CN113681711A

CN113681711A - Automatic change indoor hack device

Info

Publication number: CN113681711A
Application number: CN202110995546.5A
Authority: CN
Inventors: 杨秀莲; 梁仕华; 冯德銮; 曾成林; 杨欢
Original assignee: Guangdong University of Technology
Current assignee: Guangdong University of Technology
Priority date: 2021-08-27
Filing date: 2021-08-27
Publication date: 2021-11-23

Abstract

The invention discloses an automatic indoor soil crushing device which mainly comprises a conveying mechanism, a grinding mechanism and a screening mechanism; one end of the conveying mechanism is connected with the material storage hopper, and the other end of the conveying mechanism is connected with the feeding end of the grinding mechanism; the screening mechanism is arranged below the grinding mechanism, and the feeding end of the screening mechanism is connected with the discharging end of the grinding mechanism. When the device works, firstly, materials are put at the upper hopper and are conveyed through the conveying belt; then, the inner cylinder closes the second cover plate and then rotates at a constant speed through a second motor, and the materials are extruded and ground through the impact force between the materials and the iron balls and the rotation of the inner cylinder; then, opening the second cover plate to expose the first cover plate and rotating the second cover plate again, and throwing the ground materials from the discharge hopper to the sieve through the grid openings of the first cover plate; and finally, automatically screening the materials through a screen, and using the screened materials after screening. The invention also has the advantages of simple structure, convenient operation and easy implementation.

Description

Automatic change indoor hack device

Technical Field

The invention relates to the field of geotechnical engineering indoor experimental devices, in particular to an automatic indoor soil crushing device.

Background

In order to better understand the physical and mechanical properties of cement solidified soil, some cement solidified soil is prepared by selecting dry soil, cement, water and other additives to form a mixture, putting the mixture into a water silt machine stirrer for stirring, and then carrying out layered vibration and sample preparation; some dried soil is added with water in different proportions to prepare samples with different water contents for research; also, comparison studies were performed by adding different particle sizes of the admixture. Therefore, materials such as soil or admixture need to be ground to the required particle size fineness for testing, soil particles are connected together by utilizing the cementing action of the cementing material, meanwhile, the pores among the soil particles are effectively filled, a compact structure is formed, and the strength of the soil body is improved.

In order to achieve materials with different particle sizes, crushing and grinding become more important, so that the automatic conveying, grinding and vibrating screening device is introduced to further obtain soil with different particle sizes for subsequent research.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides an automatic indoor soil crushing device.

The purpose of the invention is realized by the following technical scheme:

an automatic indoor soil crushing device mainly comprises a conveying mechanism for conveying materials, a grinding mechanism for grinding the materials and a screening mechanism for screening material particles. One end of the conveying mechanism is connected with the material storage hopper, and the other end of the conveying mechanism is connected with the feeding end of the grinding mechanism. The screening mechanism is arranged below the grinding mechanism, and the feeding end of the screening mechanism is connected with the discharging end of the grinding mechanism.

Specifically, the conveying mechanism mainly comprises a first support, a conveying belt, a roller, a first baffle, a feeding hopper and a first motor. The first support is fixedly arranged on the ground. The rollers are mounted side by side on a first bracket. The conveyer belt is installed on the roller. The first baffle is arranged on the conveying belt and is perpendicular to the conveying belt. The feeding hopper is arranged at one end of the first support and is positioned above the conveying belt. The motor is arranged on the first support and is in transmission connection with the roller, and the conveying belt is driven to drive the first baffle to convey materials forwards.

Further, the conveying mechanism further comprises a side baffle. The side baffles are respectively arranged at two sides of the first support, fixedly connected with the first support and positioned at the left side and the right side of the conveying belt.

Specifically, the grinding mechanism mainly comprises a second support, an outer cylinder, an inner cylinder, iron balls, a rotating shaft, a second motor, a discharging hopper, a first cover plate and a second cover plate. The second support is fixedly arranged on the ground. The outer cylinder body is arranged at the top of the second support, and an opening for discharging is formed in the upper end of the outer cylinder body. The discharging hopper is arranged at the bottom of the outer barrel and is positioned above the screening mechanism. The inner cylinder is arranged in the outer cylinder through a rotating shaft and is concentric with the outer cylinder. The iron ball is placed in the inner cylinder body. The output end of the second motor is in transmission connection with the rotating shaft and drives the inner barrel to rotate through the rotating shaft. And a feeding port is arranged on the inner cylinder body. The first cover plate is arranged at the feeding port and hinged with the inner cylinder body, and the feeding port is completely opened or partially opened in a turnover mode. The second cover plate is also arranged at the feeding port and is hinged with the inner cylinder body, and the feeding port is opened or closed in a turnover mode. The second cover plate covers the first cover plate.

As a preferred scheme of the invention, the first cover plate adopts a grid-shaped structure, and a plurality of holes are formed in the cover plate.

As a preferable scheme of the present invention, the second cover plate adopts a sealing design.

Specifically, screening mechanism mainly includes sieve, chassis, third support, spring, second baffle and third motor. And the third support is fixedly arranged below the discharging hopper. The spring is arranged on the third support, and the top of the spring is connected with the bottom of the chassis. The second baffle is arranged on the side face of the chassis and fixedly connected with the chassis. The third motor is arranged at the bottom of the chassis and provides vibration for the chassis. The sieve is arranged on the chassis and is positioned below the discharging hopper.

Further, the screening mechanism further comprises a first controller for controlling the third motor. The first controller is electrically connected with the third motor.

Further, the grinding mechanism further comprises a second controller for controlling a second motor. The second controller is electrically connected with the second motor.

Further, the soil crushing device also comprises a fourth bracket. The fourth support is fixed on one side of the third support and used for fixing the second motor and the second controller or the first controller.

The invention also discloses a method and a process for using the soil crushing device, wherein the method comprises the following steps:

a method for using an automatic indoor soil crushing device comprises the following specific steps:

step S1: the material to be ground is put into a feeding hopper of a conveying mechanism and is automatically conveyed through a conveying belt, and a first baffle is arranged for preventing the material from falling before the material is put into a feeding port of the grinding mechanism;

step S2: after the inner cylinder body of the grinding mechanism is sealed by the second cover plate, the inner cylinder body is rotated at a constant speed through the coupler, the second controller, the second motor and the like, iron balls in the inner cylinder body fall freely under the action of gravity, and the materials to be ground in the inner cylinder body and the iron balls are subjected to impact force and rotation of the inner cylinder body, so that friction force and extrusion force are generated among the materials, the iron balls and the inner cylinder body to grind the materials;

step S3: opening a second cover plate of a feed inlet of the grinding mechanism, exposing the first cover plate, and rotating again, wherein the ground materials are put on the sieve from a discharge hopper through a grid opening of the first cover plate;

step S4: through the sieve of placing on the shaking table, carry out automatic screening to the material, after the screening is accomplished, can use the material that sieves in the sieve chassis well.

Compared with the prior art, the invention also has the following advantages:

(1) the automatic indoor soil crushing device provided by the invention can automatically put materials into the feeding port, and after the materials are successfully ground, the materials are automatically vibrated and screened, so that the efficiency can be obviously improved.

(2) The automatic indoor soil crushing device provided by the invention can crush and grind soil required by an indoor test into uniform soil particles; the admixture can also be crushed and prepared into different particle sizes, which is beneficial to subsequent tests.

(3) The automatic indoor soil crushing device provided by the invention can realize the functions of automatic conveying and screening, and is time-saving and labor-saving.

Drawings

Fig. 1 is a schematic structural diagram of an automatic indoor soil crushing device provided by the invention.

The reference numerals in the above figures illustrate:

1-side baffle, 2-conveyer belt, 3-first baffle, 4-feeding hopper, 5-first support, 6-first motor, 8-outer cylinder, 9-inner cylinder, 10-feeding port, 11-iron ball, 12-discharging hopper, 13-second motor, 14-second controller, 15-second support, 16-third support, 17-spring, 18-second baffle, 19-third motor, 20-first controller, 21-chassis, 22-sieve and 23-fourth support.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer and clearer, the present invention is further described below with reference to the accompanying drawings and examples.

Example 1:

as shown in fig. 1, the present embodiment discloses an automatic indoor soil crushing device, which mainly includes a conveying mechanism for conveying materials, a grinding mechanism for grinding the materials, and a screening mechanism for screening material particles. One end of the conveying mechanism is connected with the material storage hopper, and the other end of the conveying mechanism is connected with the feeding end of the grinding mechanism. The screening mechanism is arranged below the grinding mechanism, and the feeding end of the screening mechanism is connected with the discharging end of the grinding mechanism.

Specifically, the conveying mechanism mainly comprises a first bracket 5, a conveying belt 2, a roller, a first baffle 3, a feeding hopper 4 and a first motor 6. The first bracket 5 is fixedly arranged on the ground. The rollers are mounted side by side on a first support 5. The conveyor belt 2 is mounted on a drum. The first baffle 3 is arranged on the conveying belt 2 and is perpendicular to the conveying belt 2. The feeding hopper 4 is arranged at one end of the first bracket 5 and above the conveyor belt 2. The motor is arranged on the first support 5 and is in transmission connection with the roller, and the conveying belt 2 is driven to drive the first baffle 3 to convey materials forwards.

Further, the conveying mechanism further comprises a side baffle 1. The side baffles 1 are respectively arranged at two sides of the first support 5, fixedly connected with the first support 5 and positioned at the left side and the right side of the conveying belt 2.

Specifically, the grinding mechanism mainly comprises a second support 15, an outer cylinder 8, an inner cylinder 9, iron balls 11, a rotating shaft, a second motor 13, a discharging hopper 12, a first cover plate and a second cover plate. The second bracket 15 is fixedly arranged on the ground. The outer cylinder body 8 is arranged at the top of the second support 15, and the upper end of the outer cylinder body is provided with an opening for blanking. The discharging hopper 12 is arranged at the bottom of the outer cylinder 8 and is positioned above the screening mechanism. The inner cylinder 9 is arranged in the outer cylinder 8 through a rotating shaft and is arranged concentrically with the outer cylinder 8. The iron ball 11 is placed in the inner cylinder 9. The output end of the second motor 13 is in transmission connection with the rotating shaft and drives the inner cylinder 9 to rotate through the rotating shaft. The inner cylinder body 9 is provided with a feeding port 10. The first cover plate is arranged at the feeding port 10 and is hinged with the inner cylinder 9, and the feeding port 10 is completely or partially opened in a turnover mode. The second cover plate is also arranged at the feeding port 10 and is hinged with the inner cylinder 9, and the feeding port 10 is opened or closed in a turnover mode. The second cover plate covers the first cover plate.

Specifically, the screening mechanism mainly includes a screen 22, a chassis 21, a third bracket 16, a spring 17, a second baffle 18, and a third motor 19. The third bracket 16 is fixedly mounted below the lower hopper 12. The spring 17 is mounted on the third bracket 16, the top of which is connected to the bottom of the chassis 21. The second baffle 18 is arranged on the side surface of the chassis 21 and is fixedly connected with the chassis 21. The third motor 19 is installed at the bottom of the chassis 21 to provide vibration to the chassis 21. The screen 22 is arranged on the chassis 21 below the lower hopper 12.

Further, the screening mechanism further comprises a first controller 20 for controlling the third motor 19. The first controller 20 is electrically connected to the third motor 19.

Further, the grinding mechanism further comprises a second controller 14 for controlling the second motor 13. The second controller 14 is electrically connected to the second motor 13.

Further, the soil crushing device further comprises a fourth bracket 23. The fourth bracket 23 is fixed to one side of the third bracket 16, and is used to fix the second motor 13 and the second controller 14 or the first controller 20.

step S1: the material to be ground is put into a feeding hopper 4 of a conveying mechanism and is automatically conveyed through a conveying belt 2, and a first baffle 3 is arranged for preventing the material from falling before being put into a feeding port 10 of the grinding mechanism;

step S2: after the inner cylinder 9 of the grinding mechanism is sealed by the second cover plate, the inner cylinder 9 is rotated at a constant speed by a coupler, a second controller 14, a second motor 13 and the like, iron balls 11 in the inner cylinder 9 fall freely under the action of gravity, and the materials to be ground in the inner cylinder 9 and the iron balls 11 are subjected to impact force and rotation of the inner cylinder 9, so that friction force and extrusion force are generated among the materials, the iron balls 11 and the inner cylinder 9 to grind the materials;

step S3: opening a second cover plate of a feeding port 10 of the grinding mechanism to expose the first cover plate, and rotating again, wherein the ground materials are put on a sieve 22 from a discharge hopper 12 through a grid port of the first cover plate;

step S4: the materials are automatically screened through the screen 22 arranged on the vibration table, and the screened materials in the chassis 21 of the screen 22 can be used after the screening is finished.

The above embodiments are preferred embodiments of the present invention, but the present invention is not limited to the above embodiments, and any other changes, modifications, substitutions, combinations, and simplifications which do not depart from the spirit and principle of the present invention should be construed as equivalents thereof, and all such changes, modifications, substitutions, combinations, and simplifications are intended to be included in the scope of the present invention.

Claims

1. An automatic indoor soil crushing device is characterized by comprising a conveying mechanism for conveying materials, a grinding mechanism for grinding the materials and a screening mechanism for screening material particles; one end of the conveying mechanism is connected with the material storage hopper, and the other end of the conveying mechanism is connected with the feeding end of the grinding mechanism; the screening mechanism is arranged below the grinding mechanism, and the feeding end of the screening mechanism is connected with the discharging end of the grinding mechanism.

2. The automated indoor soil breaking device according to claim 1, wherein the conveying mechanism comprises a first bracket, a conveyor belt, a roller, a first baffle, a feeding hopper, and a first motor; the first support is fixedly arranged on the ground; the rollers are arranged on the first bracket side by side; the conveying belt is arranged on the roller; the first baffle is arranged on the conveying belt and is perpendicular to the conveying belt; the feeding hopper is arranged at one end of the first bracket and is positioned above the conveying belt; the motor is arranged on the first support and is in transmission connection with the roller, and the conveying belt is driven to drive the first baffle to convey materials forwards.

3. The automated indoor soil breaking device of claim 2, wherein the transport mechanism further comprises a side dam; the side baffles are respectively arranged at two sides of the first support, fixedly connected with the first support and positioned at the left side and the right side of the conveying belt.

4. The automated indoor soil crushing device according to claim 1, wherein the grinding mechanism comprises a second bracket, an outer cylinder, an inner cylinder, iron balls, a rotating shaft, a second motor, a discharging hopper, a first cover plate and a second cover plate; the second bracket is fixedly arranged on the ground; the outer cylinder body is arranged at the top of the second support, and the upper end of the outer cylinder body is provided with an opening for blanking; the discharging hopper is arranged at the bottom of the outer cylinder and is positioned above the screening mechanism; the inner cylinder body is arranged in the outer cylinder body through a rotating shaft and is concentric with the outer cylinder body; the iron ball is placed in the inner cylinder body; the output end of the second motor is in transmission connection with the rotating shaft and drives the inner cylinder body to rotate through the rotating shaft; a feeding port is arranged on the inner cylinder body; the first cover plate is arranged at the feeding port and is hinged with the inner cylinder body, and the feeding port is completely opened or partially opened in a turnover mode; the second cover plate is also arranged at the feeding port and is hinged with the inner cylinder body, and the feeding port is opened or closed in a turnover mode; the second cover plate covers the first cover plate.

5. The automated indoor soil crushing device of claim 4, wherein the first cover plate is of a grid structure, and a plurality of holes are formed in the cover plate.

6. The automated indoor soil breaking device of claim 4, wherein the second cover plate is of a sealed design.

7. The automated indoor soil crushing device according to claim 1, wherein the screening mechanism comprises a screen, a chassis, a third bracket, a spring, a second baffle, and a third motor; the third support is fixedly arranged below the discharging hopper; the spring is arranged on the third support, and the top of the spring is connected with the bottom of the chassis; the second baffle is arranged on the side surface of the chassis and is fixedly connected with the chassis; the third motor is arranged at the bottom of the chassis and provides vibration for the chassis; the sieve is arranged on the chassis and is positioned below the discharging hopper.

8. The automated indoor soil breaking device of claim 7, wherein the screening mechanism further comprises a first controller for controlling a third motor; the first controller is electrically connected with the third motor.

9. The automated indoor clod crushing device of claim 4, wherein the grinding mechanism further comprises a second controller for controlling a second motor; the second controller is electrically connected with the second motor.

10. The automated indoor soil breaking device according to claim 8 or 9, further comprising a fourth support; the fourth support is fixed on one side of the third support and used for fixing the second motor and the second controller or the first controller.