CN211678001U

CN211678001U - Ground reducing mechanism

Info

Publication number: CN211678001U
Application number: CN202020128961.1U
Authority: CN
Inventors: 李晓东
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-01-20
Filing date: 2020-01-20
Publication date: 2020-10-16
Anticipated expiration: 2030-01-20

Abstract

The utility model relates to a smash technical field, especially relate to a ground reducing mechanism, conveying discharge mechanism, smash the case, smash the hammer, smash guardrail and shale shaker, conveying discharge mechanism is including conveying discharge box, stock guide, conveying motor and axis of rotation, it includes install bin and pan feeding mouth to smash the case and bag, smash the hammer including rotating the motor, the fifth wheel, smash board and connecting axle, it includes the entry backplate to smash the guardrail, protect the flitch, the stripper, unload motor and unloading axle, the shale shaker includes material bounding wall, screen cloth, sliding block, dead lever, vibrating motor, vibrations pole, ejection of compact motor and ejection of compact connecting axle, the utility model discloses can accomplish ground and smash and with qualified and unqualified material separation of granularity.

Description

Ground reducing mechanism

Technical Field

The utility model relates to a smash technical field, especially relate to a ground reducing mechanism.

Background

Along with the rapid development of the industry of building, need smash the ground and place because the too big quality that influences the building of granularity of ground also does not benefit to the construction, current smash to the ground and adopt artifical the beating and large-scale mechanical processing mostly, consume a large amount of manpower and materials, also reduced the efficiency of construction.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a ground reducing mechanism can accomplish ground and smash and with qualified and unqualified material separation of granularity.

The purpose of the utility model is realized through the following technical scheme:

a rock soil crushing device comprises a conveying and discharging mechanism, a crushing box, a crushing hammer, a crushing guardrail and a vibrating screen, wherein the crushing hammer is rotatably connected to the crushing box, the crushing box is fixedly connected to the upper end of the conveying and discharging mechanism, the crushing guardrail is fixedly connected to the crushing box, and the vibrating screen is fixedly connected to the conveying and discharging mechanism;

the conveying and discharging mechanism comprises a conveying and discharging box, material guide plates, a conveying motor and rotating shafts, wherein the two rotating shafts are rotatably connected in the conveying and discharging box;

the crushing box comprises an installation box and a feeding port, the crushing box is fixedly connected to the upper end of the conveying discharging box, and the feeding port is fixedly connected with the installation box;

the crushing hammer comprises a rotating motor, a connecting wheel, crushing plates and a connecting shaft, wherein the rotating motor is fixedly connected to an installation box, the connecting shaft is rotatably connected to the installation box, the connecting shaft is fixedly connected to an output shaft of the rotating motor, the connecting wheel is fixedly connected to the connecting shaft, and the crushing plates are fixedly connected to the connecting wheel;

the crushing guardrail comprises an inlet guard plate, a discharging motor and a discharging shaft, wherein the inlet guard plate and the guard plate are fixedly connected in an installation box;

the shale shaker include the material bounding wall, the screen cloth, the sliding block, the dead lever, vibrating motor, the vibrations pole, ejection of compact motor and ejection of compact connecting axle, the equal fixed connection of two sliding blocks is in conveying ejection of compact incasement, two dead levers sliding connection respectively are in two sliding blocks, the equal fixed connection of two dead levers is on the material bounding wall, screen cloth and material bounding wall sliding connection, ejection of compact motor fixed connection is on the material bounding wall, the equal fixed connection of two vibrating motor is in conveying ejection of compact incasement, two vibrations pole fixed connection respectively are on two vibrating motor, the equal fixed connection of two vibrations poles is on the material bounding wall, ejection of compact connecting axle fixed connection is on ejection of compact motor output shaft, ejection of compact.

The utility model has the advantages that:

the utility model provides a ground reducing mechanism, add unprocessed ground by the pan feeding mouth, the ground falls into crushing guardrail, start and rotate the motor, the connecting axle rotates four stripper and also begins to rotate, smash the ground, a period of time later, smash the completion, start the motor of unloading, rotate the stripper, unload the shale shaker with crushing back ground, two vibrating motor and conveying motor restart, conveyer belt among the conveying discharge mechanism begins the function, the shale shaker begins to vibrate simultaneously, the granularity is less than the material of screen cloth and falls onto the conveyer belt, be walked by the conveying, close two vibrating motor after a period of time, restart discharge motor, turn down the screen cloth, lift the material that the granularity is big off, accomplish and smash the separation after.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a cross-sectional view of the overall structure of the present invention;

FIG. 3 is a schematic structural view of the conveying and discharging mechanism of the present invention;

FIG. 4 is a sectional view of the structure of the conveying and discharging mechanism of the present invention

FIG. 5 is a schematic view of the structure of the crushing box of the present invention;

FIG. 6 is a schematic view of the structure of the crushing hammer of the present invention;

fig. 7 is a schematic view of the crushing guard rail of the present invention;

FIG. 8 is a schematic structural view of the vibrating screen of the present invention;

fig. 9 is a sectional view of the structure of the vibrating screen of the present invention.

In the figure: a conveying and discharging mechanism 1; a conveying discharging box 1-1; a material guide plate 1-2; a transfer motor 1-3; 1-4 of a rotating shaft; a crushing box 2; an installation box 2-1; a feeding port 2-2; a crushing hammer 3; rotating a motor 3-1; connecting wheels 3-2; 3-3 of a crushing plate; connecting shafts 3-4; crushing the guard rail 4; an inlet guard plate 4-1; a material protecting plate 4-2; 4-3 of a stripper plate; 4-4 of a discharging motor; 4-5 of a discharging shaft; a vibrating screen 5; 5-1 of a material enclosing plate; 5-2 parts of a screen mesh; 5-3 of a sliding block; 5-4 of a fixed rod; 5-5 of a vibration motor; 5-6 parts of a vibration rod; 5-7 of a discharging motor; and 5-8 parts of a discharging connecting shaft.

Detailed Description

The present invention will be described in further detail with reference to the accompanying fig. 1-9.

The first embodiment is as follows:

as shown in fig. 1-9, a rock soil crushing device comprises a conveying and discharging mechanism 1, a crushing box 2, a crushing hammer 3, a crushing guardrail 4 and a vibrating screen 5, wherein the crushing hammer 3 is rotatably connected to the crushing box 2, the crushing box 2 is fixedly connected to the upper end of the conveying and discharging mechanism 1, the crushing guardrail 4 is fixedly connected to the crushing box 2, and the vibrating screen 5 is fixedly connected in the conveying and discharging mechanism 1;

unprocessed rock soil is added from a feeding port 2-2 and falls into a crushing guardrail 4, a rotating motor 3-1 is started, a connecting shaft 3-4 rotates four discharging plates 4-3 to start rotating, crushing rock soil, after a period of time, finishing crushing, starting a discharging motor 4-4, rotating a discharging plate 4-3, discharging the crushed rock soil into a vibrating screen 5, then the two vibrating motors 5-5 and the conveying motors 1-3 are started, the conveying belt in the conveying and discharging mechanism 1 starts to operate, meanwhile, the vibrating screen 5 starts to vibrate, materials with the granularity smaller than that of the screen 5-2 fall onto the conveying belt and are conveyed away, the two vibrating motors 5-5 are turned off after a period of time, the discharging motors 5-7 are started, the screen 5-2 is turned down, the materials with the large granularity are unloaded, and crushing and later separation are completed.

The second embodiment is as follows:

as shown in fig. 1-9, the conveying and discharging mechanism 1 includes a conveying and discharging box 1-1, two material guide plates 1-2, a conveying motor 1-3 and two rotating shafts 1-4, wherein the two rotating shafts 1-4 are both rotatably connected in the conveying and discharging box 1-1, the two material guide plates 1-2 are both fixedly connected in the conveying and discharging box 1-1, the rotating shaft 1-4 at the right end is fixedly connected to an output shaft of the conveying motor 1-3, and the two rotating shafts 1-4 are connected by a belt;

the conveying motor 1-3 is started, the conveying belt starts to operate, the screened materials are conveyed away, the two guide plates 1-2 are fixedly connected to the upper portion of the conveying discharging box 1-1, the inner sides of the two guide plates 1-2 are located on the upper portion of the material enclosing plate 5-1, and the materials can be guided into the material enclosing plate 5-1.

The third concrete implementation mode:

as shown in the figure 1-9, the installation box 2-1 is fixedly connected with the upper end of the conveying discharge box 1-1, the feeding port 2-2 is fixedly connected with the installation box 2-1, and materials are fed from the feeding port 2-2.

The fourth concrete implementation mode:

as shown in fig. 1-9, the crushing hammer 3 comprises a rotating motor 3-1, a connecting wheel 3-2, crushing plates 3-3 and a connecting shaft 3-4, the rotating motor 3-1 is fixedly connected to an installation box 2-1, the connecting shaft 3-4 is fixedly connected to the installation box 2-1, the connecting shaft 3-4 is rotatably connected to an output shaft of the rotating motor 3-1, the connecting wheel 3-2 is fixedly connected to the connecting shaft 3-4, and the crushing plates 3-3 are all fixedly connected to the connecting wheel 3-2;

the rotating motor 3-1, the connecting wheel 3-2 and the connecting shaft 3-4 rotate to drive the plurality of crushing plates 3-3 to rotate, and the crushing plates act on materials to crush the materials.

The fifth concrete implementation mode:

as shown in fig. 1-9, the crushing guardrail 4 comprises an inlet guard plate 4-1, a material guard plate 4-2, a discharging plate 4-3, a discharging motor 4-4 and a discharging shaft 4-5, wherein the inlet guard plate 4-1 and the material guard plate 4-2 are both fixedly connected in an installation box 2-1, the discharging motor 4-4 is fixedly connected on the installation box 2-1, the discharging shaft 4-5 is rotatably connected in the installation box 2-1, the discharging shaft 4-5 is fixedly connected on an output shaft of the discharging motor 4-4, the discharging shaft 4-5 is fixedly connected with the discharging plate 4-3, and the discharging plate 4-3 is slidably connected in the installation box 2-1;

the discharging plate 4-3 is contacted with the inlet guard plate 4-1 during crushing, the inlet guard plate 4-1, the material protection plate 4-2 and the discharging plate 4-3 form a whole body which can provide a supporting platform for materials, after the crushing is completed, the discharging shaft 4-5 of the discharging motor 4-4 is started to rotate, the discharging plate 4-3 is rotated to discharge the materials, and the materials fall into the material enclosing plate 5-1.

The sixth specific implementation mode:

as shown in the figure 1-9, the vibrating screen 5 comprises a material enclosing plate 5-1, a screen 5-2, sliding blocks 5-3, fixed rods 5-4, a vibrating motor 5-5, vibrating rods 5-6, a discharging motor 5-7 and a discharging connecting shaft 5-8, wherein the two sliding blocks 5-3 are fixedly connected in a conveying discharging box 1-1, the two fixed rods 5-4 are respectively and slidably connected in the two sliding blocks 5-3, the two fixed rods 5-4 are respectively and fixedly connected on the material enclosing plate 5-1, the screen 5-2 is slidably connected with the material enclosing plate 5-1, the discharging motor 5-7 is fixedly connected on the material enclosing plate 5-1, the two vibrating motors 5-5 are respectively and fixedly connected in the conveying discharging box 1-1, the two vibrating rods 5-6 are respectively and fixedly connected on the two vibrating motors 5-5, the two vibrating rods 5-6 are fixedly connected to the material enclosing plate 5-1, the discharging connecting shaft 5-8 is fixedly connected to an output shaft of the discharging motor 5-7, and the discharging connecting shaft 5-8 is fixedly connected to the screen 5-2;

when the crushed materials enter the material enclosing plate 5-1, the two vibrating motors 5-5 are started, the vibrating rods 5-6 vibrate to screen the materials with the granularity smaller than the diameter of the holes in the screen 5-2, the materials fall on the conveyor belt and are conveyed to finish discharging of qualified products, after screening is finished, the discharging motors 5-7 are started, the discharging connecting shaft 5-8 rotates to turn down the screen 5-2, the materials with the granularity larger than the diameter of the holes in the screen 5-2 are unloaded and fall on the conveyor belt, and discharging of unqualified products is finished.

The utility model relates to a ground reducing mechanism, its theory of use is: adding unprocessed rock soil from a feeding port 2-2, enabling the rock soil to fall into a crushing guardrail 4, starting a rotating motor 3-1, rotating a connecting shaft 3-4 to rotate four discharging plates 4-3 to start rotating, crushing the rock soil, finishing crushing after a period of time, starting a discharging motor 4-4, rotating the discharging plates 4-3, discharging the crushed rock soil into a vibrating screen 5, starting two vibrating motors 5-5 and a conveying motor 1-3, starting a conveying belt in a conveying discharging mechanism 1 to operate, simultaneously starting vibration of the vibrating screen 5, enabling materials with granularity smaller than that of a screen 5-2 to fall onto the conveying belt to be conveyed away, closing the two vibrating motors 5-5 after a period of time, starting a discharging motor 5-7, rotating the screen 5-2 to discharge the materials with large granularity, finishing crushing and subsequent separation, the conveying motor 1-3 is fixedly connected at the upper end of the conveying discharge box 1-1, the feeding port 2-2 is fixedly connected with the mounting box 2-1, materials are added from the feeding port 2-2, the rotating motor 3-1, the connecting wheel 3-2 and the connecting shaft 3-4 rotate to drive the plurality of crushing plates 3-3 to rotate and act on the materials to crush, the discharge plate 4-3 is contacted with the inlet guard plate 4-1 during crushing, the inlet guard plate 4-1, the guard plate 4-2 and the discharge plate 4-3 form a whole body which can provide a supporting platform for the materials, after the crushing is completed, the discharge motor 4-4 is started to rotate the discharge shaft 4-5, the discharge plate 4-3 is rotated to discharge the materials, the materials fall into the material guard plate 5-1, and the conveying motor 1-3 is started, the conveyor belt starts to operate to convey the screened materials away, the two guide plates 1-2 are fixedly connected to the upper part of the conveying and discharging box 1-1, the inner sides of the two guide plates 1-2 are positioned on the upper part of the material enclosing plate 5-1, the materials can be guided into the material enclosing plate 5-1, when the crushed material enters the material enclosing plate 5-1, the two vibrating motors 5-5 are started, the vibrating rods 5-6 generate vibration, the material with the granularity smaller than the diameter of the holes on the screen 5-2 is sieved, falls on the conveying belt and is conveyed to finish the discharge of qualified products, after screening is finished, starting a discharging motor 5-7, rotating a discharging connecting shaft 5-8 to turn down a screen 5-2, unloading materials with the granularity larger than the diameter of holes on the screen 5-2, and dropping the materials onto a conveying belt to finish discharging unqualified products.

Of course, the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and the changes, modifications, additions or replacements made by those skilled in the art within the scope of the present invention also belong to the protection scope of the present invention.

Claims

1. The utility model provides a ground reducing mechanism, includes conveying discharge mechanism (1), its characterized in that: this ground reducing mechanism is still including smashing case (2), crushing hammer (3), crushing guardrail (4) and shale shaker (5), and crushing hammer (3) rotate to be connected on smashing case (2), smashes case (2) fixed connection in the upper end of conveying discharge mechanism (1), smashes guardrail (4) fixed connection on smashing case (2), and shale shaker (5) fixed connection is in conveying discharge mechanism (1).

2. The rock-soil crushing device according to claim 1, characterized in that: the conveying and discharging mechanism (1) comprises a conveying and discharging box (1-1), guide plates (1-2), a conveying motor (1-3) and rotating shafts (1-4), wherein the two rotating shafts (1-4) are rotatably connected into the conveying and discharging box (1-1), the two guide plates (1-2) are fixedly connected into the conveying and discharging box (1-1), the rotating shaft (1-4) located at the right end is fixedly connected onto an output shaft of the conveying motor (1-3), and the two rotating shafts (1-4) are connected through belt transmission.

3. The rock-soil crushing device according to claim 2, characterized in that: the crushing box (2) comprises an installation box (2-1) and a feeding port (2-2), the installation box (2-1) is fixedly connected to the upper end of the conveying discharging box (1-1), and the feeding port (2-2) is fixedly connected with the installation box (2-1).

4. The rock-soil crushing device according to claim 3, characterized in that: the smashing hammer (3) comprises a rotating motor (3-1), a connecting wheel (3-2), smashing plates (3-3) and a connecting shaft (3-4), the rotating motor (3-1) is fixedly connected to an installation box (2-1), the connecting shaft (3-4) is rotatably connected to the installation box (2-1), the connecting shaft (3-4) is fixedly connected to an output shaft of the rotating motor (3-1), the connecting wheel (3-2) is fixedly connected to the connecting shaft (3-4), and the smashing plates (3-3) are all fixedly connected to the connecting wheel (3-2).

5. The rock-soil crushing device according to claim 4, characterized in that: the smashing guardrail (4) comprises an inlet guard plate (4-1), a guard plate (4-2), a discharging plate (4-3), a discharging motor (4-4) and a discharging shaft (4-5), wherein the inlet guard plate (4-1) and the guard plate (4-2) are fixedly connected in a mounting box (2-1), the discharging motor (4-4) is fixedly connected on the mounting box (2-1), the discharging shaft (4-5) is rotatably connected in the mounting box (2-1), the discharging shaft (4-5) is fixedly connected on an output shaft of the discharging motor (4-4), the discharging shaft (4-5) is fixedly connected with the discharging plate (4-3), and the discharging plate (4-3) is slidably connected in the mounting box (2-1).

6. The rock-soil crushing device according to claim 5, characterized in that: the vibrating screen (5) comprises a material enclosing plate (5-1), a screen (5-2), sliding blocks (5-3), fixing rods (5-4), a vibrating motor (5-5), a vibrating rod (5-6), a discharging motor (5-7) and a discharging connecting shaft (5-8), wherein the two sliding blocks (5-3) are fixedly connected in the conveying discharging box (1-1), the two fixing rods (5-4) are respectively and slidably connected in the two sliding blocks (5-3), the two fixing rods (5-4) are respectively and fixedly connected on the material enclosing plate (5-1), the screen (5-2) is slidably connected with the material enclosing plate (5-1), the discharging motor (5-7) is fixedly connected on the material enclosing plate (5-1), the two vibrating motors (5-5) are both and fixedly connected in the conveying discharging box (1-1), the two vibrating rods (5-6) are respectively and fixedly connected to the two vibrating motors (5-5), the two vibrating rods (5-6) are fixedly connected to the material enclosing plate (5-1), the discharging connecting shaft (5-8) is fixedly connected to an output shaft of the discharging motor (5-7), and the discharging connecting shaft (5-8) is fixedly connected to the screen (5-2).