CN220903642U - Automatic production device for small prefabricated parts - Google Patents

Abstract

The utility model discloses an automatic production device for small prefabricated components, which belongs to the technical field of concrete components and comprises a guide rail frame, wherein a feeding vehicle is arranged at the upper part of the guide rail frame in a rolling way, a feeding machine is fixedly connected to the lower end of the feeding vehicle, a conveyor is arranged at the lower side of the guide rail frame, a box-shaped die is arranged at the upper end of the conveyor, an elastic seat is fixedly connected to the outer part of one side of the conveyor, the elastic seat is rotationally connected with a turning plate, the elastic seat is symmetrically arranged at the side part of the turning plate, when the feeding machine is positioned at the upper side of the box-shaped die, the feeding machine is used for feeding materials into the box-shaped die, after the box-shaped die is filled with the feeding machine, the turning plate is driven to be opened upwards by a first reducing motor, the box-shaped die is moved to the front part of the conveyor by the conveyor, the turning plate is driven by the first reducing motor to cover the box-shaped die, the materials in the box-shaped die are flattened by vibration of a vibrating machine, and automatic shaping of the components is facilitated.

Description

Automatic production device for small prefabricated parts

Technical Field

The utility model belongs to the technical field of concrete members, and particularly relates to an automatic production device for small prefabricated members.

Background

Concrete refers to a generic term for engineering composite materials in which aggregate is consolidated into a whole by a cementitious material. The term concrete generally refers to cement as a cementing material, sand and stone as aggregate; the cement concrete, also called ordinary concrete, obtained by mixing with water (which can contain additives and admixtures) according to a certain proportion is widely applied to civil engineering, and the small-sized prefabricated part is mainly made of concrete.

The traditional small-sized prefabricated part is mainly formed by putting materials into a die manually and flattening the materials in a manual mode, so that the problem that the traditional small-sized prefabricated part is troublesome is caused.

For this reason, we propose a small-sized prefabricated part automated production device to solve the above-mentioned problems.

Disclosure of utility model

The utility model aims to solve the problem that the traditional small prefabricated parts are troublesome, and provides a small prefabricated part automatic production device.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

The utility model provides a small-size prefabricated component automated production device, includes the guide rail frame, the upper portion roll-mounting of guide rail frame has the feed car, the lower extreme fixedly connected with batcher of feed car, the downside of guide rail frame is equipped with the conveyer, box-shaped mould has been put to the upper end of conveyer, one side outside fixedly connected with elasticity seat of conveyer, elasticity seat rotates and is connected with turns over the board, elasticity seat symmetry sets up the lateral part at turning over the board, the upper end fixedly connected with bobbing machine that turns over the board, the outer fixedly connected with first gear motor of one side elasticity seat of turning over the board, the rotor of first gear motor runs through elasticity seat and turns over board fixed connection. The material is placed in the feeding vehicle, the feeding vehicle is utilized to move along the guide rail frame, after the feeding machine is positioned on the upper side of the box-shaped die, the feeding machine is utilized to feed the material in the box-shaped die, after the feeding machine fills the box-shaped die, the turning plate is driven by the first gear motor to upwards open, the box-shaped die is moved by the conveyor until the box-shaped die moves to the front part of the conveyor, the turning plate cover is driven by the first gear motor to be covered on the box-shaped die, the material in the box-shaped die is flattened by vibration of the vibrator, and automatic forming of the component is facilitated.

Preferably, the feeding vehicle comprises a first roller, a hopper, a saddle, a second roller, a second gear motor, a linkage shaft and a gear, wherein the saddle is symmetrically and fixedly connected to the outside of the hopper, the second roller and the first roller are rotationally connected under the saddle, the linkage shaft is fixedly connected between the first rollers, the gear is fixedly connected to the outside of the linkage shaft, a driving gear is fixedly connected to a rotor of the second gear motor, and the driving gear is meshed with the gear. The second gear motor is utilized to drive the gear to rotate, so that the gear drives the linkage shaft to rotate, and the linkage shaft drives the two first idler wheels to rotate, so that the second gear motor rolls on the guide rail frame, and the feeding vehicle can conveniently move on the guide rail frame.

Preferably, the feeding vehicle further comprises a barrier strip fixedly connected to the lower end of the saddle. The baffle strips are blocked on the inner side of the guide rail frame, so that the butt joint stability of the feeding vehicle and the guide rail frame is ensured.

Preferably, the feeder comprises a screw body, a material guiding shell and a motor, wherein the screw body is movably arranged in the material guiding shell, the motor is fixedly connected to the side part of the material guiding shell, and the screw body is fixedly connected with a rotor of the motor. The motor is utilized to drive the spiral body to rotate, and the material sliding down by the funnel is pushed to the other side of the guide shell through the spiral body, so that the blanking is conveniently controlled.

Preferably, the feeder further comprises a discharging nozzle, the discharging nozzle is symmetrically arranged, the upper end of the discharging nozzle is fixedly connected with the material guiding shell, and the material guiding shell is communicated with the inner space of the discharging nozzle. The discharge nozzle facilitates the outward discharge of the guide shell.

Preferably, the feeder further comprises a connecting ring, and the connecting ring is fixedly connected between the motor and the material guiding shell. The motor is conveniently fixedly connected with the guide shell through the connecting ring.

Preferably, the elastic seat comprises a bearing seat and a spring, and the spring is symmetrically and fixedly connected to the lower end of the bearing seat. The spring is used as a bearing seat to lift the turning plate up and down, so that the turning plate can be matched with the materials in the box-shaped die conveniently.

In summary, the technical effects and advantages of the present utility model are:

1. The material is placed in the feeding vehicle, the feeding vehicle is utilized to move along the guide rail frame, after the feeding machine is positioned on the upper side of the box-shaped die, the feeding machine is utilized to feed the material in the box-shaped die, after the feeding machine fills the box-shaped die, the turning plate is driven by the first gear motor to upwards open, the box-shaped die is moved by the conveyor until the box-shaped die moves to the front part of the conveyor, the turning plate cover is driven by the first gear motor to be covered on the box-shaped die, the material in the box-shaped die is flattened by vibration of the vibrator, and automatic forming of the component is facilitated.

2. The second gear motor is utilized to drive the gear to rotate, so that the gear drives the linkage shaft to rotate, and the linkage shaft drives the two first idler wheels to rotate, so that the second gear motor rolls on the guide rail frame, and the feeding vehicle can conveniently move on the guide rail frame.

3. The motor is utilized to drive the spiral body to rotate, and the material sliding down by the funnel is pushed to the other side of the guide shell through the spiral body, so that the blanking is conveniently controlled.

Drawings

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

FIG. 2 is a schematic view of a feed truck according to the present utility model;

FIG. 3 is a schematic view of a feeder structure of the present utility model;

Fig. 4 is a schematic diagram of the structure of the spring seat according to the present utility model.

In the figure: 1. a guide rail frame; 2. feeding vehicle; 3. a feeder; 4. an elastic seat; 5. a conveyor; 6. turning plate; 7. a first gear motor; 8. a vibrator; 9. a box-shaped mold; 21. a funnel; 22. a saddle; 23. a barrier strip; 24. a second roller; 25. a first roller; 26. a linkage shaft; 27. a gear; 28. a second gear motor; 31. a screw; 32. a material guiding shell; 33. a blanking nozzle; 34. a connecting ring; 35. a motor; 41. a bearing seat; 42. and (3) a spring.

Detailed Description

The following description of the technical solutions in the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments.

Referring to fig. 1 and 2, the automatic production device of small-size prefabricated components, including guide rail frame 1, the upper portion rolling installation of guide rail frame 1 has feed car 2, the lower extreme fixedly connected with batcher 3 of feed car 2, the downside of guide rail frame 1 is equipped with conveyer 5, box-shaped mould 9 has been put to the upper end of conveyer 5, one side outside fixedly connected with elastic seat 4 of conveyer 5, elastic seat 4 rotates and is connected with turns over board 6, elastic seat 4 symmetry sets up the lateral part at turning over board 6, the upper end fixedly connected with bobbing machine 8 of turning over board 6, the outer end fixedly connected with first gear motor 7 of one side elastic seat 4 of turning over board 6, the rotor of first gear motor 7 runs through elastic seat 4 and turns over board 6 fixed connection. The material is placed in the feeding vehicle 2, the feeding vehicle 2 is utilized to move along the guide rail frame 1, after the feeding machine 3 is positioned on the upper side of the box-shaped die 9, the feeding machine 3 is utilized to feed the box-shaped die 9, after the feeding machine 3 fills the box-shaped die 9, the first gear motor 7 is utilized to drive the turning plate 6 to turn upwards, the box-shaped die 9 is moved through the conveyor 5 until the box-shaped die 9 moves to the front part of the conveyor 5, the first gear motor 7 is utilized to drive the turning plate 6 to cover the box-shaped die 9, the material in the box-shaped die 9 is flattened by utilizing the vibration of the vibrator 8, and the components are formed.

Referring to fig. 1 and 2, the feeding car 2 includes a first roller 25, a hopper 21, a saddle 22, a second roller 24, a second gear motor 28, a linkage shaft 26 and a gear 27, wherein the first roller 25 and the second roller 24 are rollingly mounted at the upper end of the guide rail frame 1, the saddle 22 is symmetrically and fixedly connected to the outside of the hopper 21, the second roller 24 and the first roller 25 are rotatably connected to the underside of the saddle 22, the linkage shaft 26 is fixedly connected between the first rollers 25, the gear 27 is fixedly connected to the outside of the linkage shaft 26, a driving gear is fixedly connected to the rotor of the second gear motor 28, and the driving gear is meshed with the gear 27. The second gear motor 28 is utilized to drive the gear 27 to rotate, so that the gear 27 drives the linkage shaft 26 to rotate, and the linkage shaft 26 drives the two first rollers 25 to rotate, so that the second gear motor 28 rolls along the guide rail frame 1.

Referring to fig. 1 and 2, the feeding car 2 further includes a barrier rib 23, and the barrier rib 23 is fixedly coupled to a lower end of the saddle 22. The baffle bar 23 is utilized to block the inner side of the guide rail frame 1, so that the butt joint stability of the feeding car 2 and the guide rail frame 1 is ensured.

Referring to fig. 1, 2 and 3, the feeder 3 includes a screw 31, a guide shell 32 and a motor 35, the guide shell 32 is symmetrically disposed, an upper end of the guide shell 32 is fixedly connected to a lower end of the hopper 21, an inner space of the hopper 21 and the guide shell 32 is communicated, the screw 31 is movably disposed in the guide shell 32, the motor 35 is fixedly connected to a side portion of the guide shell 32, and the screw 31 is fixedly connected to a rotor of the motor 35. The motor 35 is used for driving the screw 31 to rotate, and the material sliding down from the hopper 21 is pushed to the other side of the guide shell 32 through the screw 31.

Referring to fig. 1 and 3, the feeder 3 further includes a discharging nozzle 33, the discharging nozzle 33 is symmetrically disposed, an upper end of the discharging nozzle 33 is fixedly connected with the guide shell 32, and an inner space of the guide shell 32 and the discharging nozzle 33 is communicated. The material inside the guide shell 32 is guided out by the blanking nozzle 33.

Referring to fig. 1 and 3, the feeder 3 further comprises a connecting ring 34, the connecting ring 34 being fixedly connected between the motor 35 and the guide shell 32. The motor 35 is fixedly connected with the guide shell 32 through the connecting ring 34.

Referring to fig. 1 and 4, the elastic seat 4 includes a bearing seat 41 and a spring 42, the lower end of the spring 42 is fixedly connected with the conveyor 5, one of the elastic seats 4 is fixedly connected with the first gear motor 7, the side portion of the turning plate 6 is rotatably connected in the bearing seat 41, and the spring 42 is symmetrically and fixedly connected at the lower end of the bearing seat 41. The spring 42 is used for lifting the bearing seat 41 to the elastic force of the turning plate 6 in the up-down direction, so that the turning plate 6 can be matched with the materials in the box-shaped die 9.

Working principle: the second gear motor 28 is utilized to drive the gear 27 to rotate, the gear 27 drives the linkage shaft 26 to rotate, the linkage shaft 26 drives the two first rollers 25 to rotate, the second gear motor 28 rolls along the guide rail frame 1, the motor 35 drives the screw body 31 to rotate, the material sliding down from the hopper 21 is pushed to the other side of the guide shell 32 through the screw body 31, the material in the two guide shells 32 is respectively guided into two lattices in the box-shaped die 9 through the blanking nozzle 33 until the two lattices of the box-shaped die 9 are filled, the blanking nozzle 33 is moved to the other two lattices through the feeding vehicle 2 to feed the material in the same way until the box-shaped die 9 is completely fed, the feeding vehicle 2 is used to move to the other box-shaped die 9, after the material in the box-shaped die 9 is filled, the box-shaped die 9 is opened through the first gear motor 7, the conveyor 5 is used to move the side part of the box-shaped die 9, the first gear motor 7 is used to close the box-shaped die 6, the box-shaped die 6 is pressed on the material in the box-shaped die 9 until the two lattices are filled, the blanking nozzle 33 is moved to the other two lattices through the first gear motor 7, and the box-shaped die 9 is vibrated, and the box-shaped die 9 is driven to vibrate, and the box-shaped die 9 is flattened.

The foregoing is only a preferred embodiment of the utility model, but the scope of the utility model is not limited thereto, and any person skilled in the art who is in the field of the utility model can apply equivalent substitution or modification to the technical solution and the inventive concept according to the utility model within the scope of the utility model.

The application direction is simply mentioned in the description for the prior art that the utility model is known to the person skilled in the art and has not changed, and the utility model is combined to form the complete technology; techniques well known to those skilled in the art to avoid undue popularity are employed to assist those skilled in the art in quickly understanding the principles of the utility model.

Claims (7)

1. Small-size prefabricated component automated production device, its characterized in that: including guide rail frame (1), upper portion rolling installation of guide rail frame (1) has feed car (2), the lower extreme fixedly connected with batcher (3) of feed car (2), the downside of guide rail frame (1) is equipped with conveyer (5), box-shaped mould (9) have been put to the upper end of conveyer (5), one side outside fixedly connected with elasticity seat (4) of conveyer (5), elasticity seat (4) rotation is connected with turns over board (6), elasticity seat (4) symmetry sets up in the lateral part of turning over board (6), the upper end fixedly connected with bobbing machine (8) of turning over board (6), the outer fixedly connected with first gear motor (7) of one of them elasticity seat (4) of turning over board (6), the rotor of first gear motor (7) runs through elasticity seat (4) and turns over board (6) fixed connection.

2. The automated small-sized prefabricated component production device according to claim 1, wherein: the feeding vehicle (2) comprises a first roller (25), a hopper (21), a saddle (22), a second roller (24), a second gear motor (28), a linkage shaft (26) and a gear (27), wherein the saddle (22) is symmetrically and fixedly connected to the outside of the hopper (21), the second roller (24) and the first roller (25) are rotationally connected to the underside of the saddle (22), the linkage shaft (26) is fixedly connected between the first rollers (25), the gear (27) is fixedly connected to the outside of the linkage shaft (26), and a driving gear is fixedly connected to a rotor of the second gear motor (28) and is meshed with the gear (27).

3. The automated small-sized prefabricated component production device according to claim 2, wherein: the feeding vehicle (2) further comprises a blocking strip (23), and the blocking strip (23) is fixedly connected to the lower end of the vehicle seat (22).

4. The automated small-sized prefabricated component production device according to claim 1, wherein: the feeding machine (3) comprises a spiral body (31), a material guiding shell (32) and a motor (35), wherein the spiral body (31) is movably arranged in the material guiding shell (32), the motor (35) is fixedly connected to the side part of the material guiding shell (32), and the spiral body (31) is fixedly connected with a rotor of the motor (35).

5. The automated small-sized prefabricated component manufacturing apparatus according to claim 4, wherein: the feeding machine (3) further comprises a discharging nozzle (33), the discharging nozzle (33) is symmetrically arranged, the upper end of the discharging nozzle (33) is fixedly connected with the material guiding shell (32), and the material guiding shell (32) is communicated with the inner space of the discharging nozzle (33).

6. The automated small-sized prefabricated component manufacturing apparatus according to claim 4, wherein: the feeder (3) further comprises a connecting ring (34), and the connecting ring (34) is fixedly connected between the motor (35) and the material guiding shell (32).

7. The automated small-sized prefabricated component production device according to claim 1, wherein: the elastic seat (4) comprises a bearing seat (41) and a spring (42), and the spring (42) is symmetrically and fixedly connected to the lower end of the bearing seat (41).