CN111871568A

CN111871568A - Efficient building site is broken and integrative device of stirring

Info

Publication number: CN111871568A
Application number: CN202010712203.9A
Authority: CN
Inventors: 卢新亮
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-07-22
Filing date: 2020-07-22
Publication date: 2020-11-03

Abstract

The invention relates to the technical field of engineering manufacturing instruments, in particular to a high-efficiency integrated device for crushing and stirring in a construction site. The invention comprises a stirring carrying tank, wherein a spraying material carrying box is welded on one side of the stirring carrying tank, a lateral carrying plate is welded at one end of the spraying material carrying box, and a motor is fixed at one end of the lateral carrying plate through a screw. According to the invention, through the design of the linkage transmission driving structure and the integrated crushing and stirring, the device achieves the integrated driving of crushing treatment and stirring treatment through single output power, the formed power is driven separately, firstly, the efficiency waste in the transmission process is reduced through integration, the budget of a power module is saved, the service performance of the device is greatly improved, the manufacturing cost is reduced, and through the linkage design of the double crushing structure, the device can perform double crushing and screening on the knot material simultaneously, so that the integral use efficiency of the device is greatly improved.

Description

Efficient building site is broken and integrative device of stirring

Technical Field

The invention relates to the technical field of engineering manufacturing instruments, in particular to a high-efficiency integrated device for crushing and stirring in a construction site.

Background

Along with the rapid development of society, more and more building sites are offered and are adopted neotype intelligent operation instrument to carry out the processing to the building engineering raw materials, wherein just including knot board breaker and agitating unit, because these two kinds of devices all are the basic device of raw and other materials processing, often by application and most of building sites, however, current device all is the separation design, lead to the power module design to be the separation design, the cost is higher and still need a large amount of time in the transfer process, lead to efficiency lower, and be the independent breakage of unijunction structure in the crushing process, crushing efficiency is low.

SUMMARY OF THE PATENT FOR INVENTION

The invention aims to provide a high-efficiency construction site crushing and stirring integrated device, which solves the existing problems: the existing devices are all designed in a separated mode, so that the power module is designed in a separated mode, the manufacturing cost is high, a large amount of time is needed in the transferring process, and the efficiency is low.

In order to achieve the purpose, the invention adopts the following technical scheme:

a high-efficiency integrated device for site crushing and stirring comprises a stirring carrying tank, wherein a spraying carrying box is welded on one side of the stirring carrying tank, a lateral carrying plate is welded on one end of the spraying carrying box, a motor is fixed on one end of the lateral carrying plate through a screw, an output end of the motor is simultaneously and rotatably connected with an output driving belt wheel and a driving gear, the driving gear is located at one end of the output driving belt wheel, one side of the driving gear is meshed with a driven gear, a first transmission belt is sleeved on the peripheral side of the output driving belt wheel, a first matching driven belt wheel is sleeved on the other end of the first transmission belt, the output driving belt wheel is connected with the first matching driven belt wheel through a first transmission belt, a torque transmission rotating shaft is welded on one end of the first matching driven belt wheel, and a carrying wheel groove is formed in the peripheral side of the torque transmission rotating shaft, a second transmission belt is sleeved on the peripheral side surface of the carrying wheel groove, one end of the second transmission belt is sleeved with a second matching driven belt wheel, the torque transmission rotating shaft is connected with the second matching driven belt wheel through the second transmission belt, one end of the second matching driven belt wheel is rotatably connected with a driving bevel gear, and the top end of the driving bevel gear is connected with a driven bevel gear in a meshing manner;

the inner part of the driven bevel gear is rotatably connected with a rotating conduction rod, the outer side of the rotating conduction rod is rotatably connected with a rotating carrying box, the driving bevel gear and the driven bevel gear are both positioned in the rotating carrying box, the bottom end of the rotating conduction rod is rotatably connected with a driving bevel gear, a plurality of stirring rotating rods are welded on the peripheral side surface of the driving bevel gear, and the driving bevel gear and the stirring rotating rods are both positioned in the rotating carrying box;

the automatic material spraying device is characterized in that the output ends of the driving gear and the driven gear are rotatably connected with a matched crushing wheel, the matched crushing wheel is located inside the material spraying carrying box, a first screening blanking plate and a second screening blanking plate are welded inside the material spraying carrying box from top to bottom respectively, assembling support frames are welded on two sides of the material spraying carrying box, and a high-efficiency derivation crushing structure is fixed at the top ends of the assembling support frames.

Preferably, broken structure is derived to high efficiency includes cooperation dress bottom plate, spacing slide bar, location roof, eccentric drive wheel, two-way connection loop bar, derives clamp plate, atress scour protection shell, spring, two-way conduction power pole and quartering hammer plate, spacing slide bar welds respectively in the both sides of cooperation dress bottom plate, the top welding position roof of spacing slide bar, torque conduction pivot runs through the location roof and is connected with the eccentric drive wheel rotation, two-way connection loop bar has been cup jointed to one side of eccentric drive wheel, the bottom joint of two-way connection loop bar has the derivation clamp plate, the equal sliding connection in top and the bottom of two-way conduction power pole has atress scour protection shell, the inside of atress scour protection shell is fixed with the spring, is located the atress scour protection shell bottom welded connection of two-way conduction power pole bottom has the quartering hammer plate.

Preferably, both sides of the matching bottom plate are completely attached to the matching support frame, and the matching bottom plate is connected with the matching support frame through welding.

Preferably, the bottom welding of location roof has the extension locating plate, a plurality of roller bearings have been cup jointed in the outside of torque conduction pivot, torque conduction pivot is connected through roller bearing with extension locating plate and eccentric drive wheel.

Preferably, the top end of the derivation pressing plate is welded with two matching connecting plates, a positioning and clamping through hole is formed in the matching connecting plates, and one side of the eccentric transmission wheel is welded with a connecting rotating pin.

Preferably, the top welding of two-way connection loop bar has the rotation conduction sleeve, it is clearance fit with being connected the rotating pin to rotate the conduction sleeve, the joint post has all been welded to the both sides of two-way connection loop bar bottom, the joint post is clearance fit with the location clamping through-hole.

Preferably, screening holes are formed in the second screening blanking plate and the first screening blanking plate, the diameter of the screening hole in the second screening blanking plate is a round hole of two centimeters, and the internal screening hole in the first screening blanking plate is a square hole of five square centimeters.

Preferably, a feeding guide plate is welded to one side of the spraying carrying box, and the inclination of the feeding guide plate is sixty degrees.

Preferably, the bottom of the stirring carrying tank is fixed with a discharge pipe, and the stirring carrying tank is connected with the discharge pipe in a welding manner.

Preferably, a material guiding slope is formed inside the spraying material carrying box, and the slope of the material guiding slope is forty-five degrees.

The invention has at least the following beneficial effects:

1. according to the invention, through the design of the linkage transmission driving structure and the integration of crushing and stirring, the device achieves the integration driving of crushing treatment and stirring treatment through single output power, and the formed power is divided into equal parts to be driven, so that the efficiency waste in the transmission process is reduced through integration, the budget of a power module is saved, the service performance of the device is greatly improved, and the manufacturing cost is reduced;

2. according to the invention, through the linkage design of the double-crushing structure, the device can be used for double-crushing and screening the junction material at the same time, so that the overall use efficiency of the device is greatly improved.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the patent of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the patent of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention as a whole;

FIG. 2 is a side view of the present invention in its entirety;

FIG. 3 is a partial cross-sectional view of the invention as a whole;

FIG. 4 is a schematic view of a partial structure of the linkage conduction driving structure according to the present invention;

fig. 5 is a half sectional view of a double crushing structure of the present invention;

fig. 6 is a partial structure diagram of the present invention for efficiently deriving the crushing structure.

In the figure: 1. a stirring carrying tank; 2. a discharge pipe; 3. rotating the carrying box; 4. a spray material carrying box; 5. laterally lapping a plate; 6. a motor; 7. an output driving pulley; 8. a driving gear; 9. a driven gear; 10. a first drive belt; 11. a first cooperating driven pulley; 12. a torque transmission shaft; 13. a second belt; 14. a second cooperating driven pulley; 15. a drive bevel gear; 16. a driven bevel gear; 17. rotating the conductive rod; 18. a stirring rotating rod; 19. a feeding guide plate; 20. matching with a crushing wheel; 21. a second screening blanking plate; 22. a first screening blanking plate; 23. Assembling a support frame; 24. assembling a bottom plate in a matching way; 25. a limiting sliding rod; 26. positioning a top plate; 27. An eccentric transmission wheel; 28. the loop bar is connected in a bidirectional way; 29. pushing a pressing plate; 30. a stressed scour protection housing; 31. a spring; 32. a bidirectional conductive force rod; 33. breaking the hammer plate; 34. and (5) efficiently deriving a crushing structure.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present invention and are not intended to limit the present invention.

Referring to fig. 1-6, a high-efficiency integrated device for site crushing and stirring comprises a stirring carrying tank 1, a spraying carrying tank 4 welded on one side of the stirring carrying tank 1, a lateral carrying plate 5 welded on one end of the spraying carrying tank 4, a motor 6 fixed on one end of the lateral carrying plate 5 through a screw, an output end of the motor 6 simultaneously and rotatably connected with an output driving pulley 7 and a driving gear 8, the driving gear 8 is positioned at one end of the output driving pulley 7, a driven gear 9 engaged with one side of the driving gear 8, a first driving belt 10 sleeved on the peripheral side of the output driving pulley 7, a first matching driven pulley 11 sleeved on the other end of the first driving belt 10, the output driving pulley 7 and the first matching driven pulley 11 are connected through the first driving belt 10, a torque transmission shaft 12 welded on one end of the first matching driven pulley 11, a carrying wheel groove formed on the peripheral side of the torque transmission shaft 12, a second transmission belt 13 is sleeved on the peripheral side surface of the carrying wheel groove, one end of the second transmission belt 13 is sleeved with a second matching driven belt wheel 14, the torque transmission rotating shaft 12 is connected with the second matching driven belt wheel 14 through the second transmission belt 13, one end of the second matching driven belt wheel 14 is rotatably connected with a driving bevel gear 15, and the top end of the driving bevel gear 15 is meshed with a driven bevel gear 16;

a rotary conducting rod 17 is rotatably connected inside the driven bevel gear 16, a rotary carrying box 3 is rotatably connected outside the rotary conducting rod 17, the driving bevel gear 15 and the driven bevel gear 16 are both positioned inside the rotary carrying box 3, the bottom end of the rotary conducting rod 17 is rotatably connected with the driving bevel gear 15, a plurality of stirring rotating rods 18 are welded on the peripheral side surface of the driving bevel gear 15, and the driving bevel gear 15 and the stirring rotating rods 18 are both positioned inside the rotary carrying box 3;

the equal swivelling joint of driving gear 8 and driven gear 9's output has the broken wheel of cooperation 20, and the broken wheel of cooperation 20 is located the inside of spouting material carrying case 4, and spouts the inside from the top down of material carrying case 4 and still weld respectively first screening blanking plate 22 and second screening blanking plate 21, spouts the both sides of material carrying case 4 and all welds and join in marriage dress support frame 23, joins in marriage the top of dress support frame 23 and is fixed with high-efficient broken structure 34 of deriving.

The scheme has the following working processes:

feeding and injecting water into the spraying material carrying box 4 through the feeding guide plate 19, the fed material is slid to the first screening blanking plate 22, at this time, the output driving belt wheel 7 and the driving gear wheel 8 are driven by the output of the motor 6 to rotate simultaneously, the driving gear wheel 8 drives the driven gear wheel 9 to rotate synchronously through meshing, the matched crushing wheel 20 and the matched crushing wheel 20 are subjected to contra-rotating crushing to form second crushing preparation, the torque of the output driving belt wheel 7 is transmitted to the first matched driven belt wheel 11 through the first driving belt 10, the torque transmission rotating shaft 12 is driven to rotate through the first matched driven belt wheel 11, the connection and matching of the torque transmission rotating shaft 12 and the eccentric transmission wheel 27 enable the eccentric transmission wheel 27 to rotate under the driving of the torque transmission rotating shaft 12, and the eccentric transmission wheel 27 can form the highest point and the lowest point in the rotating process due to the design of the eccentric circle form of the eccentric transmission wheel 27, at the highest point, the whole pushing and guiding pressure plate 29 is pushed to move upwards through the connecting belt of the two-way connecting loop bar 28, so that the breaking hammer plate 33 is lifted to be ready for smashing and pressing, when the eccentric transmission wheel 27 rotates to the lowest point, the pushing and pushing pressure plate 29 is pushed to drive the breaking hammer plate 33 to smash and press downwards, the bidirectional pushing and pushing of the bidirectional conduction force rod 32 can form conduction pushing and pressing in cooperation with the sliding of the early-stressed anti-impact shell 30, the reaction force formed after smashing and pressing is pushed and compressed to the inside of the spring 31, the elastic potential energy compressed by the spring 31 is utilized to offset the impact, the service life of the device is ensured, forming primary crushing after smashing and pressing the material combining plate at the first screening blanking plate 22, enabling fragments crushed to be of a proper size to enter the matched crushing wheel 20 through the first screening blanking plate 22, completing secondary crushing by rotation of the matched crushing wheel 20, and enabling mixed water flow of a proper size to enter the stirring and carrying tank 1 through the second screening blanking plate 21 and the material spraying carrying box 4;

through the conduction of second drive belt 13, conduct the torque of torque conduction pivot 12 department to second cooperation driven pulley 14, drive bevel gear 15 through second cooperation driven pulley 14 and rotate, utilize drive bevel gear 15 to be connected with driven bevel gear 16's meshing for driven bevel gear 16 obtains the torque, drives and rotates conduction pole 17 and accomplish rotatoryly, makes to rotate conduction pole 17 and drive bevel gear 15 and stir dwang 18 and form the stirring.

According to the working process, the following steps are known:

Further, the efficient derivation crushing structure 34 comprises a matching bottom plate 24, a limiting sliding rod 25, a positioning top plate 26, an eccentric transmission wheel 27, a two-way connecting sleeve rod 28, a derivation pressing plate 29, a stress anti-impact shell 30, a spring 31, a two-way conductive force rod 32 and a crushing hammer plate 33, wherein the limiting sliding rod 25 is respectively welded on two sides of the matching bottom plate 24, the positioning top plate 26 is welded on the top end of the limiting sliding rod 25, a torque conductive rotating shaft 12 penetrates through the positioning top plate 26 to be rotatably connected with the eccentric transmission wheel 27, the two-way connecting sleeve rod 28 is sleeved on one side of the eccentric transmission wheel 27, the derivation pressing plate 29 is clamped at the bottom end of the two-way connecting sleeve rod 28, the stress anti-impact shell 3 is slidably connected at the top end and the bottom end of the two-way conductive force rod 32, the spring 31 is fixed inside the stress anti-impact shell 30, the crushing hammer plate 33 is welded at the bottom end, the first smashing, pressing and crushing are convenient to form, and the situation that the caking materials are too large and are inconvenient to put into the second wheel for crushing is avoided;

furthermore, both sides of the matching bottom plate 24 are completely attached to the matching support frame 23, and the matching bottom plate 24 is connected with the matching support frame 23 through welding, so that the matching bottom plate 24 is convenient to position and assemble;

furthermore, an extension positioning plate is welded at the bottom end of the positioning top plate 26, a plurality of roller bearings are sleeved outside the torque transmission rotating shaft 12, and the torque transmission rotating shaft 12, the extension positioning plate and the eccentric transmission wheel 27 are connected through the roller bearings, so that the torque can be stably output;

furthermore, two matching connecting plates are welded at the top end of the derivation pressing plate 29, positioning and clamping through holes are formed in the matching connecting plates, a connecting rotating pin is welded at one side of the eccentric transmission wheel 27, so that convenience is brought to the operation, a rotating conduction sleeve is welded at the top end of the bidirectional connection loop bar 28, the rotating conduction sleeve is in clearance fit with the connecting rotating pin, clamping columns are welded at two sides of the bottom end of the bidirectional connection loop bar 28, the clamping columns are in clearance fit with the positioning and clamping through holes, so that derivation power transmission is facilitated, and good reciprocating punching and smashing movement is formed;

furthermore, screening holes are formed in the second screening blanking plate 21 and the first screening blanking plate 22, the diameter of the screening hole in the second screening blanking plate 21 is a round hole of two centimeters, and the internal screening hole in the first screening blanking plate 22 is a square hole of five square centimeters, so that screening and blanking after crushing are facilitated;

furthermore, a feeding guide plate 19 is welded on one side of the spraying material carrying box 4, the inclination of the feeding guide plate 19 is sixty degrees, and convenient feeding and water injection are facilitated;

further, a discharge pipe 2 is fixed at the bottom end of the stirring carrying tank 1, and the stirring carrying tank 1 is connected with the discharge pipe 2 in a welding manner, so that the finally stirred and formed discharge is facilitated;

further, the material guide slope is formed inside the spraying material carrying box 4, the inclination of the material guide slope is forty-five degrees, and discharging guiding after crushing is facilitated.

The foregoing shows and describes the general principles of the present patent, its essential features, and its advantages. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are only for the purpose of illustrating the principles of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims. The scope of the invention patent claims is defined by the appended claims and their equivalents.

Claims

1. The utility model provides an efficient broken and integrative device of stirring in building site, carries on jar (1) including the stirring, its characterized in that, the stirring carries on jar (1) one side welding has and spouts material and carries on case (4), the one end welding that spouts material and carry on case (4) has side direction carry-on board (5), the one end of side direction carry-on board (5) has motor (6) through the fix with screw, the output of motor (6) rotates simultaneously and is connected with output driving pulley (7) and driving gear (8), driving gear (8) are located the one end of output driving pulley (7), one side meshing of driving gear (8) is connected with driven gear (9), the week side cover of output driving pulley (7) has cup jointed first drive belt (10), first cooperation driven pulley (11) have been cup jointed to the other end of first drive belt (10), output driving pulley (7) and first cooperation driven pulley (11) link to each other through first drive belt (10) A torque transmission rotating shaft (12) is welded at one end of the first matching driven pulley (11), a carrying wheel groove is formed in the peripheral side face of the torque transmission rotating shaft (12), a second driving belt (13) is sleeved on the peripheral side face of the carrying wheel groove, a second matching driven pulley (14) is sleeved at one end of the second driving belt (13), the torque transmission rotating shaft (12) is connected with the second matching driven pulley (14) through the second driving belt (13), a driving bevel gear (15) is rotatably connected at one end of the second matching driven pulley (14), and a driven bevel gear (16) is meshed and connected at the top end of the driving bevel gear (15);

the internal of the driven bevel gear (16) is rotatably connected with a rotating conduction rod (17), the outer side of the rotating conduction rod (17) is rotatably connected with a rotating carrying box (3), the driving bevel gear (15) and the driven bevel gear (16) are both positioned in the rotating carrying box (3), the bottom end of the rotating conduction rod (17) is rotatably connected with the driving bevel gear (15), a plurality of stirring rotating rods (18) are welded on the peripheral side surface of the driving bevel gear (15), and the driving bevel gear (15) and the stirring rotating rods (18) are both positioned in the rotating carrying box (3);

the utility model discloses a material spraying and conveying device, including driving gear (8), driven gear (9), cooperation crushing wheel (20) are located the inside of spraying material carrying case (4), just the inside from the top down of spraying material carrying case (4) still has welded first screening blanking plate (22) and second screening blanking plate (21) respectively, the both sides of spraying material carrying case (4) all have welded join in marriage dress support frame (23), the top of joining in marriage dress support frame (23) is fixed with high-efficient derivation broken structure (34).

2. The efficient integrated device for site crushing and stirring as claimed in claim 1, wherein the efficient derivation crushing structure (34) comprises a matching bottom plate (24), a limiting sliding rod (25), a positioning top plate (26), an eccentric transmission wheel (27), a bidirectional connecting sleeve rod (28), a derivation pressing plate (29), a stress anti-impact shell (30), a spring (31), a bidirectional conducting force rod (32) and a crushing hammer plate (33), the limiting sliding rod (25) is respectively welded on two sides of the matching bottom plate (24), the positioning top plate (26) is welded on the top end of the limiting sliding rod (25), the torque conducting rotating shaft (12) penetrates through the positioning top plate (26) to be rotatably connected with the eccentric transmission wheel (27), the bidirectional connecting sleeve rod (28) is sleeved on one side of the eccentric transmission wheel (27), and the derivation pressing plate (29) is clamped on the bottom end of the bidirectional connecting sleeve rod (28), the top and the equal sliding connection in bottom of two-way conduction power pole (32) have atress scour protection shell (30), the inside of atress scour protection shell (30) is fixed with spring (31), is located atress scour protection shell (30) bottom welded connection of two-way conduction power pole (32) bottom has broken hammer plate (33).

3. A high-efficiency integrated device for site crushing and stirring as claimed in claim 1, wherein both sides of the fitting bottom plate (24) are completely attached to the fitting support frame (23), and the fitting bottom plate (24) is connected with the fitting support frame (23) by welding.

4. The efficient integrated device for site crushing and stirring as claimed in claim 2, wherein an extension positioning plate is welded at the bottom end of the positioning top plate (26), a plurality of roller bearings are sleeved on the outer side of the torque transmission rotating shaft (12), and the torque transmission rotating shaft (12), the extension positioning plate and the eccentric transmission wheel (27) are connected through the roller bearings.

5. The efficient integrated device for site crushing and stirring as claimed in claim 2, wherein two matching connecting plates are welded at the top end of the derivation pressing plate (29), positioning and clamping through holes are formed inside the matching connecting plates, and a connecting rotating pin is welded at one side of the eccentric transmission wheel (27).

6. The efficient integrated device for site crushing and stirring as claimed in claim 5, wherein a rotating conduction sleeve is welded at the top end of the bidirectional connection sleeve rod (28) and is in clearance fit with a connection rotating pin, clamping columns are welded at both sides of the bottom end of the bidirectional connection sleeve rod (28) and are in clearance fit with the positioning and clamping through holes.

7. The efficient integrated device for site crushing and stirring as claimed in claim 1, wherein the second screening blanking plate (21) and the first screening blanking plate (22) are provided with screening holes, the diameter of the screening holes in the second screening blanking plate (21) is a circular hole of two centimeters, and the diameter of the screening holes in the first screening blanking plate (22) is a square hole of five square centimeters.

8. A high-efficiency integrated site crushing and stirring device as claimed in claim 1, wherein a feeding guide plate (19) is welded to one side of the material spraying carrying box (4), and the inclination of the feeding guide plate (19) is sixty degrees.

9. The efficient integrated site crushing and stirring device as claimed in claim 1, wherein a discharge pipe (2) is fixed at the bottom end of the stirring carrying tank (1), and the stirring carrying tank (1) is connected with the discharge pipe (2) through welding.

10. The efficient integrated device for crushing and stirring at construction sites as claimed in claim 1, wherein a material guiding slope is formed inside the material spraying carrying box (4), and the slope of the material guiding slope is forty-five degrees.