JP5665080B2 - Powder filling device - Google Patents

Description

  The present invention relates to a granular material filling apparatus for filling a granular material into a container or the like.

Conventionally, as a granular material filling device for filling granular material, for example, there are devices described in Patent Documents 1 and 2 previously filed by the present applicant.
In the powder filling apparatus of Patent Document 1, a scattering disk is attached to the lower end portion of an auger screw shaft in an auger cylinder. The powder is conveyed downward by the rotation of the auger screw shaft, temporarily received by the scattering disk, and scattered from the open portion to the surroundings by the rotation of the auger screw shaft. This device is a device that supplies a predetermined amount of powder particles by rotation of the auger screw shaft, and the scattering disk prevents the powder particles from dropping from the lower end of the auger screw shaft.

  The granular material filling apparatus of Patent Document 2 has a configuration in which the auger screw shaft is abolished and a rod-shaped rotating shaft is disposed instead, and a scattering disk is provided at the lower end of the rotating shaft. According to this configuration, since the granular material is dropped without using the auger screw, it is possible to prevent the granular material from being crushed without applying a large pressure to the granular material.

JP 2007-91242 A JP 2009-126567 A

As in the prior art described above, in a powder filling device having a mechanism in which powder particles are scattered and dropped by rotation of the scattering disk and inserted into a container disposed below, rotation of the scattering disk is performed. When the operation is stopped, there is a possibility that a part of the granular material accumulated on the upper surface of the scattering disk spills from the outer peripheral edge, which is a so-called “backward” phenomenon. In the case where dripping occurs in the granular material, the weight of the granular material filled in the container slightly fluctuates, which causes a decrease in accuracy of quantitative filling.
In addition, in the granular material filling device of Patent Document 2, a configuration is also disclosed in which the scattering disk is moved in the axial direction so as to close the discharge port of the filling cylinder, thereby preventing the back of the granular bag. However, the structure for moving the scattering disk is complicated and the control is complicated.

  This invention is made | formed in view of such a situation, and it aims at preventing the penetration | invasion of the granular material which slipped into the container and packaging bag later with a simple structure.

In order to achieve the above object, the granular material filling device of the present invention includes a filling cylinder for discharging the granular material from the discharge port,
A disc-shaped scattering disk that is rotatably disposed below the discharge port of the filling cylinder, receives the powder particles discharged from the discharge port on the upper surface, and scatters to the surroundings by centrifugal force accompanying rotation,
And a granular material receiving portion protruding outward at a position lower than the outer peripheral edge of the scattering disk.

  According to the device of the present invention having the above-described configuration, even if the granular material comes behind from the outer peripheral edge of the scattering disk, the granular material can be received by the granular material receiving portion provided at a position lower than the outer peripheral edge. Since it can do, there is no possibility that the granular material which slipped into the container and packaging bag which are further arranged in the lower position will enter.

Moreover, this invention apparatus can also be set as the structure which provided the storage part which accommodates the granular material which has continued to the granular material receiving part and fell to the said granular material receiving part in the downward position of a scattering disk.
If configured in this way, even if there is a large amount of powder particles spilling from the outer periphery of the scattering disk, it can be received by the powder particle receiving part and further stored in the storage part. It is possible to more reliably prevent the particles from entering the container or the packaging bag.

The apparatus of the present invention described above is provided with a disk-shaped auxiliary disk at an arbitrary interval below the scattering disk, for example, and the outer peripheral edge of the auxiliary disk protrudes outside the outer peripheral edge of the scattering disk. It can be set as the body receiving part, and it can be set as the structure which formed the storage part with the space | gap formed between the upper surface of an auxiliary | assistant disk, and the lower surface of a scattering disk inside the said granular material receiving part.
If comprised in this way, it will be possible to prevent the powder particles that have fallen into the container or the packaging bag with a simple structure in which a disk-shaped auxiliary disk is provided below the scattering disk.

Furthermore, the device of the present invention can also be configured to include a conical cylindrical scattering receiving umbrella arranged so as to surround the periphery from the discharge port of the filling cylinder to the scattering disk.
By providing such a scattering receiving umbrella, the powder particles discharged from the discharge port of the filling cylinder and scattered to the surroundings by the centrifugal force accompanying the rotation of the scattering disk are quickly received by the inner peripheral surface of the scattering receiving umbrella. It can be dropped downward. Therefore, the granular material can be quickly and surely inserted into a container or a packaging bag arranged at a lower position.

  As described above, according to the granular material filling device of the present invention, it is possible to prevent the granular material that has fallen into the container or the packaging bag from entering with a simple structure.

It is front sectional drawing which shows schematic structure of the granular material filling apparatus which concerns on embodiment of this invention. It is front sectional drawing which expands and shows the structure of the scattering disk of this apparatus, and an auxiliary disk. It is front sectional drawing which shows the modification of the scattering disk of the same apparatus.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
Drawing is a figure which shows the granular material filling apparatus which concerns on embodiment of this invention, and FIG. 1 is front sectional drawing which shows schematic structure of a granular material filling apparatus.
As shown in the figure, the granular material filling device of this embodiment includes a granular material supply funnel 1, a filling cylinder 2, a rotating shaft 3, a scattering disk 4, an auxiliary disk 5, and a scattering receiver. 6 and a hopper 7.

The granular material supply funnel 1 is formed in an inverted conical shape, and is provided with a supply port 1a for supplying the granular material at the top. A cylindrical filling cylinder 2 that drops the granular material downward is connected to and connected to the lower end of the granular material supplying funnel 1.
The filling cylinder 2 extends in the up-down direction, and the lower end portion serves as a discharge port 2a for the granular material.

The rotating shaft 3 is a rod-like member that is coaxially disposed in the hollow portion of the filling cylinder 2. The rotating shaft 3 extends in the hollow portion of the filling cylinder 2 in the axial direction, and a lower end projects from the discharge port 2 a of the filling cylinder 2.
The rotating shaft 3 receives a rotational driving force from the rotating motor 10 and rotates.
A scattering disk 4 and an auxiliary disk 5 are attached to the lower end of the rotating shaft 3.

FIG. 2 is an enlarged front sectional view showing the structure of the scattering disk and the auxiliary disk.
The scattering disk 4 is formed in a disk shape having a diameter larger than the inner diameter of the filling cylinder 2 and is configured to receive powder particles falling from the discharge port 2 a of the filling cylinder 2. As a result, the scattering disk 4 accumulates the powder particles discharged from the filling cylinder 2 when the rotation of the rotary motor 10 is stopped, and centrifuges the powder particles accumulated during rotation and the powder particles discharged from the filling cylinder 2. Scatter around by force. Further, the outer peripheral edge 4a of the scattering disk 4 is formed at a position higher than the periphery of the center portion, thereby suppressing the spilling of the powder and facilitating the accumulation of the powder on the upper surface of the scattering disk 4.

  The auxiliary disk 5 is arranged below the scattering disk 4 at an arbitrary interval. In this embodiment, the outer peripheral edge of the disk-shaped auxiliary disk 5 protrudes outward from the outer peripheral edge of the scattering disk to form the granular material receiving part 5a. Further, a granular material reservoir 5b is formed by a gap formed between the upper surface of the auxiliary disk and the lower surface of the scattering disk inside the granular material receiving portion 5a. The auxiliary disk 5 is attached to the lower end portion of the rotating shaft 3 together with the scattering disk 4.

  The granular material receiving part 5a has a function of receiving the granular material that spills from the outer peripheral edge of the scattering disk at a position below the outer peripheral edge. By providing this granular material receiving part 5a, it is possible to prevent the granular material that has come back from the scattering disk 4 from entering the container W that is further disposed at the lower position.

  The granular material storage unit 5b is connected to the granular material receiving unit 5a, and has a function of accommodating the granular material that has fallen into the granular material receiving unit 5a. By forming this storage part 5b, even if the amount of powder particles spilling from the outer periphery of the scattering disk 4 is large, it can be received by the powder particle receiving part 5a and further stored in the storage part 5b. Therefore, it is possible to more reliably prevent the powder particles that have fallen into the container W from entering later.

  The scattering umbrella 6 is a conical cylinder-shaped member, and has an upper end fixed to the outer peripheral surface of the filling cylinder 2 and is disposed so as to surround the periphery from the discharge port 2 a of the filling cylinder 2 to the scattering disk 4. By disposing the scattering receiver umbrella 6, the powder particles discharged from the discharge port 2 a of the filling cylinder 2 and scattered around by the centrifugal force associated with the rotation of the scattering disk 4 are used as the inner peripheral surface of the scattering receiver umbrella 6. Can be quickly dropped downward.

  The hopper 7 is formed in an inverted conical shape, and is disposed so as to surround the periphery of the scattering disk 4 disposed on the hollow portion. Thereby, the hopper 7 can receive the granular material scattered from the scattering disk 4 on the inner peripheral surface. Further, the hopper 7 is provided with a pouring cylinder 8 that discharges powder particles at the lower end, and a container W conveyed from a conveying device (not shown) is automatically arranged below the pouring cylinder 8. Is done. The container W is filled with powder and granular materials from the dispensing cylinder 8.

Here, the height position of the scattering disk 4 with respect to the discharge port 2a of the filling cylinder 2 suppresses spillage according to the angle of repose of the granular material deposited when the rotary motor 10 is stopped, the area and shape of the scattering disk 4, etc. It is preferable to adjust so that it can. Generally, a granular material has a repose angle formed by a critical ridgeline where collapse starts with respect to the bottom surface in a state where the granular material is naturally dropped and accumulated in a mountain shape. For powder particles with a small angle of repose, the gap between the discharge port 2a of the filling cylinder 2 and the scattering disk 4 is adjusted to be narrow, thereby preventing the particles from falling off when the rotation of the scattering disk 3 is stopped. can do. On the other hand, for a granular material having a large angle of repose, the gap between the discharge port 2a of the filling cylinder 2 and the scattering disk 4 is adjusted to be wide so that the scattering amount of the granular material increases when the scattering disk 3 rotates. It is possible to increase the filling speed.
The granular material filling apparatus having such a configuration can quantitatively fill the granular material into the container W by controlling the rotary motor 10 to rotate the scattering disk 4 intermittently.

Next, operation | movement of the granular material filling apparatus of this embodiment is demonstrated.
When the powder is supplied into the powder supply funnel 1 from the supply port 1a, the powder is temporarily stored in the powder supply funnel 1, and further moves according to the inclination of the funnel. Flows into 2. As shown in FIG. 2, the granular material falls as it is in the filling cylinder 2, and is discharged to the scattering disk 4 from the discharge port 2a. Here, when rotation of the scattering disk 4 is stopped, the granular material dropped from the discharge port 2a accumulates on the upper surface of the scattering disk 4, and the discharge port 2a is closed.

  Next, when the rotary motor 10 is driven, the scattering disk 4 also rotates through the rotary shaft 3. Therefore, the granular material deposited on the upper surface of the scattering disk 4 when the rotation is stopped is scattered from the open portion of the outer periphery to the surroundings by the centrifugal force during the rotation. Subsequently, the particulate matter accumulated in the filling cylinder 2 is discharged onto the scattering disk 4 from the discharge port 2 a by the amount scattered from the scattering disk 4. That is, when the scattering disk 4 is rotated, the granular material is discharged from the discharge port 2 a of the filling cylinder 2, and a smooth flow is generated that is scattered from the outer peripheral edge 4 a of the scattering disk 4.

  The granular material scattered by the scattering disk 4 collides with the inner peripheral surface of the scattering umbrella 6 and falls downward due to its own weight, and fills the container W through the hopper 7 and the hollow portion of the extraction tube 8. Is done.

Even if the rotation of the rotating shaft 3, the scattering disk 4 and the auxiliary disk 5 is stopped by stopping the rotation of the rotary motor 10, the powder particles in the filling cylinder 2 fall as they are, and the upper surface of the scattering disk 4 from the discharge port 2a. It is discharged and accumulates. This continues until the discharge port 2a is blocked by the accumulated granular material.
In this state, the granular material deposited on the upper surface of the scattering disk 4 may slightly spill from the outer peripheral edge of the scattering disk 4. The granular material thus spilled is received by the granular material receiving portion 5a of the auxiliary disk 5 provided therebelow, and the falling to the container W is prevented. Even if there is a large amount of spilled granular material, it is accommodated in the storage unit 5b after being received by the granular material receiving part 5a, so there is no possibility that the granular material will fall into the container W.

In addition, this invention is not limited to embodiment mentioned above, Of course, various application implementation or deformation | transformation implementation is possible as needed.
For example, in the above-described embodiment, the scattering disk 4 and the auxiliary disk 5 are mounted on the lower end of the rod-shaped rotating shaft 3. Alternatively, the scattering disk 4 and the auxiliary disk 5 may be mounted.

  Further, in the above-described embodiment, the hopper 7 is used in the granular material filling device. However, without providing the hopper 7, the granular material that has scattered from the scattering disk 4 and collided with the scattering umbrella 6 is used as a container. It is good also as a structure dropped to W. Furthermore, it is good also as a structure which arrange | positions the container W under the scattering disk 4, and receives and fills a granular material directly with the container W, without providing either the hopper 7 and the scattering receiving umbrella 6. FIG.

  Further, as shown in FIG. 3, the granular material receiving part 5 a and the granular material storage part 5 b can be integrally formed on the scattering disk 4 without providing the auxiliary disk 5 separate from the scattering disk 4. .

  1: funnel for supplying powder, 1a: supply port, 2: filling cylinder, 2a: discharge port, 3: rotating shaft, 4: scattering disk, 4a: outer periphery, 5: auxiliary disk, 5a: receiving powder Parts, 5b: storage part, 6: scattering umbrella, 7: hopper, 8: dispensing cylinder, 10: rotary motor

Claims (4)

A filling cylinder for discharging the powder particles from the outlet;
A disc-like scattering disk that is rotatably arranged below the discharge port of the filling cylinder, receives the powder particles discharged from the discharge port on the upper surface, and scatters to the surroundings with centrifugal force accompanying rotation,
Said outwardly projecting at a lower position than the outer peripheral edge of the scattering disk, viewed contains a granular material receiving portion receiving the spilled from the outer peripheral edge of the stopped spinning the scattering disk granular material, and
The granular material receiving device is configured such that the received granular material rotates together with the scattering disk and is scattered around . In the lower position of the scattering disk, a storage unit is provided that accommodates the granular material that has been dropped into the granular material receiving unit in a row with the granular material receiving unit ,
2. The granular material filling apparatus according to claim 1, wherein the storage unit is configured to rotate the accommodated granular material together with the scattering disk to be scattered around . A disk-shaped auxiliary disk that rotates with the scattering disk at an arbitrary interval below the scattering disk is provided, and the outer peripheral edge of the auxiliary disk protrudes outward from the outer peripheral edge of the scattering disk. 3. The granule according to claim 2, wherein the storage portion is formed by a gap formed between the upper surface of the auxiliary disk and the lower surface of the scattering disk inside the granular material receiving portion. Body filling device. The powder particle according to any one of claims 1 to 3, further comprising a conical cylindrical scattering receiving umbrella disposed so as to surround a periphery from the discharge port of the filling cylinder to the scattering disk. Body filling device.

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