CN216186191U - A packing unloader for aluminium oxide powder - Google Patents

Abstract

The utility model discloses a packaging and discharging device for alumina powder, which comprises a frame, a storage barrel and a transition bin, wherein the storage barrel is fixedly arranged at the upper end of an upright post, the upper part of the storage barrel is provided with a feed hopper, the lower part of the storage barrel is provided with a discharging pipe, the middle part of a cover plate at the upper end of the transition bin is provided with a through hole, the discharging pipe is inserted into the through hole in a clearance manner, a connecting block is arranged in the transition bin, the upper part of the connecting block is provided with a blocking head, and the blocking head is positioned right below the discharging pipe; support plates are arranged on two sides of the transition bin, a first air cylinder is arranged at the lower part of each support plate, and the lower end of each first air cylinder is fixedly arranged on the enclosing plate; the lower part of the transition bin is provided with a connecting pipe, and the packing bag is sleeved outside the connecting pipe. According to the utility model, the transition bin is arranged at the lower part of the storage cylinder, and the blocking head for blocking the discharge pipe is arranged in the transition bin, so that the discharge pipe can be closed instantly after the alumina powder is filled, the powder is prevented from being discharged continuously, and the accuracy of powder filling is ensured.

Description

A packing unloader for aluminium oxide powder

Technical Field

The utility model belongs to the technical field of packaging machines, and particularly relates to a packaging and discharging device for aluminum oxide powder.

Background

Alumina is a high hardness compound, has a melting point of 2054 ℃ and a boiling point of 2980 ℃, is an ionic crystal which can be ionized at high temperature, and is commonly used for manufacturing refractory materials. The aluminum oxide production process needs bagging and packaging, the existing aluminum oxide bagging method generally adopts a packaging machine, the bag opening of a packaging bag is manually opened, then the packaging bag is sleeved on the pipe opening of a discharge pipe at the lower end of a storage cylinder, a spiral auger on a discharge pipe of a storage bin is opened, and the spiral auger discharges and fills the aluminum oxide powder inside the storage cylinder into the packaging bag. The utility model provides a packaging and blanking device for alumina powder, which is characterized in that the alumina powder is packaged quantitatively, a spiral auger stops rotating after the weight of the powder in a packaging bag meets a preset weight requirement, however, due to the special structure of the spiral auger, the powder left at the lower end of the spiral auger continuously falls from the lower part of the spiral auger after the spiral auger stops rotating, and the weight of the alumina powder in the packaging bag exceeds a standard value.

Disclosure of Invention

The utility model aims to overcome the defects in the prior art and provides a packaging and discharging device for alumina powder, so as to solve the problem that the discharging of the discharging device of the existing packaging machine is inaccurate.

In order to achieve the purpose, the utility model adopts the technical scheme that:

a packaging and discharging device for alumina powder comprises a frame, a storage barrel and a transition bin, wherein the frame comprises four stand columns, the middles of the four stand columns are connected with a surrounding plate, one side of the surrounding plate is provided with an opening to facilitate sleeving of packaging bags, the storage barrel is fixedly arranged at the upper ends of the stand columns, the upper portion of the storage barrel is provided with a feeding hopper, the lower portion of the storage barrel is provided with a discharging pipe, the middle of a cover plate at the upper end of the transition bin is provided with a through hole, the discharging pipe is inserted into the through hole in a clearance mode, a connecting block is arranged inside the transition bin and connected with the inner wall of the transition bin through a plurality of connecting rods, the upper portion of the connecting block is provided with a blocking head, and the blocking head is located right below the discharging pipe; support plates are arranged on two sides of the transition bin, a first air cylinder is arranged at the lower part of each support plate, and the lower end of each first air cylinder is fixedly arranged on the enclosing plate; the lower part of the transition bin is provided with a connecting pipe, and the packing bag is sleeved outside the connecting pipe.

When the alumina powder is bagged, the packaging bag is sleeved outside the connecting pipe, the piston rod of the first air cylinder contracts and drives the transition bin to descend through the supporting plate, and the material storage cylinder is fixed in height, so that the material blocking head in the transition bin descends after descending, the material discharge pipe is opened, and the powder leaks into the packaging bag from the interior of the material storage cylinder; after the filling is accomplished, the piston rod extension of first cylinder drives the transition feed bin and risees to utilize the inside putty head shutoff of transition feed bin to arrange the export of expecting the pipe, avoided the powder to continue to drop from the storage cylinder, improved the accuracy of packagine machine unloading.

As a further preferred option of this technical scheme, be equipped with the motor on the storage cylinder, be connected with the pivot on the output shaft of motor, the pivot outside is equipped with a plurality of linking arms, and the one end of linking arm is equipped with the scraper blade, and one side of scraper blade offsets with the inner wall of storage cylinder, and the scraper blade has avoided alumina powder material adhesion on the storage cylinder inner wall.

As a further optimization of the technical scheme, the scraper is detachably connected with the connecting arm through a bolt, so that the scraper can be conveniently replaced after being worn.

As a further preferred of this technical scheme, arrange the intraduct and be equipped with spiral auger, spiral auger's upper end and pivot fixed connection, spiral auger has avoided the powder to block up row material pipe.

As a further optimization of the technical scheme, the material blocking head is of a frustum-shaped structure and is made of a rubber material, so that the sealing effect of the material blocking head is ensured.

As a further optimization of the technical scheme, the middle of the connecting block is provided with a jack, the lower part of the plugging head is provided with an inserted bar, the inserted bar is inserted into the jack in a clearance mode, the upper part of the connecting block is provided with a spring, the upper end of the spring is fixedly connected with the lower part of the plugging head, and the spring further ensures the sealing effect of the plugging head on the discharge pipe.

As a further optimization of the technical scheme, the connecting block is of a frustum-shaped structure, so that powder is prevented from being accumulated after falling on the connecting block.

As a further preference of the technical scheme, a plurality of flow guide pipes are arranged on the cover plate, the lower ends of the flow guide pipes are communicated with the interior of the transition bin, the upper ends of the flow guide pipes are closed, sleeves are sleeved outside the flow guide pipes, one side of each sleeve is connected with a discharge pipe through a support rod, one side of each sleeve is connected with an air inlet pipe, the air inlet pipe is connected with compressed gas (not shown in the figure), one side of each flow guide pipe is provided with an air vent, and after a blocking head rises to block the discharge pipe, the air inlet pipe is aligned with the air vent; at the moment, the compressed air blows the inside of the transition bin, so that the powder is prevented from adhering to the inner wall of the transition bin.

As a further optimization of the technical scheme, the air outlet at the lower end of the flow guide pipe is tangentially arranged with the inner wall of the transition bin, so that air flow is injected along the inner wall of the transition bin, and the injection effect is ensured.

As a further preferred option of the technical solution, a bag clamping device is arranged outside the connecting pipe, the bag clamping device comprises support frames symmetrically arranged on both sides of the connecting pipe, both ends of the support frames are hinged with clamp arms, a second cylinder is arranged in the middle of the clamp arms, a cylinder seat of the second cylinder is hinged with the right clamp arm, and a piston rod of the second cylinder is hinged with the left clamp arm; the lower end of the clamping arm is provided with a clamping plate, one side of the clamping plate is connected with a semicircular hoop, and the two hoops are tightly attached to the outer wall of the connecting pipe; after the packaging bag is sleeved on the outer wall of the connecting pipe, the second cylinder contracts, the hoop is driven by the clamping arms to lock the mouth of the packaging bag outside the connecting pipe, powder is prevented from floating out of the packaging bag, after filling is completed, the lower portion of the packaging bag is screwed down, the piston rod of the second cylinder is extended, and the packaging bag can be taken down.

The utility model has the beneficial effects that:

1) according to the utility model, the transition bin is arranged at the lower part of the storage cylinder, and the blocking head for blocking the discharge pipe is arranged in the transition bin, so that the discharge pipe can be closed instantly after the alumina powder is filled, the powder is prevented from being discharged continuously, and the accuracy of powder filling is ensured.

2) Be equipped with the motor on the storage cylinder, be connected with the pivot on the output shaft of motor, the pivot outside is equipped with a plurality of linking arms, and the one end of linking arm is equipped with the scraper blade, and one side of scraper blade offsets with the inner wall of storage cylinder, and the scraper blade has avoided alumina powder material adhesion on the storage cylinder inner wall.

3) The scraper blade is detachably connected with the connecting arm through a bolt, so that the scraper blade can be conveniently replaced after being worn.

4) The spiral auger is arranged in the discharge pipe, the upper end of the spiral auger is fixedly connected with the rotating shaft, and the spiral auger prevents powder from blocking the discharge pipe.

5) The material blocking head is of a frustum-shaped structure and is made of rubber materials, so that the sealing effect of the material blocking head is guaranteed.

6) The middle part of the connecting block is provided with an insertion hole, the lower part of the plugging head is provided with an insertion rod, the insertion rod is inserted into the insertion hole in a clearance mode, the upper part of the connecting block is provided with a spring, the upper end of the spring is fixedly connected with the lower part of the plugging head, and the spring further ensures the sealing effect of the plugging head on the discharge pipe.

7) The connecting block is a frustum-shaped structure, so that powder is prevented from being accumulated after falling on the connecting block.

8) The cover plate is provided with a plurality of flow guide pipes, the lower ends of the flow guide pipes are communicated with the interior of the transition bin, the upper ends of the flow guide pipes are closed, sleeves are sleeved outside the flow guide pipes, one sides of the sleeves are connected with the discharging pipes through supporting rods, one sides of the sleeves are connected with air inlet pipes, the air inlet pipes are connected with compressed gas, air vents are arranged on one sides of the flow guide pipes, and the air inlet pipes are aligned with the air vents after the blocking heads rise to block the discharging pipes; at the moment, the compressed air blows the inside of the transition bin, so that the powder is prevented from adhering to the inner wall of the transition bin.

9) The gas outlet of the lower end of the flow guide pipe is tangentially arranged with the inner wall of the transition bin, so that the gas flow is injected along the inner wall of the transition bin, and the injection effect is ensured.

10) The two sides of the connecting pipe are symmetrically connected with supporting frames, two ends of each supporting frame are hinged with clamping arms, the middle of each clamping arm is provided with a second air cylinder, a cylinder seat of each second air cylinder is hinged with the right clamping arm, and a piston rod of each second air cylinder is hinged with the left clamping arm; the lower end of the clamping arm is provided with a clamping plate, one side of the clamping plate is connected with a semicircular hoop, and the two hoops are tightly attached to the outer wall of the connecting pipe; after the packaging bag is sleeved on the outer wall of the connecting pipe, the second cylinder contracts, the hoop is driven by the clamping arms to lock the mouth of the packaging bag outside the connecting pipe, powder is prevented from floating out of the packaging bag, after filling is completed, the lower portion of the packaging bag is screwed down, the piston rod of the second cylinder is extended, and the packaging bag can be taken down.

Drawings

FIG. 1 is a schematic structural view of a packaging and blanking device for alumina powder of the present invention.

FIG. 2 is a schematic diagram of the internal structure of a storage cylinder in the packaging and feeding device for alumina powder.

FIG. 3 is a schematic diagram of a transition bin structure of a packaging and blanking device for alumina powder.

FIG. 4 is a schematic structural diagram of a bag clamping device in a packaging and blanking device for alumina powder.

In the figure: 1. a frame; 101. a column; 102. enclosing plates; 2. a storage cylinder; 201. a feed hopper; 202. a motor; 203. a rotating shaft; 204. a connecting arm; 205. a squeegee; 206. a spiral auger; 207. a discharge pipe; 3. a transition bin; 301. a cover plate; 302. a support plate; 303. a first cylinder; 304. plugging a material head; 305. a spring; 306. connecting blocks; 307. inserting a rod; 308. a jack; 309. a connecting rod; 310. a sleeve; 311. a flow guide pipe; 312. an air inlet pipe; 313. a vent hole; 4. a bag clamping device; 401. a connecting pipe; 402. a support frame; 403. clamping arms; 404. a second cylinder; 405. a clamping plate; 406. and (5) hooping.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below with reference to fig. 1 to 4, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used for convenience of description only, and do not indicate or imply that the devices or elements referred to must have a specific orientation, a specific orientation configuration and operation, and thus, are not to be construed as limiting the present invention.

As shown in fig. 1-3, a packaging and blanking device for alumina powder comprises a frame 1, a storage cylinder 2 and a transition bin 3, wherein the frame 1 comprises four upright posts 101, the middle parts of the four upright posts 101 are connected with a coaming 102, one side of the coaming 102 is open to facilitate sleeving of packaging bags, the storage cylinder 2 is fixedly installed at the upper ends of the upright posts 101, a feed hopper 201 is arranged at the upper part of the storage cylinder 2, a discharge pipe 207 is arranged at the lower part of the storage cylinder 2, a through hole is arranged in the middle part of a cover plate 301 at the upper end of the transition bin 3, the discharge pipe 207 is inserted into the through hole in a clearance manner, a connecting block 306 is arranged inside the transition bin 3, the connecting block 306 is connected with the inner wall of the transition bin 3 through a plurality of connecting rods 309, a blocking head 304 is installed at the upper part of the connecting block 306, and the blocking head 304 is positioned right below the discharge pipe 207; support plates 302 are arranged on two sides of the transition bin 3, a first air cylinder 303 is arranged at the lower part of each support plate 302, and the lower end of each first air cylinder 303 is fixedly arranged on the enclosing plate 102; the lower part of the transition bin 3 is provided with a connecting pipe 401, and the packaging bag is sleeved outside the connecting pipe 401.

When the alumina powder is bagged, the packaging bag is sleeved outside the connecting pipe 401, the piston rod of the first air cylinder 303 contracts, the transition bin 3 is driven to descend through the supporting plate 302, the material storage cylinder 2 is fixed in height, and after the transition bin 3 descends, the material blocking head 304 in the transition bin descends, so that the material discharging pipe 207 is opened, and the powder leaks into the packaging bag from the inside of the material storage cylinder 2; after the filling is completed, the piston rod of the first cylinder 303 extends to drive the transition bin 3 to rise, so that the outlet of the discharge pipe 207 is blocked by the blocking head 304 inside the transition bin 3, the powder material is prevented from continuously falling from the storage cylinder 2, and the blanking accuracy of the packaging machine is improved.

As shown in fig. 2, in this embodiment, a motor 202 is disposed on the storage barrel 2, a rotating shaft 203 is connected to an output shaft of the motor 202, a plurality of connecting arms 204 are disposed outside the rotating shaft 203, a scraper 205 is disposed at one end of each connecting arm 204, one side of the scraper 205 abuts against an inner wall of the storage barrel 2, and the scraper 205 prevents alumina powder from adhering to the inner wall of the storage barrel 2.

In this embodiment, as shown in fig. 2, the scraper 205 and the connecting arm 204 are detachably connected by bolts, so that the scraper 205 can be replaced after being worn.

As shown in fig. 2, in this embodiment, a spiral auger 206 is disposed inside the discharge pipe 207, an upper end of the spiral auger 206 is fixedly connected to the rotating shaft 203, and the spiral auger 206 prevents the powder from blocking the discharge pipe 207.

As shown in fig. 3, in the present embodiment, the plugging head 304 has a frustum-shaped structure, and the plugging head 304 is made of a rubber material, so that the sealing effect of the plugging head 304 is ensured.

In the embodiment shown in fig. 3, the middle of the connecting block 306 is provided with an insertion hole 308, the lower portion of the plugging head 304 is provided with an insertion rod 307, the insertion rod 307 is inserted into the insertion hole 308 with a gap, the upper portion of the connecting block 306 is provided with a spring 305, the upper end of the spring 305 is fixedly connected with the lower portion of the plugging head 304, and the spring 305 further ensures the sealing effect of the plugging head 304 on the discharge pipe 207.

As shown in fig. 3, in this embodiment, the connecting block 306 has a frustum-shaped structure, so as to prevent powder from accumulating after falling on the connecting block 306.

As shown in fig. 2-3, in this embodiment, the cover plate 301 is provided with a plurality of flow guide pipes 311, the lower ends of the flow guide pipes 311 are communicated with the inside of the transition bin 3, the upper ends of the flow guide pipes 311 are closed, a sleeve 310 is sleeved outside the flow guide pipes 311, one side of the sleeve 310 is connected with the discharge pipe 207 through a support rod, one side of the sleeve 310 is connected with an air inlet pipe 312, the air inlet pipe 312 is connected with compressed air (not shown in the figure), one side of the flow guide pipe 311 is provided with a vent hole 313, and when the blocking head 304 rises to block the discharge pipe 207, the air inlet pipe 312 is aligned with the vent hole 313; at the moment, the compressed air blows the interior of the transition bin 3, so that the powder is prevented from adhering to the inner wall of the transition bin 3.

As shown in fig. 3, in this embodiment, the air outlet at the lower end of the flow guiding pipe 311 is arranged tangentially to the inner wall of the transition bin 3, so that the air flow is blown along the inner wall of the transition bin 3, and the blowing effect is ensured.

As shown in fig. 4, in this embodiment, a bag clamping device 4 is disposed outside the connecting pipe 401, the bag clamping device 4 includes support frames 402 symmetrically disposed on both sides of the connecting pipe 401, both ends of the support frame 402 are hinged with clamping arms 403, a second air cylinder 404 is disposed in the middle of the clamping arms 403, a cylinder seat of the second air cylinder 404 is hinged with the right clamping arm 403, and a piston rod of the second air cylinder 404 is hinged with the left clamping arm 403; the lower end of the clamping arm 403 is provided with a clamping plate 405, one side of the clamping plate 405 is connected with a semicircular hoop 406, and the two hoops 406 are tightly attached to the outer wall of the connecting pipe 401; after the packaging bag is sleeved on the outer wall of the connecting pipe 401, the second air cylinder 404 contracts, the hoop 406 is driven by the clamping arm 403 to lock the mouth of the packaging bag outside the connecting pipe 401, powder is prevented from floating out of the packaging bag, after filling is completed, the lower portion of the packaging bag is screwed down, the piston rod of the second air cylinder 404 is extended, and the packaging bag can be taken down.

The foregoing is merely exemplary and illustrative of the present invention, and various modifications, additions and substitutions may be made by those skilled in the art to the specific embodiments described without departing from the scope of the utility model as defined in the accompanying claims.

Claims (10)

1. A packaging and discharging device for alumina powder comprises a frame, a storage barrel and a transition bin, wherein the frame comprises four stand columns, the middles of the four stand columns are connected with a coaming, one side of the coaming is open, the storage barrel is fixedly installed at the upper ends of the stand columns, a feeding hopper is arranged at the upper part of the storage barrel, and a discharging pipe is arranged at the lower part of the storage barrel; support plates are arranged on two sides of the transition bin, a first air cylinder is arranged at the lower part of each support plate, and the lower end of each first air cylinder is fixedly arranged on the enclosing plate; the lower part of the transition bin is provided with a connecting pipe, and the packing bag is sleeved outside the connecting pipe.

2. The packaging and discharging device for aluminum oxide powder as claimed in claim 1, wherein the storage barrel is provided with a motor, the output shaft of the motor is connected with a rotating shaft, the rotating shaft is externally provided with a plurality of connecting arms, one end of each connecting arm is provided with a scraper, and one side of each scraper abuts against the inner wall of the storage barrel.

3. The packaging and blanking device for the alumina powder as claimed in claim 2, wherein the scraper and the connecting arm are detachably connected by a bolt.

4. The packaging and blanking device for the alumina powder as claimed in claim 2 or 3, wherein a spiral auger is arranged inside the discharging pipe, and the upper end of the spiral auger is fixedly connected with the rotating shaft.

5. The packaging and blanking device for the alumina powder as claimed in claim 1, wherein the plugging head is of a frustum-shaped structure and is made of rubber material.

6. The packing and blanking device for alumina powder as claimed in claim 5, wherein the connecting block has a central hole, the lower part of the plugging head has a rod inserted into the central hole with a gap, the upper part of the connecting block has a spring, and the upper end of the spring is fixedly connected to the lower part of the plugging head.

7. The packaging and blanking device for the alumina powder as claimed in claim 5 or 6, wherein the connecting block is of a frustum-shaped structure.

8. The blanking device for packaging alumina powder as claimed in claim 1, wherein the cover plate is provided with a plurality of flow guide pipes, the lower ends of the flow guide pipes are communicated with the inside of the transition bin, the upper ends of the flow guide pipes are closed, the outside of the flow guide pipes is sleeved with a sleeve pipe, one side of the sleeve pipe is connected with the discharge pipe through a support rod, one side of the sleeve pipe is connected with an air inlet pipe, the air inlet pipe is connected with compressed gas, one side of the flow guide pipes is provided with vent holes, and when the blocking head rises to block the discharge pipe, the air inlet pipe is aligned with the vent holes.

9. The packaging and blanking device for the alumina powder as claimed in claim 8, wherein the air outlet at the lower end of the draft tube is tangentially arranged with the inner wall of the transition bin.

10. The packaging and discharging device for the alumina powder according to claim 1, wherein a bag clamping device is arranged outside the connecting pipe, the bag clamping device comprises support frames symmetrically arranged at two sides of the connecting pipe, clamping arms are hinged at two ends of each support frame, a second cylinder is arranged in the middle of each clamping arm, a cylinder seat of the second cylinder is hinged with the right clamping arm, and a piston rod of the second cylinder is hinged with the left clamping arm; the lower extreme of arm lock is equipped with the grip block, and grip block one side is connected with semicircular staple bolt, and two staple bolts are hugged closely with the outer wall of connecting pipe.

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