CN219076020U - Mud injection structure for ceramic production - Google Patents

Abstract

The utility model relates to the technical field of ceramic production and discloses a mud injection structure for ceramic production, which comprises a support, wherein a support ring is fixedly arranged at the top end of the support, a stirring bin is fixedly sleeved in an inner cavity of the support ring, a first servo motor is fixedly arranged at the top end of the stirring bin, a stirring roller is fixedly sleeved on an output shaft of the first servo motor, a first cylinder is fixedly arranged at the top end of the stirring bin, and a raw material baffle is fixedly sleeved on an output shaft of the first cylinder. According to the utility model, the servo motor drives the stirring roller to rotate so as to uniformly mix the slurry raw materials, and then the slurry raw materials are input into the inner cavity of the ceramic die through the feeding pipe, so that the raw materials are automatically proportioned and uniformly mixed and then directly input into the inner cavity of the ceramic die, the condition that the slurry is sunk is avoided, the complicated step that the proportioning is needed in advance manually is avoided, and the labor intensity of the manual work is effectively reduced.

Description

Mud injection structure for ceramic production

Technical Field

The utility model relates to the technical field of ceramic production, in particular to a mud injection structure for ceramic production.

Background

In the prior art, ceramic slurry is required to be injected into a mold firstly, then ceramic is obtained through subsequent processing, the slurry is poured into a slurry injection device, then the slurry is injected into the mold through the slurry injection device, but after the slurry is put into the slurry injection device, the slurry can be settled due to static state, so that the quality of the ceramic can be influenced, various raw materials of the ceramic slurry are required to be mixed uniformly in advance manually, and then the ceramic slurry is input into the slurry injection device, but the slurry injection can be carried out only after the ceramic slurry is required to be mixed uniformly in advance manually, so that the labor intensity of the labor is increased, and the efficiency of ceramic slurry injection is reduced.

Disclosure of Invention

In order to overcome the defects in the prior art, the utility model provides a mud injection structure for ceramic production, which has the advantages of reducing the labor intensity and improving the mud injection efficiency of ceramics.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a annotate mud structure that ceramic manufacture used, includes the support, the top fixed mounting of support has the holding ring, the fixed cover in inner chamber of holding ring is equipped with the stirring storehouse, the top fixed mounting of stirring storehouse has servo motor one, the fixed cover of output shaft of servo motor one is equipped with the stirring roller, the top fixed mounting of stirring storehouse has cylinder one, the fixed cover of output shaft of cylinder one is equipped with the raw materials baffle, the surface swing joint of raw materials baffle has the raw materials storehouse, the top fixed mounting of raw materials storehouse has the pan feeding pipe, the bottom fixedly connected with ejection of compact hose of stirring storehouse, the right side fixed mounting of support has servo motor two, the fixed cover of output shaft of servo motor two is equipped with the drive roller, the surface activity of drive roller has cup jointed the conveyer belt, ceramic mold has been placed on the surface of conveyer belt.

As a preferable technical scheme of the utility model, a second air cylinder is fixedly arranged on the left side and the right side of the bracket, a connecting rod is fixedly sleeved on an output shaft of the second air cylinder, a third air cylinder is fixedly arranged on the top end of the connecting rod, a discharging baffle is fixedly sleeved on the output shaft of the third air cylinder, a material injection pipe is movably connected to the outer surface of the discharging baffle, and supporting feet are fixedly arranged at the bottom end of the bracket.

As a preferable technical scheme of the utility model, the stirring bin is a cylindrical cavity, a round hole is formed in the bottom end of the stirring bin, and the discharging hose is fixedly connected to the round hole in the bottom end of the stirring bin.

As a preferable technical scheme of the utility model, sliding grooves are formed in the left side and the right side of the inner cavity of the raw material bin, and the left end and the right end of the raw material baffle are movably connected with the sliding grooves of the raw material bin.

As a preferable technical scheme of the utility model, the two cylinders II are provided, the connecting rod consists of connecting blocks at the left end and the right end and a round rod fixedly connected with a cylinder base in the middle, the cylinder III is fixedly arranged at the top end of the cylinder base in the middle of the connecting rod, and the left end and the right end of the connecting rod are respectively fixedly sleeved on output shafts of the two cylinders II.

As a preferable technical scheme of the utility model, grooves are formed in the front side and the rear side of the inner cavity of the material injection pipe, the front end and the rear end of the material discharge baffle are movably connected with the grooves of the material injection pipe, and the top end of the material injection pipe is fixedly connected with the material discharge hose.

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

1. according to the utility model, the first air cylinder drives the raw material baffle to leave the inner cavity of the raw material bin, so that raw materials fall into the inner cavity of the stirring bin, after the added raw materials reach the required proportion, the air cylinder drives the raw material baffle to return into the inner cavity of the raw material bin, so that the raw materials are blocked in the inner cavity of the raw material bin, the proportion of the raw materials is controlled, then the servo motor drives the stirring roller to rotate, the slurry raw materials are uniformly mixed, and then the slurry raw materials are input into the inner cavity of the ceramic die through the feeding pipe, so that the automatic proportioning and uniform mixing of the raw materials are realized, the raw materials are directly input into the inner cavity of the ceramic die, the occurrence of sinking of slurry is avoided, the complicated step of manually needing to be proportioned in advance is avoided, and the labor intensity of manpower is effectively reduced.

2. According to the utility model, the connecting rod is driven to pull the discharging hose to move downwards by starting the operation of the air cylinder II, so that the bottom end of the material injection pipe is positioned in the inner cavity of the ceramic mold, then the discharging baffle is driven to leave the inner cavity of the material injection pipe by starting the air cylinder III, so that slurry in the material injection pipe is injected into the ceramic mold, and then the material injection pipe is driven to slowly rise by the air cylinder II, so that the slurry is slowly injected from the bottom end of the inner cavity of the ceramic mold, the condition that the quality of the ceramic is influenced by bubbles generated when the slurry is injected into the ceramic mold is avoided, and the slurry is prevented from being spilled outside the ceramic mold.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic diagram of the connection of the stirring bin with the structure of the utility model;

FIG. 3 is an enlarged schematic view of the structure of the present utility model at A in FIG. 2;

FIG. 4 is a schematic view of the connection of the discharging hose of the structure of the present utility model;

FIG. 5 is a schematic view of a ceramic mold of the present utility model.

In the figure: 1. a bracket; 2. a support ring; 3. a stirring bin; 4. a servo motor I; 5. a stirring roller; 6. A first cylinder; 7. a raw material baffle; 8. a raw material bin; 9. a feeding pipe; 10. a discharge hose; 11. a servo motor II; 12. a driving roller; 13. a conveyor belt; 14. a ceramic mold; 15. a second cylinder; 16. a connecting rod; 17. a third cylinder; 18. a discharging baffle; 19. a material injection pipe; 20. and supporting the feet.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 5, the utility model provides a mud injection structure for ceramic production, which comprises a support 1, wherein a support ring 2 is fixedly arranged at the top end of the support 1, a stirring bin 3 is fixedly sleeved in an inner cavity of the support ring 2, a first servo motor 4 is fixedly arranged at the top end of the stirring bin 3, a stirring roller 5 is fixedly sleeved on an output shaft of the first servo motor 4, a first cylinder 6 is fixedly arranged at the top end of the stirring bin 3, a raw material baffle 7 is fixedly sleeved on an output shaft of the first cylinder 6, a raw material bin 8 is movably connected to the surface of the raw material baffle 7, a feeding pipe 9 is fixedly arranged at the top end of the raw material bin 8, a discharging hose 10 is fixedly connected to the bottom end of the stirring bin 3, a second servo motor 11 is fixedly arranged at the right side of the support 1, a driving roller 12 is fixedly sleeved on an output shaft of the second servo motor 11, a conveying belt 13 is movably sleeved on the surface of the driving roller 12, and a ceramic die 14 is placed on the surface of the conveying belt 13;

the method comprises the steps of inputting various raw materials of slurry into the inner cavity of a raw material bin 8 through a feeding pipe 9, starting the operation of a first cylinder 6, driving a raw material baffle 7 to move along the axis direction of the first cylinder 6 through the operation of the first cylinder 6, enabling the raw materials to fall into the inner cavity of a stirring bin 3 through the movement of the raw material baffle 7, after the raw materials are added to reach a required proportion, driving the raw material baffle 7 to return into the inner cavity of the raw material bin 8 through the first cylinder 6, blocking the raw materials in the inner cavity of the raw material bin 8, controlling the proportion of the raw materials, then starting the operation of a second servo motor 4, driving a stirring roller 5 on an output shaft of the second servo motor 4 to rotate through the operation of the first servo motor 4, uniformly mixing the slurry through the rotation of the stirring roller 5, then discharging a discharging hose 10 at the bottom of the stirring bin 3 to the inner cavity of a ceramic die 14, after the slurry in the ceramic die 14 is filled, driving the discharging baffle 18 to the inner cavity of the feeding pipe 19 through the third cylinder 17, stopping the feeding, then starting the operation of the second servo motor 11, driving the rotation of an output shaft 12 on the second servo motor 11, driving the second servo motor to rotate through the driving roller 12 on the output shaft of the second servo motor 11, driving the driving roller 12 to rotate, and driving the ceramic die 14 to rotate through a driving roller 13 to be in rotary connection with a driving belt 13, and driving the ceramic die 14 to rotate, thereby carrying the ceramic die 14, and carrying out rotation;

the raw material baffle 7 is operated through the first cylinder 6 to leave the inner cavity of the raw material bin 8, so that raw materials fall into the inner cavity of the stirring bin 3, after the raw materials are added to reach the required proportion, the first cylinder 6 drives the raw material baffle 7 to return into the inner cavity of the raw material bin 8, so that raw materials are blocked in the inner cavity of the raw material bin 8, the first servo motor 4 drives the stirring roller 5 to rotate to uniformly mix slurry raw materials, and then the slurry raw materials are input into the inner cavity of the ceramic die 14 through the feeding pipe 9, so that automatic proportioning and uniform mixing of the raw materials are realized, the raw materials are directly input into the inner cavity of the ceramic die 14, the occurrence of sinking of slurry is avoided, the complicated step of manually needing to be proportioned in advance is avoided, and the labor intensity is effectively reduced.

The left side and the right side of the bracket 1 are fixedly provided with a second air cylinder 15, an output shaft of the second air cylinder 15 is fixedly sleeved with a connecting rod 16, the top end of the connecting rod 16 is fixedly provided with a third air cylinder 17, the output shaft of the third air cylinder 17 is fixedly sleeved with a discharging baffle 18, the outer surface of the discharging baffle 18 is movably connected with a material injection pipe 19, and the bottom end of the bracket 1 is fixedly provided with supporting feet 20;

the cylinder II 15 is started to operate, the connecting rod 16 on the output shaft of the cylinder II 15 is driven to move along the axial direction of the cylinder II 15, the discharging hose 10 is pulled to move downwards through the movement of the connecting rod 16, so that the bottom end of the feeding pipe 19 is positioned in the inner cavity of the ceramic mold 14, then the cylinder III 17 is started to operate, the discharging baffle 18 on the output shaft of the cylinder III 17 is driven to move along the axial direction of the cylinder III 17, so that the discharging baffle 18 is separated from the inner cavity of the feeding pipe 19, slurry in the feeding pipe 19 is injected into the ceramic mold 14, and then the cylinder II 15 drives the feeding pipe 19 to slowly rise;

the second starting cylinder 15 is operated to drive the connecting rod 16 to pull the discharging hose 10 to move downwards, so that the bottom end of the feeding pipe 19 is located in the inner cavity of the ceramic die 14, then the third starting cylinder 17 is used to drive the discharging baffle 18 to leave the inner cavity of the feeding pipe 19, so that slurry in the feeding pipe 19 is injected into the ceramic die 14, and then the second starting cylinder 15 is used to drive the feeding pipe 19 to slowly rise, so that slurry is slowly injected from the bottom end of the inner cavity of the ceramic die 14, the condition that bubbles generated when the slurry is injected into the ceramic die 14 affect the quality of the ceramic is avoided, and the slurry is prevented from being spilled outside the ceramic die 14.

Wherein, the stirring bin 3 is a cylindrical cavity, the bottom end of the stirring bin 3 is provided with a round hole, and the discharging hose 10 is fixedly connected with the round hole at the bottom end of the stirring bin 3;

the first servo motor 4 is started to rotate, the raw materials are uniformly mixed through the rotation of the first servo motor 4, and then the mixed raw materials in the stirring bin 3 are discharged through the discharging hose 10;

the stirring bin 3 is a cylindrical cavity, so that the first servo motor 4 drives the stirring roller 5 to rotate to stir slurry in the stirring bin 3, and the slurry is discharged through the discharging hose 10 through a round hole at the bottom end of the stirring bin 3.

The left and right sides of the inner cavity of the raw material bin 8 are provided with sliding grooves, and the left and right ends of the raw material baffle 7 are movably connected with the sliding grooves of the raw material bin 8;

the first cylinder 6 is started to drive the raw material baffle 7 to move, so that the raw material baffle 7 enters or leaves the inner cavity of the raw material bin 8, and the control of the mud raw material blanking proportion is realized;

through the spout of former feed bin 8 for both ends can contact with the spout of former feed bin 8 about the raw materials baffle 7, thereby make the raw materials when the raw materials baffle 7 is plugging up the raw materials, can not take place the skew because the weight extrusion of raw materials leads to the raw materials baffle 7.

The two cylinders II 15 are arranged in total, the connecting rod 16 consists of connecting blocks at the left end and the right end and a round rod with a cylinder base in the middle, the cylinder III 17 is fixedly arranged at the top end of the cylinder base in the middle of the connecting rod 16, and the left end and the right end of the connecting rod 16 are respectively fixedly sleeved on output shafts of the two cylinders II 15;

by starting the operation of the air cylinder III 17, the discharge baffle 18 on the output shaft of the air cylinder III 17 is driven to move along the axial direction of the air cylinder III 17, so that the discharge baffle 18 is separated from the inner cavity of the injection pipe 19, slurry in the injection pipe 19 is injected into the ceramic mold 14, and then the air cylinder II 15 drives the injection pipe 19 to slowly rise;

the second cylinder 15 drives the connecting rod 16 to pull the discharging hose 10 to move downwards, so that the bottom end of the feeding pipe 19 is located in the inner cavity of the ceramic die 14, then the third cylinder 17 is started to drive the discharging baffle 18 to leave the inner cavity of the feeding pipe 19, so that slurry in the feeding pipe 19 is injected into the ceramic die 14, and then the second cylinder 15 drives the feeding pipe 19 to slowly rise, so that slurry is slowly injected from the bottom end of the inner cavity of the ceramic die 14, the condition that bubbles generated when the slurry is injected into the ceramic die 14 affect the quality of ceramic is avoided, and the slurry is prevented from being spilled outside the ceramic die 14.

The front and rear ends of the discharging baffle 18 are movably connected with the grooves of the feeding pipe 19, and the top end of the feeding pipe 19 is fixedly connected with the discharging hose 10;

the third cylinder 17 is started to drive the discharge baffle 18 to move, so that the discharge baffle 18 leaves or enters the inner cavity of the injection pipe 19, and mud is fed into the inner cavity of the ceramic die 14;

the front end and the rear end of the discharge baffle 18 are movably connected in the groove of the injection pipe 19, so that the discharge baffle 18 is supported, the discharge baffle 18 is prevented from being deviated due to extrusion of slurry, and the slurry falls into the injection pipe 19 through the discharge hose 10 and finally is injected into the inner cavity of the ceramic die 14.

The working principle and the using flow of the utility model are as follows: various raw materials of slurry are input into the inner cavity of the raw material bin 8 through a feeding pipe 9, then the first cylinder 6 is started to operate, the raw material baffle 7 is driven to move along the axial direction of the first cylinder 6 through the operation of the first cylinder 6, the raw material baffle 7 is moved away from the inner cavity of the raw material bin 8, so that the raw materials fall into the inner cavity of the stirring bin 3, after the raw materials are added to reach a required proportion, the raw material baffle 7 is driven to return into the inner cavity of the raw material bin 8 through the first cylinder 6, so that the raw materials are blocked in the inner cavity of the raw material bin 8, and the control of the proportion of the raw materials is realized;

then the first servo motor 4 is started to operate, the stirring roller 5 on the output shaft of the first servo motor 4 is driven to rotate by the operation of the first servo motor, the stirring roller 5 rotates to uniformly mix the slurry, and then the uniformly mixed slurry is discharged into the material injection pipe 19 through the discharging hose 10 at the bottom of the stirring bin 3;

then starting the operation of the second cylinder 15, driving a connecting rod 16 on an output shaft of the second cylinder 15 to move along the axial direction of the second cylinder 15, pulling a discharge hose 10 to move downwards through the movement of the connecting rod 16, so that the bottom end of a material injection pipe 19 is positioned in the inner cavity of a ceramic mold 14, then driving a discharge baffle 18 on the output shaft of the second cylinder 17 to move along the axial direction of the third cylinder 17 through the operation of the third cylinder 17, so that the discharge baffle 18 is separated from the inner cavity of the material injection pipe 19, and then injecting slurry in the material injection pipe 19 into the ceramic mold 14, and driving the material injection pipe 19 to slowly rise through the second cylinder 15;

after the slurry in the ceramic die 14 is filled, the third cylinder 17 is started again to drive the discharge baffle 18 to move to the inner cavity of the material injection pipe 19, so that the slurry discharging is stopped, the second servo motor 11 is started to operate to drive the driving roller 12 on the output shaft of the second servo motor to rotate through the operation of the second servo motor 11, the conveying belt 13 is movably connected with the second servo motor through the rotation of the driving roller 12 to rotate, and the ceramic die 14 is driven to move through the rotation of the conveying belt 13, so that the ceramic die 14 is transported.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein 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. The utility model provides a annotate mud structure that ceramic manufacture used, includes support (1), its characterized in that: the utility model discloses a ceramic mould, including support (1), stirring storehouse (3), servo motor (4), driving roller (12), conveyer belt (13) have been cup jointed to the fixed cover of output shaft of servo motor (4), ceramic mould (14) have been placed on the surface of conveyer belt (13), raw materials baffle (7) are equipped with to the fixed cover in top of support (1), stirring storehouse (3) are equipped with to the fixed cover in inner chamber of support (1), stirring storehouse (3) are equipped with to the inner chamber of support (2), servo motor (4) are equipped with to the fixed cover in top of stirring storehouse (3), driving roller (5) are equipped with to the fixed cover of output shaft of servo motor (4), raw materials baffle (7) are equipped with to the fixed cover of output shaft of cylinder (6), feeding pipe (9) are equipped with to the surface swing joint of raw materials baffle (7), feeding pipe (9) are equipped with to the top of raw materials storehouse (8), the bottom fixedly connected with ejection of stirring storehouse (3), servo motor (11) are equipped with the right side fixedly of support (1), driving roller (12) are equipped with the fixed cover of output shaft of servo motor (11).

2. The cement injection structure for ceramic production according to claim 1, wherein: the left and right sides fixed mounting of support (1) has cylinder two (15), the fixed cover of output shaft of cylinder two (15) is equipped with connecting rod (16), the top fixed mounting of connecting rod (16) has cylinder three (17), the fixed cover of output shaft of cylinder three (17) is equipped with ejection of compact baffle (18), the surface swing joint of ejection of compact baffle (18) has notes material pipe (19), the bottom fixed mounting of support (1) has supporting legs (20).

3. The cement injection structure for ceramic production according to claim 1, wherein: the stirring bin (3) is a cylindrical cavity, a round hole is formed in the bottom end of the stirring bin (3), and the discharging hose (10) is fixedly connected to the round hole at the bottom end of the stirring bin (3).

4. The cement injection structure for ceramic production according to claim 1, wherein: the left and right sides of former feed bin (8) inner chamber has seted up the spout, the left and right sides both ends and the spout swing joint of former feed bin (8) of raw materials baffle (7).

5. A cement injection structure for ceramic manufacture according to claim 2, wherein: the two cylinders (15) are shared, the connecting rod (16) consists of a connecting block at the left end and the right end and a round rod fixedly connected with a cylinder base in the middle, the cylinder III (17) is fixedly arranged at the top end of the cylinder base in the middle of the connecting rod (16), and the left end and the right end of the connecting rod (16) are fixedly sleeved on output shafts of the two cylinders (15) respectively.

6. A cement injection structure for ceramic manufacture according to claim 2, wherein: grooves are formed in the front side and the rear side of the inner cavity of the material injection pipe (19), the front end and the rear end of the material discharge baffle (18) are movably connected with the grooves of the material injection pipe (19), and the top end of the material injection pipe (19) is fixedly connected with the material discharge hose (10).

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