CN213918785U

CN213918785U - In-situ effect castable device convenient for rapid forming

Info

Publication number: CN213918785U
Application number: CN202022791295.2U
Authority: CN
Inventors: 杨强; 李凌; 赵静
Original assignee: Henan Haigeer New Material Co ltd
Current assignee: Henan Haigeer New Material Co ltd
Priority date: 2020-11-27
Filing date: 2020-11-27
Publication date: 2021-08-10
Anticipated expiration: 2030-11-27

Abstract

The utility model discloses an normal position effect castable device convenient to quick shaping, including shell, stand, second recess, reset spring and torque spring, the inboard embedded motor of installing in bottom of shell, and the output of motor is connected with changes the roller, the outside of changeing the roller is fixed with the kicking block, and changes and pass through transmission cingulum interconnect between the roller, the inboard top of shell is connected with the shaping cavity, and the shaping cavity, the embedded motor of installing in the lateral wall middle part of shell, and the output of motor is connected with the threaded rod, the cover is equipped with the lug on the threaded rod, and the lug is fixed in the outside of clamp plate, the threaded rod is connected with the transfer line through the transmission cingulum, and the embedded inboard of installing in the shell bottom of transfer line, the inboard embedded motor of installing of top surface of shell. This normal position effect castable device convenient to quick shaping can carry out the even unloading of ration, can shake the flattening to the material simultaneously.

Description

In-situ effect castable device convenient for rapid forming

Technical Field

The utility model relates to a casting material production auxiliary assembly technical field specifically is a normal position effect castable device convenient to quick shaping.

Background

Half of the refractory materials are divided into shaped refractory materials and unshaped refractory materials, the unshaped refractory materials generally refer to casting materials, the casting materials are mixed powdery or granular particles consisting of a plurality of aggregates or aggregates and one or more binders, and the casting materials are used when refractory bricks are manufactured, however, the existing casting material device with in-situ effect has the following problems:

the castable device of current normal position effect when carrying out the interpolation of material, directly pours the material into the concave membrane usually, easily appears the inhomogeneous phenomenon of material distribution, is not convenient for carry out the even unloading of ration, and simultaneously, the castable device of current normal position effect directly suppresses at the fashioned in-process of material, and the material does not distribute the product quality who levels and lead to the suppression out not high, is not convenient for shake the flattening to the material.

Aiming at the problems, innovative design is urgently needed on the basis of the original castable device with in-situ effect.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a normal position effect castable device convenient to quick shaping to solve the above-mentioned background art and propose the castable device of current normal position effect and be not convenient for carry out the even unloading of ration, be not convenient for simultaneously shake the problem of flattening to the material.

In order to achieve the above object, the utility model provides a following technical scheme: an in-situ effect castable device convenient for rapid forming comprises a shell, a stand column, a second groove, a return spring and a torsion spring, wherein a motor is embedded in the inner side of the bottom of the shell, the output end of the motor is connected with a rotating roller, the rotating roller shaft is connected into the first groove, the first groove is formed in the top of the inner bottom surface of the shell, a top block is fixed on the outer side of the rotating roller, the rotating rollers are mutually connected through a transmission toothed belt, the top of the inner side of the shell is connected with a forming cavity, the motor is embedded in the middle of the side wall of the shell, the output end of the motor is connected with a threaded rod, the threaded rod is connected in a longitudinal groove in a shaft mode, the longitudinal groove is formed in the inner side wall of the shell, a lug is sleeved on the threaded rod and fixed on the outer side of a pressing plate, the pressing plate is positioned above the forming cavity, and the threaded rod is connected with a transmission rod through the transmission toothed belt, the transmission rod is embedded in the inner side of the bottom of the shell and connected with the transmission rod on the other side through the transmission toothed belt, the motor is embedded in the inner side of the top surface of the shell, the output end of the motor is connected with the rotating plate, the rotating plate is located in the material box, the material box is installed at the bottom of the top surface of the inner side of the shell, the bottom of the rotating plate is fixed with the pushing block, the outer side of the pushing block is connected with the baffle, the middle of the baffle is sleeved with the shaft rod in a penetrating mode, the shaft rod is connected in the blanking port in a shaft mode, the blanking port is formed in the bottom of the material box, and one end of the shaft rod is provided with the torsion spring.

Preferably, the jacking blocks are distributed on the outer side of the rotary roller at equal angles, and the rotary roller is rotatably connected with the first groove.

Preferably, the stand is installed to the bottom of shaping cavity, and the stand is connected in the second recess to the top of shell inboard bottom surface is seted up to the second recess, is connected with reset spring moreover between second recess and the stand.

Preferably, the upright column is designed into a T-shaped structure, and an elastic movable structure is formed between the upright column and the second groove through the return spring.

Preferably, the end part of the push block is designed to be of a hemispherical structure, and the position of the push block corresponds to the position of the baffle one by one.

Preferably, the baffle is designed to be a circular structure, the diameter of the baffle is larger than the width of the blanking port, and the baffle passes through a shaft lever and a rotating structure formed between the torsion spring and the blanking port.

Compared with the prior art, the beneficial effects of the utility model are that: the in-situ effect castable device convenient for rapid forming;

1. through the arrangement of the rotating plate, the pushing block, the baffle, the shaft rod, the blanking port and the torsion spring, the pushing block can be driven to synchronously move after the rotating plate rotates, the pushing block can generate thrust on the baffle, the baffle can rotate around the shaft rod to reversely rotate the torsion spring, the blanking port is opened to enable the material to fall, and then the baffle can be closed again under the elastic action of the torsion spring to close the blanking port, so that the quantitative uniform falling of the material is realized;

2. through the roller that changes, kicking block, first recess, shaping cavity, stand, second recess and reset spring that set up for change the roller and rotate the back at first recess, will make the kicking block bump the bottom of shaping cavity, and then make the shaping cavity produce vibrations, the stand of shaping cavity bottom can compress reset spring and produce the removal in the second recess simultaneously, and then will introduce into the material that goes out in the shaping cavity and shake the flattening, convenient follow-up processing.

Drawings

FIG. 1 is a schematic view of the overall front cut structure of the present invention;

FIG. 2 is a schematic view of the overall structure of the present invention;

FIG. 3 is a schematic view of the top view structure of the molding cavity of the present invention;

FIG. 4 is a schematic top view of the baffle of the present invention;

fig. 5 is a schematic view of the top view structure of the push block of the present invention.

In the figure: 1. a housing; 2. a motor; 3. rotating the roller; 4. a first groove; 5. a top block; 6. a drive toothed belt; 7. forming a cavity; 8. a column; 9. a second groove; 10. a return spring; 11. a threaded rod; 12. a longitudinal groove; 13. a lug; 14. pressing a plate; 15. a transmission rod; 16. rotating the plate; 17. a material box; 18. a push block; 19. a baffle plate; 20. a shaft lever; 21. a blanking port; 22. a torsion spring.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: an in-situ effect castable device convenient for rapid forming comprises a shell 1, a motor 2, a rotating roller 3, a first groove 4, a top block 5, a transmission toothed belt 6, a forming cavity 7, a stand column 8, a second groove 9, a return spring 10, a threaded rod 11, a longitudinal groove 12, a lug 13, a pressing plate 14, a transmission rod 15, a rotating plate 16, a material box 17, a pushing block 18, a baffle 19, a shaft rod 20, a blanking port 21 and a torsion spring 22, wherein the motor 2 is embedded in the inner side of the bottom of the shell 1, the output end of the motor 2 is connected with the rotating roller 3, the rotating roller 3 is axially connected in the first groove 4, the first groove 4 is arranged at the top of the bottom surface of the inner side of the shell 1, the top block 5 is fixed on the outer side of the rotating roller 3, the rotating rollers 3 are mutually connected through the transmission toothed belt 6, the top of the inner side of the shell 1 is connected with the forming cavity 7, the forming cavity 7 is arranged in the middle of the side wall of the shell 1, the motor 2 is embedded in the middle of the side wall of the shell 1, the output end of the motor 2 is connected with a threaded rod 11, the threaded rod 11 is connected in a longitudinal groove 12 in a shaft mode, the longitudinal groove 12 is formed in the inner side wall of the shell 1, a lug 13 is sleeved on the threaded rod 11, the lug 13 is fixed on the outer side of the pressing plate 14, the pressing plate 14 is located above the forming cavity 7, the threaded rod 11 is connected with a transmission rod 15 through a transmission toothed belt 6, the transmission rod 15 is installed on the inner side of the bottom of the shell 1 in an embedded mode, the transmission rod 15 is connected with a transmission rod 15 on the other side through the transmission toothed belt 6, the motor 2 is installed on the inner side of the top surface of the shell 1 in an embedded mode, the output end of the motor 2 is connected with a rotating plate 16, the rotating plate 16 is located in a material box 17, the material box 17 is installed on the bottom of the inner side of the top surface of the shell 1, a push block 18 is fixed at the bottom of the rotating plate 16, a baffle plate 19 is connected on the outer side of the push block 18, and a shaft rod 20 penetrates through the middle of the baffle plate 19, the shaft rod 20 is connected in the blanking port 21 in a shaft mode, the blanking port 21 is arranged at the bottom of the material box 17, and a torsion spring 22 is installed at one end of the shaft rod 20.

The jacking blocks 5 are distributed on the outer side of the rotary roller 3 at equal angles, and the rotary roller 3 is rotatably connected with the first groove 4, so that after the rotary roller 3 rotates in the first groove 4, the jacking blocks 5 can rotate along with the rotary roller, and further generate vibration on the forming cavity 7;

an upright post 8 is installed at the bottom of the forming cavity 7, the upright post 8 is connected in a second groove 9, the second groove 9 is formed in the top of the bottom surface of the inner side of the shell 1, and a return spring 10 is connected between the second groove 9 and the upright post 8, so that when the forming cavity 7 vibrates, the upright post 8 moves in the second groove 9, the return spring 10 is extruded, and the vibration amplitude is reduced;

the upright post 8 is designed into a T-shaped structure, and the upright post 8 forms an elastic movable structure with the second groove 9 through the return spring 10, so that the upright post 8 cannot be separated from the second groove 9 when sliding in the second groove 9;

the end part of the push block 18 is designed to be a hemispherical structure, and the positions of the push block 18 and the position of the baffle 19 correspond to each other one by one, so that when the push block 18 is in contact with the baffle 19, the baffle 19 only moves along the arc-shaped edge without being blocked;

the baffle 19 is designed to be circular structure, and the diameter of baffle 19 is greater than the width of blanking mouth 21 to baffle 19 passes through the axostylus axostyle 20 and constitutes revolution mechanic between torsion spring 22 and the blanking mouth 21, makes baffle 19 when rotating, can drive axostylus axostyle 20 reversal torsion spring 22 and open blanking mouth 21, can close blanking mouth 21 when not changeing.

The working principle is as follows: in using the in-situ effect castable apparatus to facilitate rapid prototyping, as shown in fig. 1 and 3-5, first, after loading material into the material tank 17, when the motor 2 on the inner side of the top surface of the shell 1 is started, the motor 2 drives the rotating plate 16 to rotate in the material box 17, and when the rotating plate 16 rotates, the push block 18 arranged at the bottom of the rotating plate 16 can synchronously rotate, the push block 18 can be extruded and pushed with the baffle plate 19 in the rotating process, so that the baffle 19 rotates around the shaft 20 in the blanking port 21, and the reversing torsion spring 22 opens the blanking port 21, the material falls out of the blanking port 21, the torsion spring 22 drives the baffle 19 to recover under the action of the elastic force after the push block 18 passes through, the blanking port 21 is further closed, so that the equivalent uniform falling of the materials is realized, the falling materials can enter the die cavity of the molding cavity 7, and the processing of a plurality of bricks can be synchronously performed;

as shown in fig. 1-2, when the material falls into the cavity of the molding cavity 7, the motor 2 in the sidewall of the housing 1 is started, the motor 2 drives the threaded rod 11 to rotate, the threaded rod 11 drives the transmission rod 15 to rotate through the transmission toothed belt 6 after rotating, the transmission rod 15 drives the threaded rod 11 on the other side to rotate through the transmission toothed belt 6, so that the lug 13 moves in the longitudinal groove 12, the pressing plate 14 is driven to move forward, the movement is stopped after moving above the molding cavity 7, then the motor 2 on the inner side of the bottom of the housing 1 is started, the motor 2 drives the rotating rollers 3 to rotate, the rotating rollers 3 are connected with each other through the transmission toothed belt 6, the top block 5 synchronously rotates after the rotating rollers 3, the top block 5 impacts the molding cavity 7, so that the molding cavity 7 vibrates, and the upright post 8 also compresses the return spring 10 in the second groove 9 to move, thereby reduce the vibrations range, and shake the flattening to the material in the shaping cavity 7 for the fragment of brick quality of squeezing out is better.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims

1. The utility model provides an in situ effect castable device convenient to rapid prototyping, includes shell (1), stand (8), second recess (9), reset spring (10) and torsion spring (22), its characterized in that: the motor (2) is installed in an embedded mode on the inner side of the bottom of the shell (1), the output end of the motor (2) is connected with the rotating roller (3), the rotating roller (3) is connected into the first groove (4) in an axial mode, the first groove (4) is formed in the top of the inner bottom face of the shell (1), a top block (5) is fixed on the outer side of the rotating roller (3), the rotating roller (3) is connected with the rotating roller through a transmission toothed belt (6) in an interconnecting mode, the inner top of the shell (1) is connected with a forming cavity (7) and the forming cavity (7), the motor (2) is installed in the middle of the side wall of the shell (1) in an embedded mode, the output end of the motor (2) is connected with a threaded rod (11), the threaded rod (11) is connected into a longitudinal groove (12) in an axial mode, the longitudinal groove (12) is formed in the inner side wall of the shell (1), and a lug (13) is sleeved on the threaded rod (11), the lug (13) is fixed on the outer side of the pressing plate (14), the pressing plate (14) is positioned above the forming cavity (7), the threaded rod (11) is connected with a transmission rod (15) through a transmission toothed belt (6), the transmission rod (15) is installed on the inner side of the bottom of the shell (1) in an embedded mode, the transmission rod (15) is connected with the transmission rod (15) on the other side through the transmission toothed belt (6), the motor (2) is installed on the inner side of the top surface of the shell (1) in an embedded mode, the output end of the motor (2) is connected with a rotating plate (16), the rotating plate (16) is located in the material box (17), the material box (17) is installed on the bottom of the inner top surface of the shell (1), a pushing block (18) is fixed on the bottom of the rotating plate (16), a baffle plate (19) is connected to the outer side of the pushing block (18), and a shaft lever (20) penetrates through the middle of the baffle plate (19), the shaft lever (20) is connected with the blanking port (21) in a shaft mode, the blanking port (21) is formed in the bottom of the material box (17), and a torsion spring (22) is installed at one end of the shaft lever (20).

2. An in-situ effect castable device to facilitate rapid prototyping according to claim 1 wherein: the ejecting blocks (5) are distributed on the outer side of the rotating roller (3) at equal angles, and the rotating roller (3) is rotatably connected with the first groove (4).

3. An in-situ effect castable device to facilitate rapid prototyping according to claim 1 wherein: stand (8) are installed to the bottom of shaping cavity (7), and stand (8) are connected in second recess (9), and second recess (9) are seted up at the top of shell (1) inboard bottom surface, are connected with reset spring (10) in addition between second recess (9) and stand (8).

4. An in-situ effect castable device to facilitate rapid prototyping according to claim 3 wherein: the upright post (8) is designed into a T-shaped structure, and the upright post (8) forms an elastic movable structure with the second groove (9) through a return spring (10).

5. An in-situ effect castable device to facilitate rapid prototyping according to claim 1 wherein: the end part of the push block (18) is designed to be of a hemispherical structure, and the positions of the push block (18) correspond to the positions of the baffle plates (19) one by one.

6. An in-situ effect castable device to facilitate rapid prototyping according to claim 1 wherein: the baffle (19) is designed to be a circular structure, the diameter of the baffle (19) is larger than the width of the blanking port (21), and the baffle (19) forms a rotating structure with the blanking port (21) through the shaft lever (20) and the torsion spring (22).