CN216172149U - Production facility for high-purity alumina - Google Patents

Abstract

The utility model discloses a production device for high-purity alumina, which comprises a main body, wherein a control chamber is arranged at the top of the main body, a movable box is fixedly connected at the top of the control chamber, a material box is fixedly connected at the top of the movable box, the bottom of the material box extends into the movable box, a motor is fixedly arranged on the inner wall of the bottom of the movable box, a half gear is fixedly connected at one end of an output shaft of the motor, an extension tube is fixedly connected at the top of the main body, one end of an inner tube of the extension tube extends into the movable box, a threaded tube is rotatably connected at the top of the main body, a threaded column is connected in the threaded tube in a threaded manner, a sliding door is slidably connected at the bottom of the material box, the top of the sliding door is slidably connected with the inner wall of the top of the movable box, a movable mechanism is arranged in the movable box, and the utility model drives the half gear to be in circulating contact with a rack through the output shaft of the motor, the effect of automatically performing circulating feeding is realized.

Description

Production facility for high-purity alumina

Technical Field

The utility model relates to production equipment, in particular to production equipment for high-purity alumina.

Background

Alumina is an inorganic substance, has the chemical formula Al2O3, 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 production equipment for high-purity alumina in the prior art is difficult to carry out circular feeding processing production when in use, and is difficult to ensure the production quality when excessive materials enter, so that the production equipment for high-purity alumina is provided for solving the problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide production equipment for high-purity alumina, which solves the problems that the production equipment for high-purity alumina is difficult to carry out circular feeding processing production when in use and the production quality is difficult to ensure when materials enter too much.

In order to solve the above problems, the present invention provides the following technical solutions:

the utility model provides a production facility for high-purity alumina, includes the main part, the top of main part is equipped with the control room, and the top fixedly connected with movable box of control room, the top fixedly connected with material case of movable box, and the bottom of material case extends to the movable box in, the bottom inner wall fixed mounting of movable box has the motor, and the one end fixedly connected with half-gear of motor output shaft, the flexible pipe of top fixedly connected with of main part, and the one end of flexible pipe inner tube extends to the movable box in, the top of main part is rotated and is connected with the screwed pipe, and screwed pipe female connection has the screw thread post, the bottom sliding connection of material case has the sliding door, and the top of sliding door and the top inner wall sliding connection of movable box, be equipped with the moving mechanism in the movable box.

In order to realize that the control telescopic pipe moves and realize circulating feeding, the movable mechanism comprises a rack, a movable plate, a telescopic plate, a threaded ring, an L-shaped plate, a rotating column, a transmission belt and a trapezoidal plate, the number of the rotating columns is two, the rack is slidably connected with the inner wall of the top of the movable box, the rack is movably engaged with a half gear, the movable plate is fixedly connected with the left side of the rack, the telescopic plate is rotatably connected with the inner wall of the top of the movable box, the right side of the outer plate of the telescopic plate is rotatably connected with the left side of the movable plate, the left side of the inner pipe of the telescopic plate is rotatably connected with the right side of the sliding door, the threaded ring is threadedly sleeved on the outer wall of the threaded pipe, the right side of the threaded ring is slidably connected with the inner wall of the right side of the control room, the L-shaped plate is slidably connected with the inner wall of the top of the control room, the rotating columns are rotatably connected with the top of the main body, the transmission belt is fixedly sleeved on the outer walls of the two rotating columns, and the bottom of L template and the outer wall fixed connection of drive belt, trapezoidal plate sliding connection is in the front side inner wall of control room, and the outer wall fixed connection of trapezoidal plate and drive belt No. one.

In order to control the L-shaped plate to move left and right, the right side of the L-shaped plate is rotatably connected with a positioning rod, and the right end of the positioning rod is fixedly connected with the top of the threaded column.

In order to realize that the rack can control the threaded ring to synchronously move when moving, the inner wall of the rear side of the movable box is rotatably connected with the guide wheel, the bottom of the rack is fixedly connected with the guide belt, one end of the guide belt is fixedly connected with the top of the threaded ring, and the left side of the guide belt is in contact with the guide wheel.

In order to realize that the inner tube of the control telescopic tube moves, the right side of the inner tube of the telescopic tube is fixedly connected with a second trapezoidal plate, and the inclined plane of the second trapezoidal plate is contacted with the inclined plane of the first trapezoidal plate.

In order to realize that No. two trapezoidal plates carry out the return, the top fixedly connected with spring of No. two trapezoidal plates, and the one end of spring and the top inner wall fixed connection of control room.

Compared with the prior art, the utility model has the following beneficial effects:

1. the output shaft of the motor rotates, the output shaft of the motor guides the rack to move transversely through the half gear, the rack drives the moving plate and the guide belt to move synchronously, the guide belt pulls the threaded ring to ascend, and meanwhile, the threaded ring controls the threaded pipe to rotate through threads in the threaded ring;

2. along with the rotation of the threaded pipe, the threaded pipe pushes the L-shaped plate to move transversely through the threaded column and the positioning rod, the L-shaped plate synchronously drives the first trapezoidal plate to slide through the transmission belt, when the first trapezoidal plate slides, the first trapezoidal plate drives the second trapezoidal plate to ascend through the inclined plane of the first trapezoidal plate, the second trapezoidal plate drives the inner pipe of the telescopic pipe to ascend, the rack simultaneously drives the telescopic plate to rotate through pushing the moving plate, the telescopic plate pulls the sliding door to open, and the inner pipe of the telescopic pipe synchronously extends into the material box to be connected;

3. when half gear and rack disengagement, No. two trapezoidal boards carry out the return through the elasticity of spring this moment to control trapezoidal board return and drive the drive belt and carry out the return, the drive belt drives whole device through the return control screwed pipe reversal of L template and locating lever and carries out the return this moment, and the guide sliding door is closed, through the contact of half gear and rack, realizes the effect of circulation feeding.

The output shaft of the motor drives the half gear to be in circular contact with the rack, so that the effect of automatic circular feeding is realized.

Drawings

FIG. 1 is a three-dimensional view of the structure of a production apparatus for high purity alumina according to the present invention;

FIG. 2 is a front sectional view of a production apparatus for high purity alumina according to the present invention;

FIG. 3 is a schematic structural diagram of a threaded ring, a threaded pipe, a threaded column and a positioning rod of the production equipment for high-purity alumina according to the present invention;

FIG. 4 is a top view of the structure of an L-shaped plate, a rotating column, a transmission belt and a first trapezoidal plate of the production equipment for high-purity alumina.

In the drawings, the names of the parts corresponding to the reference numerals are as follows:

1-main part, 2-control chamber, 3-movable box, 4-material box, 5-motor, 6-semi-gear, 7-rack, 8-movable plate, 9-expansion plate, 10-sliding door, 11-guide wheel, 12-guide belt, 13-threaded ring, 14-threaded pipe, 15-threaded column, 16-positioning rod, 17-L template, 18-rotating column, 19-transmission belt, 20-first trapezoidal plate, 21-expansion pipe, 22-second trapezoidal plate and 23-spring.

Detailed Description

The present invention is further illustrated by the following figures and examples, which include, but are not limited to, the following examples.

As shown in fig. 1-4, a production apparatus for high purity alumina comprises a main body 1, a control chamber 2 is arranged at the top of the main body 1, a movable box 3 is fixedly connected to the top of the control chamber 2, a material box 4 is fixedly connected to the top of the movable box 3, the bottom of the material box 4 extends into the movable box 3, a motor 5 is fixedly installed on the inner wall of the bottom of the movable box 3, a half gear 6 is fixedly connected to one end of an output shaft of the motor 5, the half gear 6 is circularly engaged with a rack 7 through the characteristics of own insection, a telescopic pipe 21 is fixedly connected to the top of the main body 1, the telescopic pipe 21 receives material by extending into the material box 4, the main body 1 is subjected to feeding processing, one end of an inner pipe of the telescopic pipe 21 extends into the movable box 3, a threaded pipe 14 is rotatably connected to the top of the main body 1, the threaded pipe 14 can control a threaded column 15 to move up and down through own thread, therefore, the L-shaped plate 17 can be pushed to move left and right through the positioning rod 16, the threaded column 15 is connected to the inner thread of the threaded pipe 14, the sliding door 10 is connected to the bottom of the material box 4 in a sliding mode, the sliding door 10 plays a role in limiting blanking of the material box 4, the top of the sliding door 10 is connected with the inner wall of the top of the movable box 3 in a sliding mode, and the movable box 3 is internally provided with a movable mechanism;

in order to control the extension tube 21 to move to realize circular feeding, the movable mechanism comprises a rack 7, a movable plate 8, an extension plate 9, a threaded ring 13, an L-shaped plate 17, two rotating columns 18, a transmission belt 19 and a trapezoidal plate 20, the number of the rotating columns 18 is two, the rack 7 is slidably connected with the inner wall of the top of the movable box 3, the rack 7 is movably meshed with the half gear 6, the rack 7 can control the extension plate 9 to rotate through the movable plate 8 and can pull the guide belt 12 to pull the threaded ring 13 to ascend simultaneously, the movable plate 8 is fixedly connected to the left side of the rack 7, the extension plate 9 is rotatably connected with the inner wall of the top of the movable box 3, when the extension plate 9 rotates, the opening and closing of the sliding door 10 can be controlled through the self extensibility, the right side of the outer plate of the extension plate 9 is rotatably connected with the left side of the movable plate 8, and the left side of the inner tube of the extension plate 9 is rotatably connected with the right side of the sliding door 10, the threaded ring 13 is sleeved on the outer wall of the threaded pipe 14 in a threaded manner, the threaded ring 13 can control the forward rotation and the reverse rotation of the threaded pipe 14 through threads, the right side of the threaded ring 13 is in sliding connection with the inner wall of the right side of the control room 2, the L-shaped plate 17 is in sliding connection with the inner wall of the top of the control room 2, the rotating columns 18 are rotatably connected to the top of the main body 1, the L-shaped plate 17 drives the transmission belt 19 to rotate, the first trapezoidal plate 20 is controlled to move transversely, the second trapezoidal plate 22 is controlled to move, the transmission belt 19 is fixedly sleeved on the outer walls of the two rotating columns 18, the bottom of the L-shaped plate 17 is fixedly connected with the outer wall of the transmission belt 19, the first trapezoidal plate 20 is in sliding connection with the inner wall of the front side of the control room 2, and the first trapezoidal plate 20 is fixedly connected with the outer wall of the transmission belt 19; in order to control the L-shaped plate 17 to move left and right, the right side of the L-shaped plate 17 is rotatably connected with a positioning rod 16, and the right end of the positioning rod 16 is fixedly connected with the top of the threaded column 15;

in order to realize that the threaded ring 13 can be controlled to synchronously move when the rack 7 moves, the inner wall of the rear side of the movable box 3 is rotatably connected with a guide wheel 11, the bottom of the rack 7 is fixedly connected with a guide belt 12, one end of the guide belt 12 is fixedly connected with the top of the threaded ring 13, and the left side of the guide belt 12 is in contact with the guide wheel 11; in order to control the inner tube of the telescopic tube 21 to move, a second trapezoidal plate 22 is fixedly connected to the right side of the inner tube of the telescopic tube 21, and the inclined surface of the second trapezoidal plate 22 is in contact with the inclined surface of the first trapezoidal plate 20; in order to realize the return of the second trapezoidal plate 22, a spring 23 is fixedly connected to the top of the second trapezoidal plate 22, and one end of the spring 23 is fixedly connected to the inner wall of the top of the control chamber 2.

In the practical operation of the embodiment, the output shaft of the motor 5 rotates, the output shaft of the motor 5 drives the half gear 6 to rotate, when the half gear 6 rotates, the half gear 6 performs lateral movement through the toothed guiding rack 7, along with the movement of the rack 7, the rack 7 drives the moving plate 8 to move synchronously with the guiding belt 12, when the guiding belt 12 moves, the guiding belt 12 pulls the threaded ring 13 to ascend, along with the ascending of the threaded ring 13, the threaded ring 13 rotates through the threaded control threaded pipe 14 inside the threaded ring 13, at this time, along with the rotation of the threaded pipe 14, the threaded pipe 14 synchronously ascends through the threaded control threaded column 15, when the threaded column 15 ascends, the threaded column 15 pushes the L-shaped plate 17 through the positioning rod 16 to perform lateral movement, along with the movement of the L-shaped plate 17, the L-shaped plate 17 drives the driving belt 19 to rotate, when the driving belt 19 rotates, the transmission belt 19 synchronously drives the first trapezoidal plate 20 to slide, when the first trapezoidal plate 20 slides, the first trapezoidal plate 20 drives the second trapezoidal plate 22 to ascend through the inclined surface of the first trapezoidal plate 20, at the moment, the second trapezoidal plate 22 drives the inner tube of the telescopic tube 21 to ascend, simultaneously, along with the movement of the rack 7, the rack 7 drives the telescopic plate 9 to rotate through the pushing movable plate 8, when the telescopic plate 9 rotates, the telescopic plate 9 pulls the sliding door 10 to open, at the moment, the inner tube of the telescopic tube 21 synchronously extends into the material box 4 to receive the material, when the half gear 6 is disengaged from the rack 7, at the moment, the second trapezoidal plate 22 returns through the elasticity of the spring 23, at the same time, the second trapezoidal plate 22 controls the first trapezoidal plate 20 to return and drives the transmission belt 19 to return, at the moment, the transmission belt 19 drives the whole device to return through the return control threaded tube 14 of the L17 and the positioning rod 16 to rotate, at the moment, the sliding door 10 is closed, and the function of circular feeding is realized through the contact of the half gear 6 and the rack 7.

The utility model is well implemented in accordance with the above-described embodiments. It should be noted that, based on the above structural design, in order to solve the same technical problems, even if some insubstantial modifications or colorings are made on the present invention, the adopted technical solution is still the same as the present invention, and therefore, the technical solution should be within the protection scope of the present invention.

Claims (6)

1. A production facility for high-purity alumina, includes main part (1), its characterized in that: the top of the main body (1) is provided with a control chamber (2), the top of the control chamber (2) is fixedly connected with a movable box (3), the top of the movable box (3) is fixedly connected with a material box (4), the bottom of the material box (4) extends into the movable box (3), the bottom inner wall of the movable box (3) is fixedly provided with a motor (5), one end of an output shaft of the motor (5) is fixedly connected with a half gear (6), the top of the main body (1) is fixedly connected with a telescopic pipe (21), one end of an inner pipe of the telescopic pipe (21) extends into the movable box (3), the top of the main body (1) is rotatably connected with a threaded pipe (14), the threaded pipe (14) is internally threaded and is connected with a threaded column (15), the bottom of the material box (4) is slidably connected with a sliding door (10), and the top of the sliding door (10) is slidably connected with the top inner wall of the movable box (3), a movable mechanism is arranged in the movable box (3).

2. The production equipment for high-purity alumina according to claim 1, characterized in that: the movable mechanism comprises a rack (7), a movable plate (8), a telescopic plate (9), a threaded ring (13), an L-shaped plate (17), a rotating column (18), a transmission belt (19) and a trapezoidal plate (20), the number of the rotating columns (18) is two, the rack (7) is connected to the inner wall of the top of the movable box (3) in a sliding manner, the rack (7) is movably meshed with the half gear (6), the movable plate (8) is fixedly connected to the left side of the rack (7), the telescopic plate (9) is connected to the inner wall of the top of the movable box (3) in a rotating manner, the right side of the outer plate of the telescopic plate (9) is connected to the left side of the movable plate (8) in a rotating manner, the left side of the inner pipe of the telescopic plate (9) is connected to the right side of the sliding door (10) in a rotating manner, the threaded ring (13) is sleeved on the outer wall of the threaded pipe (14), and the right side of the threaded ring (13) is connected to the inner wall of the control chamber (2) in a sliding manner, l template (17) sliding connection is at the top inner wall of control room (2), and rotates the top of all rotating the connection in main part (1) of post (18), drive belt (19) fixed cover is established at the outer wall of two rotation posts (18), and the outer wall fixed connection of the bottom of L template (17) and drive belt (19), trapezoidal plate (20) sliding connection is at the front side inner wall of control room (2), and the outer wall fixed connection of trapezoidal plate (20) and drive belt (19).

3. The production equipment for high-purity alumina according to claim 2, characterized in that: the right side of the L-shaped plate (17) is rotatably connected with a positioning rod (16), and the right end of the positioning rod (16) is fixedly connected with the top of the threaded column (15).

4. The production equipment for high-purity alumina according to claim 1, characterized in that: the rear side inner wall of activity case (3) rotates and is connected with guide wheel (11), and the bottom fixedly connected with guide belt (12) of rack (7), the top fixed connection of the one end of guide belt (12) and screw ring (13), and the left side of guide belt (12) contacts with guide wheel (11).

5. The production equipment for high-purity alumina according to claim 1, characterized in that: the right side of the inner tube of the telescopic tube (21) is fixedly connected with a second trapezoidal plate (22), and the inclined surface of the second trapezoidal plate (22) is in contact with the inclined surface of the first trapezoidal plate (20).

6. The production apparatus for high-purity alumina according to claim 5, wherein: the top of the second trapezoidal plate (22) is fixedly connected with a spring (23), and one end of the spring (23) is fixedly connected with the inner wall of the top of the control chamber (2).

Images