CN215713426U - Electrolytic aluminum liquid quantitative discharging device - Google Patents

Abstract

The utility model discloses an electrolytic aluminum liquid quantitative discharging device which is connected with an electrolytic aluminum liquid discharging port, and a bearing and conveying device is attached to the outer surface of the electrolytic aluminum liquid discharging port; the method comprises the following steps: the material receiving pipeline is arranged on the outer surface of the discharge port, the conveying pipe is arranged on the outer surface of the material receiving pipeline, the heating layer is arranged on the outer surface of the conveying pipe, and the base is arranged on the lower surface of the conveying pipe; and the impact block is arranged on the inner surface of the conveying pipe. This electrolytic aluminum liquid ration discharging device, the setting has the all-round zone of heating that carries out, stable nestification is at the surface of conveyer pipe to get the material receiving pipeline that the bore increases gradually through installing, carry out stable connection in discharge gate department, prevent to appear leaking, and carry out stable transport to the conveyer pipe through the base, and through the impact block that sets up, prevent to cause the extrusion to the pipeline, and cause excessive impact to the backup pad, and through adjustable backup pad, control aluminium liquid circulation.

Description

Electrolytic aluminum liquid quantitative discharging device

Technical Field

The utility model relates to the technical field of electrolytic aluminum liquid, in particular to a quantitative discharging device for electrolytic aluminum liquid.

Background

In electrolytic aluminum industrial production, during the transport of prior art aluminium liquid, through manual control conveyer, carry out stable transportation with discharging device's aluminium liquid of giving off, but current discharging device still has certain defect, for example:

the utility model discloses an automatic discharging and charging device for electrolytic aluminum liquid, which is provided with an authorization notice number of CN211005651U and an authorization notice date of 20200714, and the device comprises an electrolytic cell and a sensor for monitoring the liquid level height of the electrolytic aluminum liquid in the electrolytic cell, … …, wherein the electrolytic aluminum liquid enters a discharging pipeline from an aluminum liquid outlet along the bottom inclined plane of the electrolytic cell, so that the automation level is improved, and the human resources are saved;

however, the above prior art solutions have the following drawbacks: when the device is used, the device needs to be operated manually, danger is easy to occur, aluminum liquid is easy to oxidize in the moving process, the flow speed of the device is not controlled, a large amount of aluminum liquid is easy to move, the pipeline is damaged, the heating device is uneven, and the aluminum liquid is easy to stick to the bottom.

Aiming at the problems, innovative design is urgently needed on the basis of the original desk structure.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an electrolytic aluminum liquid quantitative discharging device, which solves the problems that when the device is used, the device needs to be operated manually, danger is easy to occur, aluminum liquid is easy to oxidize in the moving process, in addition, the flow speed of the device is not controlled in the conveying process, a large amount of aluminum liquid is easy to move, the pipeline is damaged, in addition, the heating device is not uniform, and the aluminum liquid is easy to stick to the bottom.

In order to achieve the purpose, the utility model provides the following technical scheme: an electrolytic aluminum liquid quantitative discharging device is connected with an electrolytic aluminum liquid discharging port, and a bearing and conveying device is attached to the outer surface of the electrolytic aluminum liquid discharging port;

the method comprises the following steps:

the material receiving pipeline is arranged on the outer surface of the discharge port, the conveying pipe is arranged on the outer surface of the material receiving pipeline, the heating layer is arranged on the outer surface of the conveying pipe, and the base is arranged on the lower surface of the conveying pipe;

the impact block is arranged on the inner surface of the conveying pipe;

the moving groove is arranged on the inner surface of the conveying pipe, a moving block is mounted on the inner surface of the moving groove, a threaded rod for adjusting the position is mounted on the inner surface of the moving block, and a connecting block is mounted on the outer surface of the moving block;

the connecting rod is arranged on the outer surface of the connecting block, the outer surface of the connecting rod is connected with a supporting plate, and the outer surface of the supporting plate is connected with a distributing block;

the support frame, install in the upper surface of base, and upper surface connection has the drive belt, and the drive belt is connected with cylinder straight-teeth gear A through the main shaft to the meshing is connected with cylinder straight-teeth gear B.

Through above-mentioned structure, effectual carrying when using to ration and constant speed flow prevent to flow the too fast pipeline and cause the damage, and through heating all around, prevent the condition that the cooling solidifies.

Preferably, the material receiving pipeline and the conveying pipe form an inclined fixed connection, the outer surface of the material receiving pipeline is of a trapezoidal structure, the height of the inner surface of the material receiving pipeline is gradually increased, and meanwhile, the upper surface of the conveying pipe is supported and arranged by the support frame through the base of which the outer surface is of an inverted T-shaped structure.

Through above-mentioned structure, carry out effectual installation when using, prevent to leak, and carry out diversified heating, keep the stability of temperature.

Preferably, the impact block is fixed at the left side and the right side of the inner connection part of the material receiving pipeline and the conveying pipe in an embedded mode, the height of the outer surface of the impact block is consistent with that of the inner surface of the conveying pipe, and the shape of the outer surface of the impact block is of a triangular structure.

With the above structure, the impact device is prevented from being damaged during use, and the internal structure is stably moved.

Preferably, the moving block and the conveying pipe form a clamping sliding structure through a moving groove, the moving block is in threaded connection with the threaded rod, the connecting block and the outer side of the outer surface of the moving block are installed in an embedded mode, meanwhile, the connecting block and the connecting rod form a relative rotation structure, and the outer surface of the connecting rod and the outer surface of the supporting plate are hinged.

With the above configuration, the position of the control device is controlled during use to adjust the amount of the conveyance amount.

Preferably, the supporting plates are symmetrically arranged relative to the middle end of the inner surface of the conveying pipe, the distributing block and the inner surface of the conveying pipe are arranged in an embedded mode, the top end of the outer surface of the distributing block is of an arc-shaped structure, and meanwhile the edge end of the outer surface of the distributing block and the inner surface of the conveying pipe form a shunting type flow channel.

Through above-mentioned structure, carry out stable reposition of redundant personnel when using, prevent the condition of long-pending material to and carry out the stable supporting and use.

Preferably, the spur gear A is connected with the squeeze roller through the main shaft, the squeeze roller is provided with material stirring blocks with equal angles, the material stirring blocks and the edge end of the outer surface of the squeeze roller are arranged in an embedded mode, meanwhile, the squeeze roller is provided with 2 groups at equal intervals relative to the outer surface of the support frame, and the material stirring blocks arranged on the 2 groups of squeeze rollers are connected in a cross mode.

Through above-mentioned structure, carry out controlling means regulation velocity of flow when using, prevent that the velocity of flow is too fast to lead to the pipeline to receive excessive extrusion.

Compared with the prior art, the utility model has the beneficial effects that: the electrolytic aluminum liquid quantitative discharging device;

1. the heating layer is arranged in an all-dimensional mode and is stably embedded on the outer surface of the conveying pipe, the material receiving pipeline with the gradually increased caliber is installed and is stably connected to the discharging port to prevent leakage, the conveying pipe is stably conveyed through the base, the impact block is arranged to prevent the pipeline from being extruded and prevent excessive impact on the supporting plate, and the flow rate of aluminum liquid is controlled through the adjustable supporting plate;

2. when the supporting plate with the flow control amount is arranged, the distributing block with the shunt is connected to the outer surface of the supporting plate, the stable material stirring block arranged through the extrusion roller connected to the outer surface is used for stirring materials, the cylindrical straight gear A and the cylindrical straight gear B are controlled through the transmission belt arranged on the upper end supporting frame, the rotation of the extrusion roller is stably controlled, and the flow speed of the materials of the device is controlled

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic diagram of a semi-sectional three-dimensional structure of the material receiving pipeline of the present invention;

FIG. 3 is a schematic view of a partially cut-away perspective structure of the delivery tube of the present invention;

FIG. 4 is a schematic perspective view of the squeeze roll of the present invention;

fig. 5 is a schematic diagram of the exploded perspective structure of the present invention.

In the figure: 1. a receiving pipe; 2. a delivery pipe; 3. a heating layer; 4. a base; 5. an impact block; 6. a moving groove; 7. a moving block; 8. a threaded rod; 9. connecting blocks; 10. a connecting rod; 11. a support plate; 12. a material distributing block; 13. a support frame; 14. a transmission belt; 15. a spur gear A; 16. a spur gear B; 17. a squeeze roll; 18. a material stirring block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the 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.

Referring to fig. 1-5, the present invention provides a technical solution: an electrolytic aluminum liquid quantitative discharging device is connected with an electrolytic aluminum liquid discharging port, and a bearing and conveying device is attached to the outer surface of the electrolytic aluminum liquid discharging port; the method comprises the following steps: the material receiving pipeline 1 is arranged on the outer surface of the discharge port, the conveying pipe 2 is arranged on the outer surface of the material receiving pipeline, the heating layer 3 is arranged on the outer surface of the conveying pipe 2, and the base 4 is arranged on the lower surface of the conveying pipe; an impact block 5 mounted on the inner surface of the conveying pipe 2; a moving groove 6 which is arranged on the inner surface of the conveying pipe 2, is provided with a moving block 7 on the inner surface, is provided with a threaded rod 8 for adjusting the position on the inner surface of the moving block 7, and is provided with a connecting block 9 on the outer surface; the connecting rod 10 is arranged on the outer surface of the connecting block 9, the outer surface of the connecting rod is connected with a supporting plate 11, and the outer surface of the supporting plate 11 is connected with a distributing block 12; and a support frame 13 mounted on the upper surface of the base 4, wherein the upper surface is connected with a transmission belt 14, and the transmission belt 14 is connected with a spur gear A15 through a main shaft and is connected with a spur gear B16 in a meshing manner.

In use, leakage is prevented through the arranged material receiving pipeline 1, the materials stably flow into the conveying pipe 2 through the impact block 5, the distance between the supporting plates 11 is controlled, the flow is regulated, and the flow speed of the device is controlled through the operation of the squeezing rollers 17.

Material receiving pipe 1 and conveyer pipe 2 constitute slope fixed connection, and the surface of material receiving pipe 1 is the trapezium structure to material receiving pipe 1's internal surface height increases gradually, and the setting is supported with support frame 13 through base 4 that the surface shape is "T" structure to the upper surface of conveyer pipe 2 simultaneously.

The impact block 5 is fixed at the left side and the right side of the inner connection part of the material receiving pipeline 1 and the conveying pipe 2 in an embedded mode, the height of the outer surface of the impact block 5 is consistent with that of the inner surface of the conveying pipe 2, and the shape of the outer surface of the impact block 5 is of a triangular structure.

The moving block 7 and the conveying pipe 2 form a clamping sliding structure through the moving groove 6, the moving block 7 is in threaded connection with the threaded rod 8, the connecting block 9 and the outer side of the outer surface of the moving block 7 are installed in an embedded mode, meanwhile, the connecting block 9 and the connecting rod 10 form a relative rotation structure, and the outer surface of the connecting rod 10 and the outer surface of the supporting plate 11 are hinged.

The supporting plate 11 is symmetrically arranged about the middle end of the inner surface of the conveying pipe 2, the distributing block 12 and the inner surface of the conveying pipe 2 are installed in an embedded mode, the top end of the outer surface of the distributing block 12 is of an arc-shaped structure, and meanwhile the edge end of the outer surface of the distributing block 12 and the inner surface of the conveying pipe 2 form a shunting type flow channel.

When using, through the stable access of material receiving pipe 1, close backup pad 11, flow aluminium liquid to conveyer pipe 2 in, and through impact block 5, prevent to cause the impact to conveyer pipe 2 and backup pad 11, and carry out stable support through base 4, and layer of heating 3 all around heats, rethread motor drive threaded rod 8 rotates, adjust the position of movable block 7 in the shifting chute 6, thereby adjust connecting block 9 and drive connecting rod 10, the opening size of control backup pad 11, say aluminium liquid and flow to the upper surface of distributor block 12.

The spur gear A15 is connected with the extrusion roller 17 through a main shaft, the extrusion roller 17 is provided with material-pulling blocks 18 with equal angles, the material-pulling blocks 18 are embedded in the edge end of the outer surface of the extrusion roller 17, meanwhile, the extrusion roller 17 is provided with 2 groups with equal distance about the outer surface of the supporting frame 13, and the material-pulling blocks 18 arranged on the 2 groups of extrusion roller 17 are in cross connection.

When the aluminum liquid stirring device is used, the driving belt 14 on the supporting frame 13 is driven to rotate by starting the motor, so that the cylindrical spur gear A15 is meshed with the cylindrical spur gear B16 to be connected, the material stirring block 18 arranged on the extrusion roller 17 is adjusted to rotate alternately, the shunted aluminum liquid is extruded, and the aluminum liquid flows quantitatively at a constant speed.

The working principle is as follows: when the electrolytic aluminum liquid quantitative discharging device is used, according to the figures 1-5, the device is firstly placed at a position needing to work, when in use, a material receiving pipeline 1 arranged on a conveying pipe 2 is connected into a discharging port, a supporting plate 11 connected with a control device is closed, the damage to a device for controlling the flow velocity is prevented, the discharging port is opened, aluminum liquid flows into the conveying pipe 2, the conveying pipe 2 is supported through a base 4 on the outer surface, the heating layer 3 on the periphery is used for heating and controlling the temperature of the aluminum liquid, the supporting plate 11 is prevented from being extruded through the use of an impact block 5, then a motor is started, a moving block 7 is controlled by rotating a threaded rod 8 to move in a moving groove 6, a connecting rod 10 arranged on a connecting block 9 is adjusted, the angle of the supporting plate 11 is controlled, the discharging amount is effectively controlled, the distributing block 12 is used for distributing, and another group of motors is started, the control transmission belt 14 drives the cylindrical spur gear A15 and the cylindrical spur gear B16 under the support frame 13 to carry out meshing motion, the alternating speed between the material shifting blocks 18 arranged on the squeeze roll 17 is adjusted, the flow speed of the control device can be stabilized when the device is used, and the overall practicability is improved.

Those not described in detail in this specification are within the skill of the art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. An electrolytic aluminum liquid quantitative discharging device is connected with an electrolytic aluminum liquid discharging port, and a bearing and conveying device is attached to the outer surface of the electrolytic aluminum liquid discharging port;

it is characterized by comprising:

the material receiving pipeline is arranged on the outer surface of the discharge port, the conveying pipe is arranged on the outer surface of the material receiving pipeline, the heating layer is arranged on the outer surface of the conveying pipe, and the base is arranged on the lower surface of the conveying pipe;

the impact block is arranged on the inner surface of the conveying pipe;

the moving groove is arranged on the inner surface of the conveying pipe, a moving block is mounted on the inner surface of the moving groove, a threaded rod for adjusting the position is mounted on the inner surface of the moving block, and a connecting block is mounted on the outer surface of the moving block;

the connecting rod is arranged on the outer surface of the connecting block, the outer surface of the connecting rod is connected with a supporting plate, and the outer surface of the supporting plate is connected with a distributing block;

the support frame, install in the upper surface of base, and upper surface connection has the drive belt, and the drive belt is connected with cylinder straight-teeth gear A through the main shaft to the meshing is connected with cylinder straight-teeth gear B.

2. The electrolytic aluminum liquid quantitative discharging device of claim 1, characterized in that: the material receiving pipeline and the conveying pipe form an inclined fixed connection, the outer surface of the material receiving pipeline is of a trapezoidal structure, the height of the inner surface of the material receiving pipeline is gradually increased, and meanwhile the upper surface of the conveying pipe is supported and arranged through a base and a supporting frame, wherein the outer surface of the base is of an inverted T-shaped structure.

3. The electrolytic aluminum liquid quantitative discharging device of claim 1, characterized in that: the impact block is fixed on the left side and the right side of the inner connection position of the material receiving pipeline and the conveying pipe in an embedded mode, the height of the outer surface of the impact block is consistent with that of the inner surface of the conveying pipe, and the shape of the outer surface of the impact block is of a triangular structure.

4. The electrolytic aluminum liquid quantitative discharging device of claim 1, characterized in that: the movable block and the conveying pipe form a clamped sliding structure through the movable groove, the movable block is in threaded connection with the threaded rod, the connecting block and the outer side of the outer surface of the movable block are installed in an embedded mode, meanwhile, the connecting block and the connecting rod form a relative rotation structure, and the outer surface of the connecting rod and the outer surface of the supporting plate are hinged.

5. The electrolytic aluminum liquid quantitative discharging device of claim 1, characterized in that: the supporting plate is symmetrically arranged relative to the middle end of the inner surface of the conveying pipe, the distributing block and the inner surface of the conveying pipe are arranged in an embedded mode, the top end of the outer surface of the distributing block is of an arc-shaped structure, and meanwhile the edge end of the outer surface of the distributing block and the inner surface of the conveying pipe form a shunting type flow channel.

6. The electrolytic aluminum liquid quantitative discharging device of claim 1, characterized in that: the cylinder straight gear A is connected with the squeeze roll through the main shaft, the squeeze roll is provided with a material stirring block with equal angles, the material stirring block and the outer surface edge end of the squeeze roll are arranged in an embedded mode, meanwhile, the squeeze roll is provided with 2 groups at equal intervals relative to the outer surface of the supporting frame, and the material stirring blocks arranged on the 2 groups of squeeze rolls are connected in a cross mode.

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