KR20200006328A - Apparatus for filling of granule or powder - Google Patents

Abstract

The present invention relates to an apparatus for filling granules or powder. The apparatus fills a fixed amount of a granule or a powder product in a container and comprises: a first hopper having a wide upper portion and a narrow lower portion and forming an inlet and an outlet on an upper and a lower side thereof; a first drum of a horizontal cylindrical shape having a first transport pipe coupled to the outlet of the first hopper and arranged on an upper side thereof and a second transport pipe arranged on a lower side thereof, and allowing a second driving means to be mounted thereon; a measurement drum which is axially coupled to the second driving means and comes in contact with the inner circumferential surface of the first drum to rotate; a second drum of a horizontal cylindrical shape which is mounted on one side of the first drum and accommodates a measurement module mounted and linked to the measurement module; a second hopper which has a wide upper portion and a narrow lower portion and is arranged on a lower side of the second transport pipe; and a discharge guide which is mounted on a base frame and sets the position of the container on a lower side of the second hopper. The apparatus economically and efficiently performs filling work in comparison to a conventional technique.

Description

Granule or Powder Filling Equipment {APPARATUS FOR FILLING OF GRANULE OR POWDER}

The present invention relates to a granule or powder filling apparatus, and more particularly, it is possible to more efficiently and efficiently fill a filling operation compared to the prior art by configuring an apparatus for easily filling a container with granules or powdery products by a volume set by a user. It relates to a technique to perform.

In general, granules or powdery products such as grains, nuts, and red pepper powder are taken out from storage tanks in a packing process and packed into containers, and grain weighing and filling machines are used as a device for performing such operations.

The general configuration of grain weighing and filling machine is as follows through a known technique.

For example, Korean Utility Model Utility Model No. 20-2000-0007184 includes a main body frame having four pillars extending vertically, an auxiliary tank fixed temporarily on the main body frame and temporarily storing dried grains, and an auxiliary tank. An input hopper integrally formed with the auxiliary tank at the bottom of the auxiliary tank, a weighing tank for receiving grain from the auxiliary tank, an electronic scale for measuring the weight of the grain supplied into the weighing tank with a load cell, and a guide rail and a lift. And a lifting device for carrying out the weighed grain to the outside, and a grain automatic weighing device including a control device installed at one side of the main frame and controlling the overall operation of the automatic weighing device.

As another example, Korean Utility Model Registration No. 20-0339623 installs a storage tank in which different grains are contained in a main body, and configures a grain automatic packaging vending machine that takes out and sells the grains in the storage tank according to a consumer's operation.

Specifically, the discharge screw for discharging grains in the storage tank as installed and rotated on the discharge port of each storage tank, the motor is installed on the outside of each storage tank axially fixed to the discharge screw, discharge outlet directly below the discharge screw A discharge cell installed to collect the side at once, a weighing container installed directly below the discharge pipe, and a load cell for controlling the driving of the motor by weighing the weight of the grain contained in the weighing container installed on one side of the weighing container. And, the grain is automatically packaged as the grain in the weighing container falls freely through the shutter installed at the lower side of the weighing container to open and close the lower part of the weighing container according to the driving means, and the hopper installed at the lower part of the weighing container. Consists of packaging means for discharging to the outlet side.

Korean Utility Model Model No. 20-2000-0007184 (2000.04.25) Korea Utility Model Registration No. 20-0339623 (2004.01.24) Korea Patent Registration No. 10-0378300 (2002.03.27) Korean Patent Publication No. 10-2017-0128895 (2017.11.24)

Grain weighing and charger, which is applied to the prior art as described above, takes out the grain from the storage tank, supplies it to the weighing tank, automates a series of configurations for weighing with a set capacity in the weighing tank, and then transporting it to a discharge device and packing it in a container. It is made in the form of

In other words, the prior art is equipped with a series of components in conjunction with the discharge device, the discharge screw, etc. using an electronic balance equipped with a load cell to automate the overall weighing and filling operation of grain.

In the above-described conventional automatic grain discharging device, the strain measuring device detects the amount of deformation generated when a load is applied to the load cell as an electric signal, converts it into a digital signal using a control device, and operates the lifting device and the discharge device in conjunction with each other. Implement automation through a series of configurations that control this.

Another automatic grain vending machine of the prior art is also provided with a load cell on one side of the weighing container, the operation of the motor to control the operation of the discharge screw to discharge the grain from the storage tank to the weighing container is shifted by detecting the grain amount of the load cell Automate as much as possible.

Therefore, the conventional grain weighing and filling machine also increases the technical difficulty of the device, such as the complexity of the device structure and the enlargement of the device structure, which must be designed with digital equipment, in order to derive the interlocking configuration of each part mounted to implement automation. It is common for the equipment cost to be expensive.

Moreover, since the device of the prior art is designed to be used only for grains, for example, nuts, pepper powder, and various powder products, there is a limit to the use of a separate device.

As a result, the user is in a small economic situation such as small businesses or farmhouses, and the economic burden is very difficult to operate and maintain the device.

Therefore, the present invention is invented to solve the problems of the prior art as described above,

An apparatus for filling granules or powder products into a container in a fixed amount,

A first hopper of an upper and lower straits forming upper and lower inlets and outlets;

A horizontal cylindrical first drum having first and second transfer pipes coupled to the outlet of the first hopper and upper and lower outer circumferential surfaces thereof and mounting second driving means;

A metering drum axially coupled to the second driving means and rotating in contact with the inner circumferential surface of the first drum;

A horizontal cylindrical second drum mounted on one side of the first drum and accommodating the weighing module interlocked with the weighing drum;

A second hopper of a light-lower narrower provided below the second transfer pipe; And

Equipped with a base frame and the discharge guide for setting the container position on the lower side of the second hopper; it is possible to achieve the purpose of performing the filling operation more economically and efficiently than the prior art.

The present invention provides an apparatus for easily filling a container by quantitatively measuring various products in granules or powder according to user settings.

In particular, the present invention has the advantage of reducing the device cost and easy operation and maintenance by simplifying the overall configuration and design as compared to the prior art device.

Therefore, even in a small workplace such as a small company or a farmhouse, the filling apparatus of the present invention can be applied efficiently without any economic burden, regardless of the type of products such as grains, nuts, and red pepper powder.

In addition, the present invention is equipped with a series of configurations for excluding the problem that the smooth discharge is inhibited due to the adsorption between the powder, or between the powder and the device when applying the product in the state of high moisture content, the accumulation of exhaust due to conventional powder adsorption B, there is an advantage to solve all problems such as causing a malfunction of the device.

1 is a perspective view of a granule or powder filling apparatus according to the present invention.
2 to 3 are front and side views of the granule or powder filling apparatus according to the present invention.
4 is an exploded perspective view of a granule or powder filling apparatus according to the present invention.
5 is a view showing a quantitative drum and a quantitative module of the granule or powder filling apparatus according to the present invention.
6 to 9 is an illustration of the state of use of the granule or powder filling apparatus according to the present invention.

Hereinafter, the configuration and operation according to a preferred embodiment of the granule or powder filling apparatus of the present invention will be described in detail with reference to the accompanying drawings. In the following description, a detailed description of parts that can be easily implemented by those skilled in the art may be omitted.

1 is a perspective view of a granule or powder filling apparatus according to the present invention, FIGS. 2 to 3 are front and side views of a granule or powder filling apparatus according to the present invention, and FIG. 4 is a decomposition of the granule or powder filling apparatus according to the present invention. 5 is a view illustrating a quantitative drum and a quantitative module of a granule or powder filling apparatus according to the present invention, and FIGS. 6 to 9 illustrate examples of a state of use of the granule or powder filling apparatus according to the present invention.

The granule or powder filling device to which the technique of the present invention is applied comprises a device for easily filling granules or powder-like products in a container by a predetermined volume, thereby simplifying the structure and filling economically and efficiently as compared to the filling device according to the prior art. Note that it is about a technique that allows a task to be performed.

The granule or powder filling device of the present invention for this purpose is the first hopper 110 and the first hopper according to the filling and discharging operation sequence in the input device in the granules or powder product filling the container by a predetermined amount as shown in FIG. The drum 120 and the metering drum 130, the second drum 140 and the metering module 150, the second hopper 160, and the discharge guide 170 are included. .

The first hopper 110 is provided with an upper and lower strait that forms the inlet and outlet on the upper and lower sides. Inside the first hopper 110, when the injected granules or powder, in particular, the moisture content is high and the powder or the product having adsorption between the powder and the device is smoothly transferred to the lower outlet, no residue is generated in the first hopper 110. The first cleaner 112 and the second cleaner 113 are provided.

The first driving means 111 is mounted on the upper side of the first hopper 110 and vertically provided as a core of the first hopper 110. The first driving means 111 is mounted on the upper end of the first hopper 110 to be detachably mounted.

The first cleaner 112 is axially coupled to the first driving means 111 and provided to rotate in contact with an inner surface of the first hopper 110.

The first cleaner 112 may include a plurality of angles around the first driving unit 111 at various angles, and forms a contact portion corresponding to the lower inclination angle of the first hopper 110 to lower the input when rotating. To guide.

The second cleaner 113 is axially coupled to the first driving means 111 at the lower side of the first cleaner 112 and provided to rotate inside the first transfer pipe 121.

The first transfer pipe 121 is formed on the upper side of the first drum 120 to provide a transfer path between the first hopper 110 and the metering drum 130. Since the metering drum 130, which will be described later, rotates in the second drum 140, the input is transferred to the first transport pipe 121 until the metering groove 131 returns to the position corresponding to the first transport pipe 121. Temporarily stagnates within. Therefore, the second cleaner 113 is provided to prevent the stagnant inputs from agglomerating with each other or being adsorbed by the first transfer pipe 121.

The first drum 120 is formed in a horizontal cylindrical shape and provided with a first transport pipe 121 and a second transport pipe 122 coupled to the outlet of the first hopper 110 on the upper and lower outer circumferential surfaces.

As shown in FIG. 4, the first drum 120 forms an inner space for accommodating the metering drum 130 and vertically passes through the first transport pipe 121 and the second transport pipe 122.

One side of the first drum 120 is opened to communicate with the second drum 140, and the other side is equipped with a second driving means 123 to couple the metering drum 130 to operate.

The first transport pipe 121 and the second transport pipe 122 are selectively communicated with the metering groove 131 according to the rotational position of the metering drum 130 to receive the input into the metering groove 131 to receive a second A passage for discharging to the hopper 160 is formed.

Therefore, the air gap is maintained between the inner circumferential surface of the first drum 120 and the outer circumferential surface of the metering drum 130 by minimizing the gap between the first transport pipe 121 and the second transport pipe 122 and the metering groove 131. For the purpose of providing an airtight means 133, a predetermined friction reducing means may be further installed.

The second driving means 123 is mounted on the outside of one side of the first drum 120 and the driving shaft is introduced into the first drum 120 to be coupled to the metering drum 130. The rotational speed of the second driving means 123 can be variably applied according to the filling amount set by the metering groove 131 and the metering block 154 which will be described later, and by a control module (unsigned) provided at one side. Configure to be controlled automatically or manually in conjunction with each other.

The metering drum 130 is axially coupled to the second driving means 123 and provided to rotate in contact with the inner circumferential surface of the first drum 120.

As shown in Figures 4 to 5, the metering drum 130 is provided to be integrally rotated by mounting the metering module 150.

The metering drum 130 forms a cylindrical shape in which the upper metering groove 131, the one side of the metering block access tunnel 132, and the gap 134 are closed.

The metering groove 131 forms an inlet corresponding to the outlet of the first transport pipe 121 or the inlet of the second transport pipe 122 when the metering drum 130 rotates on one side on the outer circumferential surface of the metering drum 130. To a certain depth.

In the embodiment of the present invention is configured to facilitate the entry and exit of the metering block 154 while optimizing the discharge of the input by forming a cross-section of the metering groove 131 in a hemispherical shape, other shapes may be applied as necessary. will be.

The metering groove 131 is provided to adjust the internal volume by entering and exiting the metering block 154 to be described later to set the capacity of the input, the first conveying pipe 121 and the second conveying pipe ( Compared with 122), it is preferable to form the size larger.

In addition, the spacer 134 is provided between the bottom of the metering groove 131 and the core of the metering drum 130. This is to receive the vibration generated when the metering groove 131 by the third cleaner 126, which will be described later in the gap portion 134 so that effective cleaning is performed.

The metering block access tunnel 132 is formed through a horizontal through-hole so as to communicate with the second drum 140 from the inside of the metering groove 131. The metering block access tunnel 132 forms a passage through which the metering block 154 of the metering module 150 enters and exits the metering groove 131, thereby forming the same cross section as the metering groove 131.

On the outer circumferential surface of the metering drum 130 except for the metering groove 131, the airtight means 133 is mounted as described above to contact the inner circumferential surface of the first drum 120.

The second drum 140 is formed in a horizontal cylindrical shape and mounted on one side of the first drum 120, and mounted to the metering drum 130 to accommodate the metering module 150 interlocked.

The second drum 140 is configured to open and close one side so that the operation of the weighing module 150 is made, and at the lower side, a predetermined discharge pipe (unsigned) is provided to enter and exit the weighing block 154. It is configured to discharge the input residue which is inevitably introduced from

The metering module 150 accommodated in the second drum 140 rotates integrally with the metering drum 130 which rotates in the first drum 120 to adjust the internal volume of the metering groove 131. It is provided to set the charging capacity.

The weighing module 150 has a weighing frame 152 fixed at both ends on one side of the weighing drum 130 and spaced apart from the set surface 151 by a predetermined distance.

The separation distance between the setting surface 151 and the metering drum 130 of the metering frame 152 is formed in consideration of the length from which the metering block 154 is completely drawn out from the metering groove 131.

The weighing frame 152 is provided with a weighing frame 153 which is axially coupled to the setting surface 151 and reciprocated toward the weighing drum 130.

The weighing frame 153 is provided with a predetermined handle to enter or withdraw the weighing block 154 from the setting surface 151 of the weighing frame 152 according to the operation direction.

The metering block 154 is coupled to the metering frame 153 and is provided to adjust the volume by entering and exiting the metering groove 131 through the metering block access tunnel 132 of the metering drum 130.

The metering block 154 has the same cross section as the metering groove 131 and has a length that can be coupled to the metering frame 153 through the metering groove 131 and the metering block access tunnel 132.

One side of the weighing block 154 is provided with a predetermined metering indicator 155 to check the volume of the weighing groove 131 according to the advance and exit of the weighing block 154 by the weighing frame 153. do.

The second hopper 160 is provided as a light beam lower side provided on the lower side of the second transfer pipe 122 of the first hopper (110).

The second hopper 160 is provided so that the metering drum 130 is rotated so that the metering groove 131 is discharged when positioned so as to correspond to the second transfer pipe 122.

In particular, in the present invention, the third input to solve the coagulation and adsorption problems between the powder or between the powder apparatus that may occur when the inputs to the metering groove 131 is put into the second hopper 160 at a time in a state of temporary stagnation The cleaner 126 and the fourth cleaner 163 are provided.

The third cleaner 126 is provided on the second transfer pipe 122 side of the first drum 120 to act on the inner side of the metering groove 131 to clean the input.

As shown in FIG. 7 or 9, one side of the second transfer pipe 122 is provided with a first elastic member 124 for fixing one end.

The other end of the first elastic member 124 is coupled to the hinge member 125 and axially coupled to one side wall of the second transfer pipe 122 to be provided inward.

The third cleaner 126 is coupled to be perpendicular to the axial direction of the hinge member 125, and is provided to contact the outer circumferential surface or to elastically hit the inner surface of the metering groove 131 when the metering drum 130 rotates. do.

That is, the third cleaner 126 and the hinge member 125 are provided to be elastically operated in opposite directions by the second elastic member 162. Therefore, in the operating state in which the metering groove 131 does not correspond to the second transport pipe 122, the third cleaner 126 rubs against the outer circumferential surface of the metering drum 130, and the metering groove in the second transport pipe 122. In the corresponding operating state, the 131 may be configured to elastically operate in the direction in which the third cleaner 126 strikes the inner surface of the metering groove 131 together with the contraction of the second elastic member 162.

The fourth cleaner 163 is provided on the upper side of the second hopper 160 to operate throughout the second hopper 160 to clean the inputs as follows.

As shown in FIG. 3 or 4, the upper and lower ends of the second hopper 160 and the upper and lower ends of the second hopper 160 are coupled to and spaced apart from each other. Stretch connection means 161 of the '수단' or '⊂' shape is provided.

The expansion connecting means 161 is made of a material such as silicon, for example, so that the coupling between the second transfer pipe 122 and the second hopper 160 is made elastically, by the fourth cleaner 163 When vibration occurs, it is provided to absorb and control the vibration in the horizontal direction.

In addition, a second elastic member 162 for fixing both ends between the lower end of the second transfer pipe 122 and the upper flange of the second hopper 160 is provided when the vibration occurs by the fourth cleaner 163 below. While absorbing and controlling the vibration in the up and down directions, the elastic force by the stretchable connecting means 161 is mechanically compensated. The second elastic member 162 may be mounted one or more as necessary.

The fourth cleaner 163 is mounted on one side of the second hopper 160 and is provided to generate vibration in cooperation with the third driving means 164. The fourth cleaner 163 is provided with a built-in eccentric rotating body to generate vibration by using the rotational force generated by the third driving means 164, and may be configured by applying the technique of a well-known vibration generator.

The third driving means 164 for applying the operation of the fourth cleaner 163 and the fourth cleaner 163 may include the first to second driving means 111 and 123 and the first to third cleaners 112, 113, and 126. Similarly, a predetermined control module (unsigned) provided on one side is configured to automatically or manually control the operation time, intensity, interval, and the like.

The discharge guide 170 is mounted on the base frame 171 and provided to set the container position at the lower side of the second hopper 160.

As shown in FIG. 4, the discharge guide 170 lifts up and down to adjust the front, rear, and up and down positions according to the capacity of the container while placing the container to fill the inputs directly under the second hopper 160. The unit 174 and the moving unit 177 are configured to be included.

The lifting unit 174 is perpendicular to one side of the bottom support 172 parallel to the base frame 171 and forms a first long hole 173 coupling the fastening means to the base frame 171.

The bottom support portion 172 is formed in a flat plate form the container. It is provided with an open type in which one side of the container is formed to be bent in and out of the container so that the container can be easily drawn in and out.

The elevating part 174 is formed integrally with the bottom support part 172, and the bottom support part 172 is raised and lowered to the second hopper 160 side according to the position of coupling the fastening means to the first long hole 173 provided at both sides. It is equipped to make. An opening is formed at the lower side of the elevating unit 174 to allow the front and rear of the moving unit 177 to be described later.

The second moving hole 176 couples the fastening means to the bottom support part 172 at one side of the side support part 175 upwardly provided in a '∧' shape at an upper center of the bottom support part 172. To form.

The side support 175 forms a support wall that forms a predetermined angle to receive and support the side of the container placed in the bottom support 172.

The moving part 177 is formed integrally with the support wall, but the side support part 175 is centered on the second hopper 160 according to the position of coupling the fastening means to the second long hole 176 provided on one side or both sides. Move forward and backward. The moving part 177 moves through the lower opening of the elevating part 174 described above, and a predetermined guide is formed on both sides of the moving part 177 in consideration of the case where the second long hole 176 is formed only on one side. can do.

Looking at the schematic use state of the granule or powder filling apparatus to which the technique of the present invention is configured as described above is as follows. Since the following description is given by way of example and with reference to the present invention, the present invention is not limited by the following examples and it will be obvious that various modifications can be provided without departing from the scope of the invention. .

As shown in Figure 1, the filling device of the present invention is the first hopper 110, the metering drum 130 in the up and down directions to go through a series of processes for inputting, moving, discharging, filling the granules or powders It comprises a first drum 120 to accommodate the, the second drum 140 to accommodate the weighing module 150, the second hopper 160, and the discharge guide 170.

Prior to full operation of the filling device, a capacity for filling the input is set. The user opens one side opening of the second drum 140 and operates the weighing frame 153 of the weighing module 150.

The weighing block 154 is set in the weighing groove 131 through the weighing block access tunnel 132 of the weighing drum 130 by setting the entry position of the weighing block 154 from the setting surface 151 while checking the weighing indicator 155. ).

The predetermined volume of the container to fill the input and the volume of the metering groove 131 are set to correspond.

The container is placed in contact with the side support 175 on the bottom support 172 of the discharge guide 170. According to the capacity and size of the container, the moving part 177 is moved forward and backward so that the inlet of the container is located directly below the outlet of the second hopper 160 to fix the fastening means to the second long hole 176 and then to elevate. The fastening means is fixed to the first long hole 173 by raising and lowering the part 174.

In addition, by operating the control module provided on one side, the operation of the first driving means to the third driving means (111, 123, 164), the speed and the strength, the interval and the like are set in advance.

The user inputs granules or powder to the upper side of the first hopper 110. If necessary, conveyor systems can be used to implement automation from the loading process.

By the operation of the first driving means 111, the first cleaner 112 provided inside the first hopper 110 is rotated and transferred to the first transfer pipe 121 while preventing the aggregation or adsorption of the inputs.

The inputs transferred to the first transfer pipe 121 are temporarily stagnated until the measurement drum 130 rotates to the position corresponding to the first transfer pipe 121 and the metering groove 131. When 131 is positioned in the upper 12 o'clock direction, the first cleaning pipe 121 is cleaned by the rotation of the second cleaner 113 and is dropped into the metering groove 131.

The metering drum 130 is rotated in one direction by the second driving means 123 in the first drum 120 to transfer the metering groove 131 to the first conveying pipe 121 or the second conveying pipe 122. Optionally rotate correspondingly.

As described above, after the input is dropped into the metering groove 131 at the first transport pipe 121, the metering groove 131 is rotated by 180 degrees and the metering groove 131 is positioned at the lower 6 o'clock direction as shown in FIG. 8. It is placed in a position corresponding to the second transfer pipe (122).

In addition, as shown in FIG. 7, the third cleaner 126, which has been rubbed with the outer circumferential surface of the metering drum 130, may have the first elastic member () when the metering groove 131 and the second transfer pipe 122 correspond to each other as shown in FIG. 9. 124 rotates and strikes the inner side of the metering groove 131 by contraction. Therefore, while the input is cleaned in the metering groove 131 is dropped into the second transfer pipe (122).

By the operation of the third driving means 164, the fourth cleaner 163 coupled to one side of the second hopper 160 generates vibration. Vibration is transmitted to the second hopper 160 by the elastic connecting means 161 and the second elastic member 162 coupled between the second hopper 160 and the second transfer pipe 122.

Therefore, the input dropped from the second transfer pipe 122 to the second hopper 160 is discharged to the lower outlet while preventing the agglomeration or adsorption in the second hopper 160 and filled into the container by a predetermined capacity. .

As described above, the container may be replaced according to the operating speeds and intervals of the first to third driving means 111, 123, and 164 to continuously fill the plurality of containers by a predetermined amount.

The granule or powder filling apparatus according to the present invention as described above provides a device for filling a container by simply metering a product in the form of granules or powder according to a user setting.

In particular, the present invention has the advantage that can be used without economic burden even in small-scale workplaces such as small businesses or farmhouses by simplifying the overall configuration and design compared to the conventional expensive automated filling devices.

In addition, the present invention can be efficiently performed by applying a variety of settings regardless of the type and properties of products such as grains, nuts, red pepper powder.

In addition, the present invention has various advantages, such as minimizing discharge accumulation due to aggregation of powders or adsorption of powders in the apparatus, thereby eliminating various problems such as loss of input capacity and causing malfunction of the apparatus. It is expected to be large.

110: first hopper 111: first driving means
112: first cleaner 113: second cleaner
120: first drum 121: first transport pipe
122: second transport pipe 123: second drive means
124: first elastic member 125: hinge member
126: third cleaner 130: metering drum
131: Weighing groove 132: Weighing block access tunnel
133: airtight means 134: gap portion
140: second drum 150: weighing module
151: setting surface 152: weighing frame
153: setting means 154: weighing block
155: Weighing indicator 160: Hopper 2
161: stretchable connecting means 162: second elastic member
163: fourth cleaner 164: third drive means
170: discharge guide 171: base frame
172: bottom support 173: first hole
174: lifting unit 175: side support
176: Chapter 2 177: moving part

Claims (7)

An apparatus for filling granules or powder products into a container in a fixed amount,
A first hopper of an upper and lower straits forming upper and lower inlets and outlets;
A horizontal cylindrical first drum having first and second transfer pipes coupled to the outlet of the first hopper and upper and lower outer circumferential surfaces thereof and mounting second driving means;
A metering drum axially coupled to the second driving means and rotating in contact with the inner circumferential surface of the first drum;
A horizontal cylindrical second drum mounted on one side of the first drum and accommodating the weighing module interlocked with the weighing drum;
A second hopper of a light-lower narrower provided below the second transfer pipe; And
And a discharge guide mounted on a base frame and setting a container position at a lower side of the second hopper. The method of claim 1,
The first driving means is mounted on the upper side of the first hopper and vertically provided as the core of the first hopper,
A first cleaner axially coupled to the first driving means and rotating in contact with an inner surface of the first hopper;
Granule or powder filling device, characterized in that configured to have a second cleaner axially coupled to the first drive means and rotates inside the first transfer pipe. The method of claim 1,
The metering drum,
On one side on the outer circumferential surface, the metering groove to form an inlet corresponding to the outlet of the first transport pipe or the inlet of the second transport pipe when the metering drum is rotated to a predetermined depth;
A metering block access tunnel allowing a horizontal through hole to communicate with a second drum inside the metering groove; And
And an airtight means provided on an outer circumferential surface of the metering drum except for the metering groove to contact the inner circumferential surface of the first drum.
Granule or powder filling device, characterized in that configured to provide a gap between the bottom of the metering groove and the core of the metering drum. The method of claim 1,
The weighing module,
A metering frame fixed at both ends on one side of the metering drum and spaced apart from the set surface by a predetermined distance;
Setting means axially coupled to the setting surface of the metering frame and reciprocating toward the metering drum; And
And a weighing block coupled to the setting means and configured to adjust the volume by entering and exiting the weighing groove through the weighing block access tunnel of the weighing drum. The method of claim 1,
In the second transfer pipe,
A first elastic member fixing one end to one side of the second transfer pipe;
A hinge member coupled to the other end of the first elastic member and axially coupled to one side wall of the second transfer pipe and provided inward; And
And a third cleaner coupled to the axial direction of the hinge member so as to be vertical and contacting the outer circumferential surface or elastically hitting the inner surface of the metering groove when the metering drum is rotated. . The method of claim 1,
On the upper side of the second hopper,
Stretch connecting means of '⊃' or '⊂' spaced apart by coupling the upper and lower ends to the lower end of the second transfer pipe and the upper flange of the second hopper;
A second elastic member fixing both ends between a lower end of the second transfer pipe and an upper flange of the second hopper; And
And a fourth cleaner mounted on one side of the second hopper and generating vibration in association with the third driving means. The method of claim 1,
The discharge guide,
A lifting portion forming a bottom support portion parallel to the base frame and a first long hole perpendicular to one side of the bottom support portion and coupling the fastening means to the base frame; And
And a side support part provided upward in a '∧' shape at the upper center of the bottom support part, and a moving part forming a second long hole for coupling the fastening means to the bottom support part at one side of the side support part. Granule or powder filling device.

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