solenoid 450 and the rotation support plate 452 is moved downward, the outer magnet gear 472 is moved vertically downward with respect to the rotation output shaft 471, and the inner magnet gear 440 is moved to the outer magnet. It is pulled by the gear 472 and moves vertically downward with respect to the power transmission shaft 420.

  When the motor 470 is turned on in this state, the outer magnet gear 472 rotates in a predetermined direction as shown in FIG. 16, the inner magnet gear 440 rotates in the direction opposite to the outer magnet gear 472, and the power transmission shaft 420 is rotated. It rotates integrally with the inner magnet gear 440. The granular material rotation guide 421, the upright plate 422, the scraper 26, and the screw part 423 that are provided so as not to rotate with respect to the power transmission shaft 420 are inside the granular material storage cylinder 410 (the granular material storage region R1). Rotate.

  The granular material guided to the discharge path 13 </ b> A by the granular material rotation guide 421 is sent downward by the screw portion 423 and discharged from the granular material discharge port 35.

  When the supply of the powder is finished, first, the motor 470 is stopped, and then the direction of the current passed through the outer magnet 462 is reversed so that the inner magnet 441 is attracted. Then, excitation of both solenoids 450 and 460 is stopped. Then, in a state where the inner magnet 441 and the outer magnet 462 are attracted to each other, the plunger 461 moves vertically upward, so that the power transmission shaft 420 is lifted vertically upward inside the vertical cylinder portion 411 and the inner magnet 441 is moved. It stops at a position where it abuts on the upper end wall of the vertical cylinder portion 411. Then, the conical slope 28 </ b> A of the valve body 28 comes into contact with the annular edge portion 35 </ b> E of the granular material discharge port 35 and the granular material discharge port 35 is closed. Here, when excitation of the solenoid 450 stops, the outer magnet gear 472 moves vertically upward by the plunger 451 and the rotation support plate 452, and the inner magnet gear 440 magnetically coupled to the outer magnet gear 472 also moves vertically upward. At this time, the inner magnet gear 440 may push up the fixed platen 442. That is, the two tension springs may cooperate to move the power transmission shaft 420 vertically upward.

  When the power transmission shaft 420 reaches the upper end position, the power transmission shaft 420 is moved to the upper end position by the attractive force between the inner magnet 441 and the holding magnet 443 and the attractive force between the inner magnet gear 440 and the outer magnet gear 472. Can be held in. Therefore, energization to the outer magnet 462 can be stopped. The configuration of this embodiment also has the same effect as the first embodiment. In addition, the partition 430 divides the granular material accommodation area R1 and the magnet accommodation area R2 so that the granular material does not enter the magnet accommodation area R2. Therefore, the rotation of the inner magnet gear 440 due to the biting of the granular material. It is possible to prevent the occurrence of defects and linear motion defects.

[Other Embodiments]
The present invention is not limited to the above-described embodiment. For example, the embodiments described below are also included in the technical scope of the present invention, and various other than the following can be made without departing from the scope of the invention. It can be changed and implemented.

  (1) In the first to third embodiments, the supply drum 11 is arranged inside the sealed work case 100. However, even if the whole of the granular material supply apparatus 10 is arranged in an open state. Good.

  (2) In the third embodiment, the decrease in the weight of the entire supply drum 11 is measured (loss-in-weight method) as the weight of the powder discharged from the supply drum 11. You may make it measure the weight of the received granular material directly. At this time, the measuring instrument may be arranged inside the work case 100 or arranged outside the work case 100 so as to receive the load of the entire receiver 130 including the granular material in a non-contact state. May be.

  (3) In the fourth embodiment, the screw portion 423 on the inner side of the discharge passage 13A is configured by the helical coil wound around the outer side of the power transmission shaft 420. However, as in the first embodiment, power transmission is performed. You may comprise by the spiral protrusion (refer FIG. 4 (A)) protruded from the outer peripheral surface of the shaft 420, or the spiral groove (refer FIG. 4 (B)) which the outer peripheral surface of the power transmission shaft 420 was depressed.

  (4) In the first to fourth embodiments, instead of the screw portions 27 and 423, the valve body 28 stands vertically upward from the conical slope 28A, extends along the inner peripheral surface of the discharge passage 13A, and discharges. You may provide the vertical pole 480 (equivalent to the "valve fixed rotary body" of this invention) which turns in the inner surface vicinity of the path | route 13A (refer FIG. 18 (A)). By rotating the vertical pole 480 in the discharge passage 13A, the powder particles in the discharge passage 13A can be flowed, and clogging due to arch formation and aggregation of the powder particles can be prevented. Moreover, the granular material adhering to the inner surface of the discharge path 13A can be scraped off.

  (5) In the fourth embodiment, the discharge passage 13A extending vertically downward from the bottom wall inner surface 411B of the vertical tube portion 411 is provided. However, as shown in FIG. 18B, the lower end of the vertical tube portion 411 is provided. The inner surface 411D may be a conical surface having a diameter reduced to a mortar shape as it approaches the powder particle discharge port 35, and the granular material may move toward the particle discharge port 35 by its own weight due to the inclination of the lower surface 411D. . At this time, a shaft-fixed rotating body 481 that extends along the generatrix of the lower end inner surface 411D and turns around the lower end inner surface 411D may be provided integrally with the power transmission shaft 420. By rotating the fixed shaft rotating body 481, the powder particles can be flowed, and clogging due to arch formation and aggregation of the powder particles can be prevented. Moreover, the granular material adhering to lower end part inner surface 411D can be scraped off.

  (6) In the fourth embodiment, the torque of the motor 470 is transmitted to the power transmission shaft 420 by the magnetic coupling between the inner magnet gear 440 and the outer magnet gear 472, but the power transmission shaft 420, the rotation output shaft 471, The spur gears fixed to each other may be engaged with each other. In addition, the rotation output shaft 471 of the motor 470 is arranged so as to be orthogonal to the power transmission shaft 420, and the power transmission shaft 420 and the rotation output shaft 471 are connected by a worm and a worm wheel or a pair of bevel gears. Also good. In these cases, a part of the cylindrical wall above the partition wall 430 in the vertical cylinder part 411 may be partially cut to form a gear connection opening, and the gears may be engaged with each other at the gear connection opening.

  (7) As shown in FIG. 19, a plurality of the granular material supply devices 400 according to the fourth embodiment are mounted side by side in a turning direction on a turning base 502 that turns around a vertical turning shaft 501, and a weighing machine 503 (electronic balance). It is good also as the granular material supply and measurement system 500 which supplies a granular material with respect to the receiver 130 mounted in the measuring device 503 from the granular material supply apparatus 400 positioned above (1).

  (8) In the first embodiment, torque and axial force are transmitted in a non-contact state between the rotary output shaft 52 and the power transmission shaft 20, but torque and axial force are transmitted in a contact state. May be. Specifically, for example, the entire motor 50 including the rotation output shaft 52 can be linearly moved so as to be in contact with and separated from the upper end portion of the power transmission shaft 20, and the power transmission shaft 20 is always urged upward to generate powder. The linear motion urging means for maintaining the granule discharge port 35 closed by the valve body 28, the lower end portion of the rotation output shaft 52, and the upper end portion of the power transmission shaft 20 are fixed and meshed with each other. And a pair of clutch plates capable of transmitting torque.

  When supplying powder particles, the entire motor 50 including the rotary output shaft 52 is moved vertically downward to engage the clutch plates, and from here the whole motor 50 is further moved vertically downward, The power transmission shaft 20 is moved vertically downward against the urging force of the direct acting urging means, and the granular material discharge port 35 is opened. When the motor 50 is turned on in this open state, torque is transmitted from the rotation output shaft 52 to the power transmission shaft 20 via the clutch plate, and the powdered particles are discharged. Further, when the supply of the powder particles is finished, the entire motor 50 is moved vertically upward. Then, when the power transmission shaft 20 moves vertically upward by the urging force of the direct acting urging means and the motor 50 rises to a position where the clutch plates are separated from each other, the granule discharge port 35 is closed by the valve body 28 and the powder is discharged. Leakage of particles is prevented.

  (9) In the fourth embodiment, when the granular material supply device 400 is used in a special environment (for example, vacuum, high temperature, corrosive gas atmosphere, etc.) different from the atmosphere, it is shown in FIG. As described above, the solenoid 460 for applying axial force to the power transmission shaft 420 is accommodated in the closed space of the first housing 491 so as to be isolated from the special environment, and for applying torque to the power transmission shaft 420. Solenoid 450 as a direct drive source of motor 470 and outer magnet gear 472 may be housed in a second housing 492 separate from first housing 491 and isolated from the special environment. In addition, pipes 490 and 490 are connected to the respective housings 491 and 492, and cooling gas is sucked into and exhausted into the housings 491 and 492 via the pipes 490 so as to suppress the temperature rise of the solenoids 450 and 460 and the motor 470. May be. Further, the cable CA connected to the solenoids 450 and 460 and the motor 470 may be passed through the pipes 490 and 490 so as not to be exposed to a special environment.

10 Powder and Particle Supply Device 11 Supply Drum (Powder and Particle Container)
13A Discharge path 20 Power transmission shaft 20A Connection shaft part 21 Granule rotation guide (rotary body in container, shaft movable rotary body)
25A Non-circular through hole 26 Scraper 27 Screw part 27A Spiral ridge 27B Spiral groove 27C Spiral coil 28 Valve element 28A Conical slope 31 Upper surface standby guide (linear motion regulating member)
35 Granule outlet 35E Annular edge (valve seat)
50 Motor (Rotary drive source)
52 Rotation output shaft (Rotation output part)
73 Outer magnet for coupling 74 Inner magnet for coupling 80 Solenoid (direct drive source)
81 Plunger (attractable magnetic material)
DESCRIPTION OF SYMBOLS 100 Work case 110 Ceiling wall 400 Granule supply apparatus 410 Powder storage cylinder (powder container)
420 Power Transmission Shaft 420A Connecting Shaft 421 Powder and Particle Rotation Guide (Rotary Body in Container, Shaft Movable Rotating Body)
423 Screw part 440 Inner magnet gear 441 Inner magnet 460 Solenoid (direct drive source)
461 Plunger (attracted magnetic material)
462 Outer magnet 470 Motor (rotation drive source)
471 Rotation output shaft (Rotation output part)
472 Outer magnet gear 480 Vertical pole (valve fixed rotating body)
481 Shaft-fixed rotating body (rotating body in container)
MC1 Integral linear motion type magnet coupling MC2 Torque transmission magnet coupling MC3 Axial force transmission magnet coupling

Claims (9)

A powder container containing powder, and
A circular powder outlet that vertically penetrates the center of the bottom wall of the powder container;
A valve body having a conical shape whose diameter can be opened and closed by opening and closing the powder body discharge port with respect to the opening edge of the powder body discharge port from below,
A rotating body in a container for rotating in the granular material container with the granular material outlet opened, and discharging the granular material from the granular material outlet,
It is arranged on the central axis of the granular material discharge port and extends in the vertical direction, and the rotating body in the container is fixed to the middle part of the vertical direction so as to be integrally rotatable, and the valve body can be linearly moved integrally at the lower end. A power transmission shaft fixed to the
A linear drive source for applying an axial force to the power transmission shaft and opening and closing the particulate discharge port in the valve body;
A rotational drive source for applying torque to the power transmission shaft in a state in which the granular material discharge port is open, and rotationally driving the rotating body in the container ;
A valve seat provided at an opening edge of the granular material discharge port, abutting against a conical slope of the valve body;
Standing up from the conical slope of the valve body, it is arranged in a discharge path extending in the vertical direction from the upper surface of the bottom wall of the powder container to the powder discharge port, and is adjacent to the inner surface of the discharge path A granular material supply device comprising: a valve body fixed rotating body capable of turning in a state. A powder container containing powder, and
A circular powder outlet that vertically penetrates the center of the bottom wall of the powder container;
A valve body capable of opening and closing the powder body discharge port by contacting and separating from below the opening edge of the powder body discharge port;
A rotating body in a container for rotating in the granular material container with the granular material outlet opened, and discharging the granular material from the granular material outlet,
It is arranged on the central axis of the granular material discharge port and extends in the vertical direction, and the rotating body in the container is fixed to the middle part of the vertical direction so as to be integrally rotatable, and the valve body can be directly moved to the lower end part A power transmission shaft fixed to the
A linear drive source for applying an axial force to the power transmission shaft and opening and closing the particulate discharge port in the valve body;
A rotational drive source for applying torque to the power transmission shaft in a state in which the granular material discharge port is open, and rotationally driving the rotating body in the container;
Spiral ridges or spiral grooves or spirals provided integrally in the power transmission shaft, arranged in a discharge path extending vertically from the upper surface of the bottom wall of the powder container to the powder discharge port A screw part made of a coil,
A granular material supply characterized in that a granular material rotation guide that collects the granular material on the bottom wall of the granular material container and guides it into the discharge path is provided as the rotating body in the container. apparatus. A powder container containing powder, and
A circular powder outlet that vertically penetrates the center of the bottom wall of the powder container;
A valve body capable of opening and closing the powder body discharge port by contacting and separating from below the opening edge of the powder body discharge port;
A rotating body in a container for rotating in the granular material container with the granular material outlet opened, and discharging the granular material from the granular material outlet,
It is arranged on the central axis of the granular material discharge port and extends in the vertical direction, and the rotating body in the container is fixed to the middle part of the vertical direction so as to be integrally rotatable, and the valve body can be directly moved to the lower end part A power transmission shaft fixed to the
A linear drive source for applying an axial force to the power transmission shaft and opening and closing the particulate discharge port in the valve body;
A rotation drive source for applying a torque to the power transmission shaft in a state in which the granular material discharge port is open, and rotating the in-container rotating body;
A rotation connecting shaft portion having a non-circular cross section is provided at an intermediate portion of the power transmission shaft,
A granular material characterized in that a shaft-movable rotating body having a non-circular through-hole fitted so as to be relatively linearly movable and non-rotatable is provided as the rotating body in the container. Feeding device. The shaft movable rotating body is fixed within the powder container, sandwiched between the shaft movable rotating body and the bottom wall of the powder container, allows rotation of the shaft movable rotating body, and is located above and below the shaft movable rotating body. The granular material supply apparatus according to claim 3, wherein a linear motion regulating member for regulating movement is provided. Projecting downward from the shaft movable rotor toward the inside of a discharge path extending in the vertical direction from the upper surface of the bottom wall of the powder container to the powder discharge port, and from the inner surface of the discharge path The powder and granular material supply device according to claim 3, further comprising a scraper that scrapes off the body. A powder container containing powder, and
A circular powder outlet that vertically penetrates the center of the bottom wall of the powder container;
A valve body capable of opening and closing the powder body discharge port by contacting and separating from below the opening edge of the powder body discharge port;
A rotating body in a container for rotating in the granular material container with the granular material outlet opened, and discharging the granular material from the granular material outlet,
It is arranged on the central axis of the granular material discharge port and extends in the vertical direction, and the rotating body in the container is fixed to the middle part of the vertical direction so as to be integrally rotatable, and the valve body can be directly moved to the lower end part A power transmission shaft fixed to the
A linear drive source for applying an axial force to the power transmission shaft and opening and closing the particulate discharge port in the valve body;
A rotation drive source for applying a torque to the power transmission shaft in a state in which the granular material discharge port is open, and rotating the in-container rotating body;
Provide a work case with a closed space isolated from the outside,
The powder container is accommodated in a closed space of the work case and suspended from the ceiling wall of the work case, and the rotary drive source and the linear drive source are arranged outside the work case,
A torque transmission magnet coupling for magnetically coupling the rotation output portion of the rotational drive source and the power transmission shaft via the wall of the work case so as to be capable of rotating integrally or interlockingly;
An axial force transmission magnet coupling that magnetically couples the linear motion output portion of the linear motion drive source and the power transmission shaft through the wall portion of the work case so as to be capable of integral linear motion. Powder body supply device. The inner surface of the granular material container has a conical inner surface whose diameter is increased upward from the granular material discharge port, and extends along a generatrix of the inner surface of the conical surface and is rotatable in a state adjacent to the conical inner surface. The granular material supply apparatus according to claim 6, wherein a fixed shaft rotating body is provided as the rotating body in the container. An inner magnet for coupling, which is disposed inside the work case and fixed so as to rotate integrally with the power transmission shaft and move linearly integrally with the power transmission shaft;
A coupling outer disposed outside the work case and magnetically coupled to the coupling inner magnet via the wall of the work case so as to rotate integrally with the coupling inner magnet and to move integrally with the coupling inner magnet. An integral linear motion rotation type magnet coupling composed of a magnet is provided as the torque transmission magnet coupling and the axial force transmission magnet coupling,
The coupling outer magnet and the rotation output portion of the rotation drive source are coupled by a spline mechanism that allows mutual linear motion and transmits rotation,
A magnetic attractant fixed to the coupling outer magnet is provided,
A direct acting urging means for constantly urging the power transmission shaft upward to maintain the powder particle outlet in a closed state; and The powder granule according to claim 6 or 7, comprising a solenoid capable of magnetically attracting downward against an urging force and capable of opening the powder particle discharge port as the linear drive source. Body supply device. The valve body has a conical shape whose diameter is reduced upward,
The granular material supply apparatus according to any one of claims 2 to 8, wherein a valve seat that abuts on a conical slope of the valve body is provided at an opening edge of the granular material discharge port. .

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