CN216465201U - Avoid causing inaccurate magnesia carbon brick weighing device of measurement at weighing in-process - Google Patents

Abstract

The utility model provides a magnesia carbon brick weighing device which avoids inaccurate measurement in the weighing process. Avoid causing the inaccurate magnesia carbon brick weighing device of measurement in the weighing process to include: the processing device comprises a processing base, a weighing mechanism and a control device, wherein the processing base is provided with a processing mechanism and a weighing mechanism; the magnesium carbon brick weighing device comprises a production box, a manufacturing mold, two supporting plates, a mounting plate, a processing support, a hydraulic cylinder, a lifting plate, four positioning rods and a pressing block, wherein the production box is fixedly mounted at the top of a processing base, the manufacturing mold is fixedly mounted on the production box, and the two supporting plates are both fixedly mounted at the top of the processing base.

Description

Avoid causing inaccurate magnesia carbon brick weighing device of measurement at weighing in-process

Technical Field

The utility model belongs to the technical field of magnesia carbon brick weighing, and particularly relates to a magnesia carbon brick weighing device capable of avoiding inaccurate metering in the weighing process.

Background

A magnesia carbon brick is an indispensable refractory material in the steel industry, the magnesia carbon brick is made of fused magnesia and graphite as raw materials, resin is used as a bonding agent, a refractory product is made by technological processes of mixing, molding, heat treatment and the like, in the production process, different size fractions of the fused magnesia and graphite fine powder are added into mixing equipment according to weight percentage, at present, a manual mode is generally adopted, the graphite is added into the mixing equipment after being weighed, the mode is high in labor intensity and low in production efficiency, and in the prior art, a raw material weighing device for steam-pressing brick production is disclosed, the technical field of weighing devices is related, the problems that batch blanking is not easy to carry out according to required amount and the flexibility of structural use is not enough in the existing weighing device for the raw materials for producing the steam-pressing bricks are solved. The collecting box is characterized in that a blanking pipe is arranged at the upper end of the collecting box, a partition plate is arranged in the collecting box, a first movable plate is arranged in the partition plate, the collecting box is of a funnel shape, a first opening is formed in the collecting box, a supporting plate is arranged at the lower end of the collecting box, weighing equipment is arranged in the supporting plate, a first supporting rod is arranged at the lower end of the collecting box, a base is arranged at the lower ends of the first supporting rod and the supporting plate, and an inclined plate is arranged in the base.

However, the structure has the disadvantages that when the raw materials for producing the magnesia carbon bricks are weighed, the raw materials are often added at one time, so that the metering is inaccurate, the produced magnesia carbon bricks are inconsistent in size, and the magnesia carbon bricks need to be reprocessed by operators, so that the time and the labor are wasted.

Therefore, there is a need to provide a new magnesia carbon brick weighing apparatus which avoids the inaccurate measurement during the weighing process.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a magnesia carbon brick weighing device which can realize accurate weighing by controlling the adding speed of raw materials in the magnesia carbon brick raw material weighing process, can convey the raw materials for processing and avoids inaccurate metering in the weighing process.

In order to solve the technical problem, the magnesia carbon brick weighing device for avoiding inaccurate metering in the weighing process comprises a processing base, wherein a processing mechanism and a weighing mechanism are arranged on the processing base; the processing mechanism comprises a production box, a manufacturing die, two supporting plates, a mounting plate, a processing bracket, a hydraulic cylinder, a lifting plate, four positioning rods and a pressing block, the production box is fixedly arranged at the top of the processing base, the manufacturing mould is fixedly arranged on the production box, the two support plates are both fixedly arranged at the top of the processing base, the mounting plate is fixedly arranged on the top of the two supporting plates, the processing bracket is fixedly arranged on the mounting plate, the hydraulic cylinder is fixedly arranged on the inner wall of the top of the processing bracket, the lifting plate is fixedly arranged on an output shaft of the hydraulic cylinder, the four positioning rods are all fixedly arranged at the bottom of the mounting plate, the bottom end of the positioning rod is fixedly connected with the top of the production box, the positioning rod is connected with the lifting plate in a sliding mode, the pressing block is fixedly installed at the bottom of the lifting plate, and the pressing block is matched with the manufacturing mold;

the weighing mechanism comprises a weighing tank, a trapezoidal block, a rotating plate, a weighing sensor, a material carrying plate, an arc-shaped groove, an arc-shaped block, an arc-shaped toothed plate, a first servo motor and a first gear, the weighing tank is fixedly arranged at the bottom of a mounting plate, the trapezoidal block is fixedly arranged on the inner wall of one side of the weighing tank, the rotating plate is hinged to the bottom of the trapezoidal block, the weighing sensor is fixedly arranged at the top of the rotating plate, the material carrying plate is fixedly arranged at the top of the weighing sensor, the arc-shaped groove is formed in the bottom of the trapezoidal block, the arc-shaped block is fixedly arranged at the bottom of the rotating plate, one side of the arc-shaped block extends into the arc-shaped groove and is in sliding connection with the arc-shaped groove, the arc-shaped toothed plate is fixedly arranged on the arc-shaped block, the first servo motor is fixedly arranged at the bottom of the trapezoidal block, and the first gear is fixedly arranged on an output shaft of the first servo motor, the first gear is meshed with the arc toothed plate.

As a further scheme of the utility model, a speed-limiting block is slidably mounted on the outer wall of one side of the weighing tank, one side of the speed-limiting block extends into the weighing tank, the outer wall of one side of the speed-limiting block is in contact with the outer wall of one side of the trapezoidal block, a rectangular toothed plate is fixedly mounted at the bottom of the speed-limiting block, a second servo motor is fixedly mounted on the outer wall of one side of the weighing tank, a second gear is fixedly mounted on an output shaft of the second servo motor, and the second gear is meshed with the rectangular toothed plate.

As a further scheme of the utility model, an auxiliary plate is fixedly installed in the production box, a first rotating motor is fixedly installed on the outer wall of one side of the production box, a threaded rod is fixedly installed on an output shaft of the first rotating motor, one end of the threaded rod extends into the production box and is rotatably connected with the production box, one end of the threaded rod is rotatably connected with one side of the auxiliary plate, a moving block is installed on the threaded rod in a threaded manner, the top of the moving block extends out of the production box, a sliding rod is fixedly installed on the inner wall of one side of the production box, one end of the sliding rod is fixedly connected with the auxiliary plate, and the sliding rod is slidably connected with the moving block.

As a further scheme of the utility model, a conveying support is fixedly mounted on the outer wall of one side of the moving block, a material conveying hopper is fixedly mounted on the conveying support, two first hinged supports are fixedly mounted on the material conveying hopper, an electric telescopic rod is hinged to the first hinged supports, two second hinged supports are fixedly mounted on the material conveying hopper, a connecting support is hinged to the second hinged supports, a material blocking plate is fixedly mounted on the connecting support, a connecting rod is hinged to the connecting support, and one end of the connecting rod is fixedly connected with an output shaft of the corresponding electric telescopic rod.

As a further scheme of the utility model, a feeding box is fixedly mounted at the top of the mounting plate, a second rotating motor is fixedly mounted on the outer wall of one side of the feeding box, an auger is fixedly mounted on an output shaft of the second rotating motor, one end of the auger extends into the feeding box and is rotatably connected with the feeding box, a feeding pipe is fixedly mounted on the inner wall of the bottom of the feeding box, and the bottom end of the feeding pipe extends into the weighing tank.

As a further scheme of the utility model, an arc-shaped sliding cavity is formed in the arc-shaped block, a first limiting rod is slidably mounted in the arc-shaped sliding cavity, a short rod is fixedly mounted in the arc-shaped groove, one end of the short rod extends into the arc-shaped sliding cavity, one end of the short rod is fixedly connected with the first limiting rod, a rectangular sliding cavity is formed in the speed limiting block, a second limiting rod is slidably mounted in the rectangular sliding cavity, an L-shaped rod is fixedly mounted on the outer wall of one side of the weighing tank, one end of the L-shaped rod extends into the rectangular sliding cavity, and one end of the L-shaped rod is fixedly connected with the second limiting rod.

Compared with the prior art, the magnesia carbon brick weighing device for avoiding inaccurate metering in the weighing process has the following beneficial effects:

1. according to the utility model, the processing mechanism is arranged, so that the raw material of the magnesia carbon brick can be rapidly pressed and formed, and the effect of processing the raw material of the magnesia carbon brick to enable the raw material of the magnesia carbon brick to be rapidly formed is achieved;

2. according to the utility model, the weighing mechanism is arranged, so that accurate weighing can be realized by controlling the adding speed of the raw materials, and the effect of controlling the adding speed of the raw materials according to the weight of the raw materials to be added in the weighing process is achieved.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is a schematic front sectional view of a magnesia carbon brick weighing apparatus according to the present invention for avoiding inaccurate measurement during the weighing process;

FIG. 2 is an enlarged schematic view of portion A of FIG. 1;

FIG. 3 is an enlarged schematic view of portion B of FIG. 1;

FIG. 4 is an assembly view of the material transporting hopper, the first articulated bracket, the electric telescopic rod, the second articulated bracket, the connecting bracket and the striker plate of the present invention;

FIG. 5 is an assembly view of the lifter plate and the locator rod of the present invention.

In the figure: 1. processing a base; 2. a production box; 3. manufacturing a mould; 4. a support plate; 5. mounting a plate; 6. processing a bracket; 7. a hydraulic cylinder; 8. positioning a plate; 9. pressing into blocks; 10. weighing the tank; 11. a trapezoidal block; 12. a rotating plate; 13. a weighing sensor; 14. a material carrying plate; 15. an arc-shaped groove; 16. an arc-shaped block; 17. an arc toothed plate; 18. a first servo motor; 19. a first gear; 20. a speed limit block; 21. a rectangular toothed plate; 22. a second servo motor; 23. a second gear; 24. a first rotating electric machine; 25. a moving block; 26. a material conveying hopper; 27. a first hinge bracket; 28. a second hinge bracket; 29. connecting a bracket; 30. a second rotating electric machine; 31. an arc-shaped sliding cavity; 32. a rectangular sliding cavity.

Detailed Description

Please refer to fig. 1, fig. 2, fig. 3, fig. 4 and fig. 5 in combination, wherein fig. 1 is a schematic front sectional view of a magnesia carbon brick weighing apparatus for avoiding inaccurate measurement during the weighing process according to the present invention; FIG. 2 is an enlarged schematic view of portion A of FIG. 1; FIG. 3 is an enlarged schematic view of portion B of FIG. 1; FIG. 4 is an assembly view of the material transporting hopper, the first articulated bracket, the electric telescopic rod, the second articulated bracket, the connecting bracket and the striker plate of the present invention; FIG. 5 is an assembly view of the lifter plate and the locator rod of the present invention. The magnesia carbon brick weighing device for avoiding inaccurate metering in the weighing process comprises a processing base 1, wherein a processing mechanism and a weighing mechanism are arranged on the processing base 1; the processing mechanism comprises a production box 2, a manufacturing mold 3, two supporting plates 4, a mounting plate 5, a processing bracket 6, a hydraulic cylinder 7, a lifting plate 8, four positioning rods and a pressing block 9, wherein the production box 2 is fixedly arranged at the top of a processing base 1, the manufacturing mold 3 is fixedly arranged on the production box 2, the two supporting plates 4 are both fixedly arranged at the top of the processing base 1, the mounting plate 5 is fixedly arranged at the tops of the two supporting plates 4, the processing bracket 6 is fixedly arranged on the mounting plate 5, the hydraulic cylinder 7 is fixedly arranged on the inner wall of the top of the processing bracket 6, the lifting plate 8 is fixedly arranged on an output shaft of the hydraulic cylinder 7, the four positioning rods are all fixedly arranged at the bottom of the mounting plate 5, the bottom ends of the positioning rods are fixedly connected with the top of the production box 2, and the positioning rods are in sliding connection with the lifting plate 8, the pressing block 9 is fixedly arranged at the bottom of the lifting plate 8, and the pressing block 9 is matched with the manufacturing die 3;

the weighing mechanism comprises a weighing tank 10, a trapezoidal block 11, a rotating plate 12, a weighing sensor 13, a material carrying plate 14, an arc-shaped groove 15, an arc-shaped block 16, an arc-shaped toothed plate 17, a first servo motor 18 and a first gear 19, wherein the weighing tank 10 is fixedly arranged at the bottom of a mounting plate 5, the trapezoidal block 11 is fixedly arranged on the inner wall of one side of the weighing tank 10, the rotating plate 12 is hinged to the bottom of the trapezoidal block 11, the weighing sensor 13 is fixedly arranged at the top of the rotating plate 12, the material carrying plate 14 is fixedly arranged at the top of the weighing sensor 13, the arc-shaped groove 15 is arranged at the bottom of the trapezoidal block 11, the arc-shaped block 16 is fixedly arranged at the bottom of the rotating plate 12, one side of the arc-shaped block 16 extends into the arc-shaped groove 15 and is in sliding connection with the arc-shaped groove 15, the arc-shaped toothed plate 17 is fixedly arranged on the arc-shaped block 16, the first servo motor 18 is fixedly arranged at the bottom of the trapezoidal block 11, the first gear 19 is fixedly installed on an output shaft of the first servo motor 18, and the first gear 19 is meshed with the arc toothed plate 17.

As shown in fig. 3, a speed-limiting block 20 is slidably mounted on an outer wall of one side of the weighing tank 10, one side of the speed-limiting block 20 extends into the weighing tank 10, an outer wall of one side of the speed-limiting block 20 is in contact with an outer wall of one side of the trapezoidal block 11, a rectangular toothed plate 21 is fixedly mounted at the bottom of the speed-limiting block 20, a second servo motor 22 is fixedly mounted on an outer wall of one side of the weighing tank 10, a second gear 23 is fixedly mounted on an output shaft of the second servo motor 22, and the second gear 23 is engaged with the rectangular toothed plate 21;

the speed-limiting block 20, the rectangular toothed plate 21, the second servo motor 22 and the second gear 23 are matched with each other, so that the speed-limiting block 20 can be indirectly controlled to move through the second servo motor 22, and the problem that the adding speed of the magnesia carbon brick raw material cannot be controlled due to the fact that the speed-limiting block 20 cannot move is avoided.

As shown in fig. 1, an auxiliary plate is fixedly installed in the production tank 2, a first rotating motor 24 is fixedly installed on the outer wall of one side of the production tank 2, a threaded rod is fixedly installed on an output shaft of the first rotating motor 24, one end of the threaded rod extends into the production tank 2 and is rotatably connected with the production tank 2, one end of the threaded rod is rotatably connected with one side of the auxiliary plate, a moving block 25 is installed on the threaded rod in a threaded manner, the top of the moving block 25 extends out of the production tank 2, a sliding rod is fixedly installed on the inner wall of one side of the production tank 2, one end of the sliding rod is fixedly connected with the auxiliary plate, and the sliding rod is slidably connected with the moving block 25;

through the mutual cooperation of accessory plate, first rotation motor 24, threaded rod, movable block 25 and slide bar, form and to drive movable block 25 indirectly through first rotation motor 24 and remove, avoided the unable removal of movable block 25 to lead to unable raw materials in the fortune hopper 26 to be carried to the preparation mould 3 in.

As shown in fig. 1 and 4, a conveying bracket is fixedly mounted on an outer wall of one side of the moving block 25, a material conveying hopper 26 is fixedly mounted on the conveying bracket, two first hinged brackets 27 are fixedly mounted on the material conveying hopper 26, an electric telescopic rod is hinged to the first hinged brackets 27, two second hinged brackets 28 are fixedly mounted on the material conveying hopper 26, a connecting bracket 29 is hinged to the second hinged brackets 28, a material blocking plate is fixedly mounted on the connecting bracket 29, a connecting rod is hinged to the connecting bracket 29, and one end of the connecting rod is fixedly connected with an output shaft of the corresponding electric telescopic rod;

through carry support, fortune hopper 26, first articulated bracket 27, electric telescopic handle, second articulated bracket 28, linking bridge 29, striker plate and connecting rod mutually support, form and to rotate through electric telescopic handle control striker plate, avoided the striker plate unable to rotate and lead to unable raw materials in the fortune hopper 26 to lift off.

As shown in fig. 1, a feeding box is fixedly installed at the top of the installation plate 5, a second rotating motor 30 is fixedly installed on the outer wall of one side of the feeding box, an auger is fixedly installed on an output shaft of the second rotating motor 30, one end of the auger extends into the feeding box and is rotatably connected with the feeding box, a feeding pipe is fixedly installed on the inner wall of the bottom of the feeding box, and the bottom end of the feeding pipe extends into the weighing tank 10;

through pay-off case, second rotation motor 30, auger and inlet pipe mutually support, form and to transport the magnesia carbon brick raw materials in can 10 through second rotation motor 30 control auger phase weighing, avoided adding the raw materials in the unable weighing tank 10 and lead to unable weighing.

As shown in fig. 2 and 3, an arc-shaped sliding cavity 31 is formed in the arc-shaped block 16, a first limiting rod is slidably mounted in the arc-shaped sliding cavity 31, a short rod is fixedly mounted in the arc-shaped groove 15, one end of the short rod extends into the arc-shaped sliding cavity 31, one end of the short rod is fixedly connected with the first limiting rod, a rectangular sliding cavity 32 is formed in the speed limiting block 20, a second limiting rod is slidably mounted in the rectangular sliding cavity 32, an L-shaped rod is fixedly mounted on the outer wall of one side of the weighing tank 10, one end of the L-shaped rod extends into the rectangular sliding cavity 32, and one end of the L-shaped rod is fixedly connected with the second limiting rod;

through the mutual cooperation of the arc-shaped sliding cavity 31, the first limiting rod, the short rod, the rectangular sliding cavity 32, the second limiting rod and the L-shaped rod, the arc-shaped block 16 and the speed limiting block 20 can be limited through the first limiting rod and the second limiting rod, and the phenomenon that the arc-shaped block 16 and the speed limiting block 20 cannot work normally due to the deviation is avoided.

The working principle of the magnesia carbon brick weighing device for avoiding inaccurate metering in the weighing process is as follows:

the first step is as follows: the magnesia carbon brick is required to be weighed, firstly, magnesia carbon brick raw materials are added into a feeding box, then, a second rotating motor 30 is started, the second rotating motor 30 drives an auger to rotate, the auger conveys the magnesia carbon brick raw materials, the raw materials enter a weighing tank 10 through a feeding pipe, at the moment, the weight of the raw materials is not measured by a weighing sensor 13, a second servo motor 22 is controlled to rotate, a second gear 23 is driven by the second servo motor 22 to rotate, the second gear 23 drives a rectangular toothed plate 21 meshed with the second gear to move, the rectangular toothed plate 21 drives a speed limiting block 20 to move towards the direction far away from a trapezoidal block 11, a feeding through hole is formed between the speed limiting block 20 and the trapezoidal block 11, at the moment, the feeding through hole is large, the speed of the raw materials falling onto a material carrying plate 14 is high, along with the continuous addition of the raw materials, the weighing sensor 13 detects that the weight of the raw materials is gradually close to a set value, at the moment, the second servo motor 22 is reversely started, the speed limiting block 20 is close to the trapezoidal block 11 through reverse operation, the feeding port is gradually reduced, the speed of the raw materials falling onto the material carrying plate 14 is gradually reduced, when the weighing sensor 13 detects that the weight of the raw materials meets a set value, the speed limiting block 20 is attached to the trapezoidal block 11, the raw materials are prevented from continuously falling, and errors can be avoided in weighing, so that inaccurate metering is caused;

the second step is as follows: when the magnesia carbon brick raw material needs to be processed, firstly, a first servo motor 18 is started, the first servo motor 18 drives a first gear 19 to rotate, the first gear 19 drives an arc toothed plate 17 to rotate, the arc toothed plate 17 drives an arc block 16 to rotate, the arc block 16 drives a rotating plate 12 to rotate, the rotating plate 12 drives a material carrying plate 14 to rotate, the raw material above the material carrying plate is poured into a conveying hopper 26, after the pouring is completed, a first rotating motor 24 is started, the first rotating motor 24 drives a threaded rod to rotate, the threaded rod drives a moving block 25 to move, the moving block 25 cannot rotate due to the limit of a sliding rod, the moving block 25 drives a conveying support to move, the conveying support drives the conveying hopper 26 to move until the conveying hopper 26 moves to the position right above a manufacturing mold 3, at the moment, two electric telescopic rods are started, the electric telescopic rods retract, and at the moment, the connecting rod pulls a connecting support 29, connecting bracket 29 takes place to rotate, and connecting bracket 29 drives the striker plate and rotates, waits when the striker plate is opened, and its inside raw materials drop to preparation mould 3 in, accomplish and empty the back, and reverse operation makes fortune hopper 26 return, starts pneumatic cylinder 7 this moment, and pneumatic cylinder 7 drives the decline of lifter plate 8, and lifter plate 8 drives briquetting 9 and descends, and briquetting 9 suppresses the raw materials in preparation mould 3, makes its rapid prototyping, accomplishes the processing work.

It should be noted that the device structure and the accompanying drawings of the present invention mainly describe the principle of the present invention, and in the technology of the design principle, the settings of the power mechanism, the power supply system, the control system, and the like of the device are not completely described and clear, and on the premise that the skilled person understands the principle of the utility model, the details of the power mechanism, the power supply system, and the control system can be clearly known, the control mode of the application document is automatically controlled by the controller, and the control circuit of the controller can be realized by simple programming of the skilled person in the art;

the standard parts used in the method can be purchased from the market, and can be customized according to the description of the specification and the accompanying drawings, the specific connection mode of each part adopts conventional means such as mature bolts, rivets, welding and the like in the prior art, the machines, parts and equipment adopt conventional models in the prior art, and the structure and the principle of the parts known by the skilled person can be known by technical manuals or conventional experimental methods.

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, or a direct or indirect use of these embodiments, without departing from the principles and spirit of the utility model, the scope of which is defined in the claims and their equivalents, as used in the related art, and all of which are intended to be encompassed by the present invention.

Claims (6)

1. The utility model provides an avoid causing the inaccurate magnesia carbon brick weighing device of measurement at weighing process which characterized in that includes:

the processing device comprises a processing base, a weighing mechanism and a control device, wherein the processing base is provided with a processing mechanism and a weighing mechanism;

the processing mechanism comprises a production box, a manufacturing die, two supporting plates, a mounting plate, a processing bracket, a hydraulic cylinder, a lifting plate, four positioning rods and a pressing block, the production box is fixedly arranged at the top of the processing base, the manufacturing mould is fixedly arranged on the production box, the two support plates are both fixedly arranged at the top of the processing base, the mounting plate is fixedly arranged on the top of the two supporting plates, the processing bracket is fixedly arranged on the mounting plate, the hydraulic cylinder is fixedly arranged on the inner wall of the top of the processing bracket, the lifting plate is fixedly arranged on an output shaft of the hydraulic cylinder, the four positioning rods are all fixedly arranged at the bottom of the mounting plate, the bottom end of the positioning rod is fixedly connected with the top of the production box, the positioning rod is connected with the lifting plate in a sliding mode, the pressing block is fixedly installed at the bottom of the lifting plate, and the pressing block is matched with the manufacturing mold;

the weighing mechanism comprises a weighing tank, a trapezoidal block, a rotating plate, a weighing sensor, a material carrying plate, an arc-shaped groove, an arc-shaped block, an arc-shaped toothed plate, a first servo motor and a first gear, the weighing tank is fixedly arranged at the bottom of a mounting plate, the trapezoidal block is fixedly arranged on the inner wall of one side of the weighing tank, the rotating plate is hinged to the bottom of the trapezoidal block, the weighing sensor is fixedly arranged at the top of the rotating plate, the material carrying plate is fixedly arranged at the top of the weighing sensor, the arc-shaped groove is formed in the bottom of the trapezoidal block, the arc-shaped block is fixedly arranged at the bottom of the rotating plate, one side of the arc-shaped block extends into the arc-shaped groove and is in sliding connection with the arc-shaped groove, the arc-shaped toothed plate is fixedly arranged on the arc-shaped block, the first servo motor is fixedly arranged at the bottom of the trapezoidal block, and the first gear is fixedly arranged on an output shaft of the first servo motor, the first gear is meshed with the arc toothed plate.

2. The magnesia carbon brick weighing apparatus of claim 1, wherein the apparatus comprises: the weighing tank is characterized in that a speed-limiting block is slidably mounted on the outer wall of one side of the weighing tank, one side of the speed-limiting block extends into the weighing tank, the outer wall of one side of the speed-limiting block is in contact with the outer wall of one side of the trapezoidal block, a rectangular toothed plate is fixedly mounted at the bottom of the speed-limiting block, a second servo motor is fixedly mounted on the outer wall of one side of the weighing tank, a second gear is fixedly mounted on an output shaft of the second servo motor, and the second gear is meshed with the rectangular toothed plate.

3. The magnesia carbon brick weighing apparatus of claim 1, wherein the apparatus comprises: the production box is characterized in that an auxiliary plate is fixedly installed in the production box, a first rotating motor is fixedly installed on the outer wall of one side of the production box, a threaded rod is fixedly installed on an output shaft of the first rotating motor, one end of the threaded rod extends into the production box and is rotatably connected with the production box, one end of the threaded rod is rotatably connected with one side of the auxiliary plate, a moving block is installed on the threaded rod in a threaded mode, the top of the moving block extends out of the production box, a sliding rod is fixedly installed on the inner wall of one side of the production box, one end of the sliding rod is fixedly connected with the auxiliary plate, and the sliding rod is slidably connected with the moving block.

4. The magnesia carbon brick weighing apparatus of claim 3, wherein the apparatus comprises: the movable block comprises a moving block and is characterized in that a conveying support is fixedly mounted on the outer wall of one side of the moving block, a conveying hopper is fixedly mounted on the conveying support, two first hinged supports are fixedly mounted on the conveying hopper, an electric telescopic rod is mounted on the first hinged supports in a hinged mode, two second hinged supports are fixedly mounted on the conveying hopper, a connecting support is mounted on the second hinged supports in a hinged mode, a material blocking plate is fixedly mounted on the connecting support, a connecting rod is mounted on the connecting support in a hinged mode, and one end of the connecting rod is fixedly connected with an output shaft of the corresponding electric telescopic rod.

5. The magnesia carbon brick weighing apparatus of claim 1, wherein the apparatus comprises: the top fixed mounting of mounting panel has the pay-off case, fixed mounting has the second to rotate the motor on the outer wall of one side of pay-off case, fixed mounting has the auger on the output shaft of second rotation motor, the one end of auger extends to in the pay-off case and rotates with the pay-off case to be connected, fixed mounting has the inlet pipe on the bottom inner wall of pay-off case, the bottom of inlet pipe extends to and weighs in the jar.

6. The magnesia carbon brick weighing apparatus for avoiding the metering inaccuracy caused in the weighing process according to claim 2, wherein: the arc-shaped sliding cavity is formed in the arc-shaped block, a first limiting rod is slidably mounted in the arc-shaped sliding cavity, a short rod is fixedly mounted in the arc-shaped groove, one end of the short rod extends into the arc-shaped sliding cavity, one end of the short rod is fixedly connected with the first limiting rod, a rectangular sliding cavity is formed in the speed limiting block, a second limiting rod is slidably mounted in the rectangular sliding cavity, an L-shaped rod is fixedly mounted on the outer wall of one side of the weighing tank, one end of the L-shaped rod extends into the rectangular sliding cavity, and one end of the L-shaped rod is fixedly connected with the second limiting rod.

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