CN216098279U - Nano-particle polishing tank - Google Patents

Abstract

The utility model discloses a nano-particle polishing tank, which relates to the technical field of ceramic product production equipment and comprises a shell, wherein a barrel body with an opening at one end is arranged in the shell, a feeding hopper is hinged on the shell, the discharging end of the feeding hopper extends into the barrel body through the opening of the barrel body, the shell is also detachably connected with a discharging box, a power assembly for driving the barrel body to rotate is arranged on the shell, a helical blade is arranged in the barrel body, the side part of the helical blade extends to the inner wall of the barrel body, a grid plate is arranged in the shell and is positioned in the area between the helical blades at two sides, an air inlet pipe extending into the opening is arranged on the shell, the other end of the air inlet pipe is connected with a hot air blower, when the barrel body rotates forwards under the action of the power assembly, materials entering the barrel body from the feeding hopper are conveyed to the sealing end of the barrel body under the action of the helical blades, and the polishing efficiency and the polishing quality of the materials are improved.

Description

Nano-particle polishing tank

Technical Field

The utility model relates to the technical field of ceramic-like product production equipment, in particular to a polishing tank for nano ceramic-like sand grains.

Background

The sand playing is an indispensable game for children in childhood, and the hand-operating ability of the children can be improved by accumulating sand, shoveling sand, touching sand and the like, the muscular tissue of the children can be exercised, and the hand-eye coordination ability and the physical quality of the children can be improved. Meanwhile, sand is not in a fixed shape, so that children can pile up into different shapes according to own imagination, and the imagination and creativity of the children can be improved to a great extent. Because of playing various benefits of sand, a lot of children's places of amusement have all set up the sand pool, and natural sand or artifical sand is mostly adopted in the sand pool in most places of amusement at present, and these two kinds of sand all have a lot of potential safety hazards: if the cleaning cannot be carried out, bacteria are easy to breed, and dust is easy to rise; the particles are not uniform, and the fine sand is too much, so that the particles can easily enter eyes, ears and respiratory tracts of children; meanwhile, the surface is not smooth, so that delicate skin of the child is easily scratched, and the like, and the health and the safety of the child are seriously threatened.

With the development of nanotechnology, a new ceramic-like sand grain is developed in the market, and the sand grain is formed by extruding materials into slices by an extruder and then cutting the slices into small grains with the same size by a cutter.

Disclosure of Invention

Aiming at the defects, the utility model aims to provide a nano particle polishing tank, and aims to solve the technical problems that in the prior art, porcelain-like sand grains are easy to have burrs, the surface is rough, and the surface brightness is low.

In order to solve the technical problems, the technical scheme of the utility model is as follows:

the utility model provides a nano-particles thing polishing tank, which comprises a housin, be equipped with one end open-ended staving in the casing, it has feed hopper to articulate on the casing, feed hopper's discharge end extends to in the staving through the opening of staving, it connects out the workbin still to detachable on the casing, be equipped with drive staving pivoted power component on the casing, be equipped with helical blade in the staving, helical blade's lateral part extends to the inner wall of staving, be equipped with the grid plate in the casing, the grid plate is located the region between the helical blade of both sides, be equipped with the intake pipe that extends to in the opening on the casing, the air heater is connected to the other end of intake pipe.

Preferably, a transition arc is arranged at the joint of the side wall of the sealing end of the barrel body and the bottom plate.

Preferably, the lateral part of feed hopper is equipped with the second fixture block, is equipped with the second draw-in groove in the second fixture block, and the second draw-in groove inside callipers is equipped with the intake pipe.

Preferably, the open end of the barrel body is provided with a discharge port, a cover plate is detachably connected to the discharge port, and an opening is formed in the cover plate.

Preferably, a first handle is fixedly connected to the cover plate.

Preferably, the opposite sides of the discharging box are hinged with second handles.

Preferably, the grid plate is fixedly connected to the inner wall of the barrel body through a connecting rod.

Preferably, be equipped with a conical section of thick bamboo on the discharge gate, a conical section of thick bamboo is the flaring form along the direction of keeping away from the discharge gate, and a throat end of a conical section of thick bamboo extends to the lateral wall of discharge gate.

Preferably, the outer wall of the barrel body is sleeved with an insulating layer.

After the technical scheme is adopted, the utility model has the beneficial effects that:

because the nano-particle polishing tank comprises a shell, a barrel body with an opening at one end is arranged in the shell, a feeding funnel is hinged on the shell, the discharging end of the feeding funnel extends into the barrel body through the opening of the barrel body, the shell is also detachably connected with a discharging box, a power assembly for driving the barrel body to rotate is arranged on the shell, a helical blade is arranged in the barrel body, the side part of the helical blade extends to the inner wall of the barrel body, a grid plate is arranged in the shell, the grid plate is positioned in the area between the helical blades at two sides, an air inlet pipe extending into the opening is arranged on the shell, the other end of the air inlet pipe is connected with a hot air blower, when the barrel body rotates forwards under the action of the power assembly, materials entering the barrel body from the feeding funnel are conveyed to the sealing end of the barrel body under the action of the helical blade, the materials become smooth and bright under the mutual friction impact, and the hot air blower blows hot air into the barrel body through the air inlet pipe, the hot-blast burr that makes on the material melts the shrink, changes in the burr on the getting rid of the material, and the grid plate makes it more even to the material mixture in to the staving to can not reduce hot-blast temperature by a wide margin, the polishing back that finishes, the staving is reversal under power component's effect, and the material is carried to the opening part under helical blade's effect, and the in-process material of carrying receives further polishing.

Because the lateral wall of the seal end of the barrel body is provided with the transition circular arc at the joint of the bottom plate and the base plate, the materials move towards the center in the seal end of the barrel body, and the seal end which is left over by one part when the materials at the seal end are conveyed out of the barrel is avoided.

Because feed hopper's lateral part is equipped with the second fixture block, is equipped with the second draw-in groove in the second fixture block, and second draw-in groove inside callipers is equipped with the intake pipe for intake pipe detachable connects on feed hopper, and during the material ejection of compact, can be along with feed hopper together upwards swing, avoid the opening part.

Because the open end of staving is equipped with the discharge gate, and detachable is connected with the apron on the discharge gate, has seted up the opening on the apron for the speed of material ejection of compact.

Because the cover plate is fixedly connected with the first handle, the cover plate can be disassembled more easily.

Because the opposite side of ejection of compact case all articulates there is the second handle for ejection of compact case's dismantlement is convenient and fast more.

Because the grid plate passes through the inner wall of connecting rod rigid coupling in the staving for the grid plate rotates along with the staving, improves the polishing quality of material.

Because be equipped with the toper section of thick bamboo on the discharge gate, the toper section of thick bamboo is the flaring form along the direction of keeping away from the discharge gate, and the throat end of toper section of thick bamboo extends to the lateral wall of discharge gate for the material that discharge gate department flows into out the workbin along the toper section of thick bamboo, prevents that the material from spattering everywhere.

In conclusion, the utility model solves the technical problems that the porcelain-like sand grains in the prior art are easy to have burrs, the surface is rough and the surface brightness is low, when the barrel body rotates forwards under the action of the power assembly, the materials entering the barrel body from the feeding hopper are conveyed to the sealing end of the barrel body under the action of the spiral blade, the materials become smooth and bright under mutual friction and impact, meanwhile, the hot air blower blows hot air into the barrel body through the air inlet pipe, the burrs on the materials are melted and shrunk by the hot air, the burrs on the materials are easier to remove, the materials in the barrel body are mixed by the grid plate to be more uniform, the temperature of the hot air cannot be greatly reduced, after polishing is finished, the barrel body rotates backwards under the action of the power assembly, the materials are conveyed to the opening under the action of the spiral blade, and the materials are further polished in the conveying process.

Drawings

FIG. 1 is a sectional view showing the structure of a nano-particle polishing tank according to the present invention;

fig. 2 is a schematic structural view of a nano-particle polishing tank according to the present invention.

In the figure, the housing 1, the mounting block 10, the rotating shaft 11, the supporting block 12, the first clamping groove 120, the air inlet pipe 13, the transition arc 14, the barrel body 2, the helical blade 20, the grid plate 21, the opening 22, the discharge port 23, the cover plate 24, the first handle 240, the conical barrel 25, the connecting rod 26, the feed hopper 3, the connecting block 30, the second clamping block 31, the second clamping groove 310, the discharge hopper 4, the first clamping block 40, the second handle 41, the power assembly 5, and the motor 50.

Detailed Description

The utility model is further elucidated with reference to the drawing.

The orientations referred to in this specification are based on the orientation of the nano-particle polishing tank of the present invention during normal operation, and do not limit the orientation during storage and transportation, but only represent relative positional relationships, and do not represent absolute positional relationships.

As shown in fig. 1 and fig. 2, a nano-particle polishing tank comprises a casing 1, a barrel 2 with an opening 22 at one end is arranged in the casing 1, a heat insulating layer is sleeved on the outer wall of the barrel 2, an installation block 10 is welded on the casing 1, a through hole is arranged on the installation block 10, a rotating shaft 11 is rotatably arranged in the through hole, a connecting block 30 is welded on a feeding funnel 3, the connecting block 30 is welded with the rotating shaft 11, the discharging end of the feeding funnel 3 extends into the barrel 2 through the opening 22 of the barrel 2, a supporting block 12 is welded on the casing 1, a discharging funnel 4 is arranged on the supporting block 12, a first clamping groove 120 is arranged on the supporting block 12, a first clamping block 40 matched with the first clamping groove 120 is arranged on the discharging funnel 4, a second handle 41 is preferably hinged on the opposite side of the discharging funnel 4, a power assembly 5 for driving the barrel 2 to rotate is arranged on the casing 1, the power assembly 5 used in the embodiment is a motor 50, an output shaft of a motor 50 is connected with a sealing end of a barrel body 2, a spiral blade 20 is arranged in the barrel body 2, the side part of the spiral blade 20 extends to the inner wall of the barrel body 2, the inner side of the spiral blade 20 is enclosed into a barrel-shaped area, a grid plate 21 is arranged in the barrel-shaped area, an air inlet pipe 13 extending into an opening 22 is arranged on a shell 1, the other end of the air inlet pipe 13 is connected with an air heater, when the barrel body 2 rotates forwards under the action of the motor 50 in use, a material and a polishing agent are added into the barrel body 2 from a feeding funnel 3, the material and the polishing agent entering the barrel body 2 are mixed and conveyed to the sealing end of the barrel body 2 under the action of the spiral blade 20, the material becomes smooth and bright under mutual friction and impact, meanwhile, the air heater blows hot air into the barrel body 2 through the air inlet pipe 13, the hot air melts and shrinks burrs on the material to be easier to remove the burrs on the material, the material is stirred by the grid plate 21 to be distributed more evenly, dial the material of center department to the helical blade 20 department of both sides to can not reduce hot-blast temperature by a wide margin, the polishing back that finishes, staving 2 reverses under motor 50's effect, and the material is carried to opening 22 department under helical blade 20's effect, and with feed hopper 3 and intake pipe 13 upswing simultaneously, avoid opening 22, the in-process material of carrying receives further polishing, flows into out the workbin from opening 22.

Wherein, the lateral wall of the seal end of staving 2 is equipped with transition circular arc 14 with the junction of bottom plate, and during the use, the material moves towards center department in to the staving 2 seal end, avoids seal end department's material to have partly to leave over when carrying outside the bucket.

As a preferable example of the present embodiment, the second fixture block 31 is disposed on a side portion of the feeding funnel 3, the second fixture block 31 is disposed with the second clamping groove 310, the air inlet pipe 13 is clamped in the second clamping groove 310, the air inlet pipe 13 is detachably connected to the feeding funnel 3 during use, and the material can swing upwards along with the feeding funnel 3 to avoid the opening 22 during material discharging.

Wherein, the opening 22 end of staving 2 is equipped with discharge gate 23, and detachable is connected with apron 24 on the discharge gate 23, has seted up opening 22 on the apron 24 for the speed of material ejection of compact, the rigid coupling has the first in command 240 on the apron 24 for apron 24's dismantlement is more laborsaving.

Wherein, the grid plate 21 is fixedly connected to the inner wall of the barrel body 2 through the connecting rod 26, and when in use, the grid plate 21 rotates along with the barrel body 2.

As a preferable example of the present embodiment, the discharge port 23 is provided with a tapered cylinder 25, the tapered cylinder 25 is in a gradually expanding shape along a direction away from the discharge port 23, a reduced end of the tapered cylinder 25 extends to a side wall of the discharge port 23, and when the material discharging device is used, the material flowing out of the discharge port 23 flows into the discharge box along the tapered cylinder 25, so that the material can be prevented from being splashed.

The present invention is not limited to the above-described embodiments, and those skilled in the art will be able to make various modifications without creative efforts from the above-described conception, and fall within the scope of the present invention.

Claims (9)

1. A nano-particle polishing tank is characterized by comprising a shell, wherein a barrel body with an opening at one end is arranged in the shell, a feeding funnel is hinged on the shell, the discharge end of the feeding funnel extends into the barrel body through the opening of the barrel body, the shell is also detachably connected with a discharge box, a power assembly for driving the barrel body to rotate is arranged on the shell,

the barrel body is internally provided with a helical blade, the side part of the helical blade extends to the inner wall of the barrel body,

a grid plate is arranged in the shell and is positioned in the area between the helical blades on the two sides,

the shell is provided with an air inlet pipe extending into the opening, and the other end of the air inlet pipe is connected with an air heater.

2. The nano-particle polishing can as claimed in claim 1, wherein a transition arc is formed at a junction of the bottom plate and the sidewall of the closed end of the can body.

3. The nano-particle polishing tank of claim 1, wherein a second clamping block is disposed on a side portion of the feeding hopper, a second clamping groove is disposed in the second clamping block, and the air inlet pipe is clamped in the second clamping groove.

4. The nano-particle polishing tank of claim 1, wherein a discharge port is formed at an opening end of the tank body, a cover plate is detachably connected to the discharge port, and the cover plate is provided with the opening.

5. The nano-particle polishing can of claim 4, wherein a first handle is attached to the lid.

6. The nano-particle polishing tank of claim 1, wherein a second handle is hinged to each of opposite sides of the discharge tank.

7. The nano-particle polishing tank of claim 1, wherein the grid plate is fixedly connected to the inner wall of the tank body by a connecting rod.

8. The nano-particle polishing tank of claim 4, wherein the discharge port is provided with a tapered barrel, the tapered barrel is gradually expanded along a direction away from the discharge port, and a reduced end of the tapered barrel extends to a side wall of the discharge port.

9. The nano-particle polishing tank according to any one of claims 1 to 8, wherein an insulating layer is sleeved on an outer wall of the tank body.

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