CN110898964A - Building wall coating grinding device - Google Patents

Abstract

In order to solve the technical problem, the invention relates to a paint grinding device, in particular to a building wall paint grinding device which comprises an adjustable proportion feeding device, a crushing device and a grinding and stirring device, wherein the proportion of discharged paint and the single paint discharging speed can be regulated and controlled through the adjustable proportion feeding device, the crushing device extrudes and crushes the paint in a grinding mode, the grinding and stirring device grinds paint blocks reaching the size specification and then has the functions of stirring and the like, the adjustable proportion feeding device is installed and fixed on the crushing device, and the crushing device is installed and fixed on the grinding and stirring device.

Description

Building wall coating grinding device

Technical Field

The invention relates to paint grinding equipment, in particular to building wall paint grinding equipment.

Background

In the development process of people, the level of all aspects of human beings is improved, in order to be matched with the progress of the human beings, civil engineering is continuously built, the urban appearance is greatly improved, and in order to increase the attractiveness of the wall surface, the wall surface is coated with paint, so that the building wall surface paint grinding equipment is invented.

Disclosure of Invention

The invention relates to paint grinding equipment, in particular to building wall paint grinding equipment, which can regulate and control the proportion of discharged paint and the single paint discharging speed through an adjustable proportion feeding device, can regulate and control the discharging speed of discharged paint, can regulate and control the discharging speed of the discharged paint, can crush the paint in an extrusion and grinding mode through a crushing device, and has the functions of grinding and then stirring paint blocks which reach the size specification through a grinding and stirring device.

In order to solve the technical problem, the invention relates to a paint grinding device, in particular to a building wall paint grinding device which comprises an adjustable proportion feeding device, a crushing device and a grinding and stirring device, wherein the proportion of discharged paint and the single paint discharging speed can be regulated and controlled through the adjustable proportion feeding device, the crushing device extrudes and crushes the paint in a grinding mode, the grinding and stirring device grinds paint blocks reaching the size specification and then has the functions of stirring and the like, the adjustable proportion feeding device is installed and fixed on the crushing device, and the crushing device is installed and fixed on the grinding and stirring device.

As a further optimization of the technical scheme, the adjustable proportion feeding device of the building wall coating grinding equipment comprises a solid material storage box, a rotating shaft, a discharging wheel, a solid material storage box I, a rotating shaft I, a discharging wheel I, a connecting column, an adjusting box, a solid material storage box baffle groove I, a solid material storage box baffle groove II, a solid material storage box baffle groove I, a solid material storage box baffle groove II, a rotating connecting rod I, a motor, an output belt wheel, a transmission belt, a transmission shaft, a transmission receiving belt wheel, an output pinion, an output gear wheel, a transmission sleeve, a receiving gear wheel, a receiving pinion, an adjusting sliding ring, an adjusting rod, an output pinion I, a transmission sleeve I, a receiving gear wheel I, a receiving pinion I, an adjusting sliding ring I and an adjusting rod I, wherein the rotating shaft is rotatably arranged in the solid material storage box, the discharging wheel is installed and fixed on the rotating shaft, one rotating shaft is rotatably installed inside the first solid material storage box, the first discharging wheel is installed and fixed on the first rotating shaft, the connecting column is installed and fixed on the first solid material storage box and the first solid material storage box, the adjusting box is installed and fixed on the connecting column, the first solid material storage box blocking groove is arranged on the adjusting box, the second solid material storage box blocking groove is arranged on the adjusting box, the first solid material storage box blocking groove is arranged on the adjusting box, the rotating connecting rod is slidably installed inside the transmission sleeve, the rotating connecting rod is installed and fixed on the rotating shaft, the first rotating connecting rod is installed and fixed on the first rotating shaft, the first rotating connecting rod is slidably installed inside the transmission sleeve, the motor is installed and fixed inside the adjusting box, the output belt wheel is installed and fixed, the transmission shaft is rotatably installed in the adjusting box, the transmission receiving belt wheel is fixedly installed on the transmission shaft, the output small gear is fixedly installed on the transmission shaft, the output large gear is fixedly installed on the transmission shaft, the transmission sleeve is rotatably installed in the adjusting box, the receiving large gear is fixedly installed on the transmission sleeve, the receiving small gear is fixedly installed on the transmission sleeve, the adjusting sliding ring is rotatably installed on the transmission sleeve, the adjusting rod is fixedly installed on the adjusting sliding ring, the output small gear is fixedly installed on the transmission shaft, the output large gear is fixedly installed on the transmission shaft, the transmission sleeve is rotatably installed in the adjusting box, the receiving large gear is fixedly installed on the transmission sleeve, the receiving small gear is fixedly installed on the transmission sleeve, the adjusting sliding ring is rotatably installed on the transmission sleeve, and the adjusting rod is fixedly installed on the.

As a further optimization of the technical scheme, the crushing device of the building wall coating grinding equipment comprises a crushing cylinder, a feed inlet, a discharge sieve hole, a second rotating shaft, a second motor, a bevel gear, a first half bevel gear, a second half bevel gear, an extrusion semi-cylinder, a third motor, a third bevel gear, a third transmission shaft, a third receiving bevel gear, a third rotating disc, a toggle column, a top tooth surface swinging block, a rack, an extrusion plate, a fourth motor, a fourth output gear, a fourth transmission shaft, a fourth receiving gear, a fourth rotating half bevel gear, a fifth rotating half bevel gear, a fourth connecting shaft, a fourth receiving bevel gear and a grinding disc, wherein a solid material storage box is fixedly arranged on the crushing cylinder, the first solid material storage box is fixedly arranged on the crushing cylinder, the feed inlet is arranged on the crushing cylinder, the discharge sieve hole is arranged on the crushing cylinder, the second rotating shaft is rotatably arranged on the crushing cylinder, the second motor and the bevel gear, a first half bevel gear is fixedly arranged on a second rotating shaft, a second half bevel gear is fixedly arranged on the second rotating shaft, an extrusion semi-cylinder is fixedly arranged on the second rotating shaft, a third motor is fixedly arranged inside the extrusion semi-cylinder, a third bevel gear is fixedly arranged on a third motor, a third transmission shaft is rotatably arranged on the extrusion semi-cylinder, a third receiving bevel gear is fixedly arranged on a third transmission shaft, a third rotating disc is fixedly arranged on the third transmission shaft, a toggle column is fixedly arranged on the third rotating disc, the toggle column is slidably arranged inside a top end tooth surface swinging block, the top end tooth surface swinging block is rotatably arranged inside the extrusion semi-cylinder, a rack is meshed with the top end tooth surface swinging block, the rack is slidably arranged inside the extrusion semi-cylinder, an extrusion plate is fixedly arranged on the rack, a fourth motor is fixedly arranged inside a crushing cylinder, a fourth output gear is, the four-rotation transmission shaft is installed inside the crushing barrel, the four receiving gear is installed and fixed on the four transmission shaft, the four rotating half bevel gear is installed and fixed on the four transmission shaft, the five rotating half bevel gear is installed and fixed on the four transmission shaft, the four connecting shaft is installed and installed inside the crushing barrel in a rotating mode, and the four receiving bevel gear is installed and fixed on the four connecting shaft grinding disc in a installing mode.

As a further optimization of the technical scheme, the grinding and stirring device of the building wall coating grinding equipment comprises a grinding and stirring box, a feed inlet III, a grinding discharge hole, a mounting frame III, a mounting plate III, a motor VI, a bevel gear VI, a rotating shaft VI, a receiving bevel gear VI, a rotating disc VI, a toggle column VI, a trapezoidal push rod, a push bolt, a grinding hemisphere, a spring VI, a stirring leg, a grinding motor and a transmission gear VII, wherein a crushing cylinder is fixedly arranged on the grinding and stirring box, the feed inlet III is arranged on the grinding and stirring box, the grinding discharge hole is arranged on the grinding and stirring box, the mounting frame III is fixedly arranged inside the grinding and stirring box, the mounting plate III is fixedly arranged inside the grinding and stirring box, the motor VI is fixedly arranged on the mounting frame III, the bevel gear VI is fixedly arranged on the motor VI, the bevel gear VI is meshed with the receiving bevel gear VI, six installation of receiving bevel gear are fixed on six moving shafts, six installation of rolling disc are fixed on six moving shafts, six installation of stirring post are fixed on six rolling discs, six sliding installations of stirring post are on trapezoidal catch bar, trapezoidal catch bar sliding installation is on three mounting brackets, the installation of pushing bolt is fixed on trapezoidal catch bar, grinding hemisphere sliding installation is on pushing bolt, six springs are installed inside grinding hemisphere, the stirring leg is articulated on grinding hemisphere, grinding motor installation is fixed on three mounting brackets, seven installation of drive gear is fixed on grinding motor, seven drive gear and grinding hemisphere meshing.

As further optimization of the technical scheme, the number of the feed inlets of the grinding and stirring device of the building wall coating grinding equipment is two, and the number of the stirring legs is four.

The building wall paint grinding equipment has the beneficial effects that:

the invention relates to paint grinding equipment, in particular to building wall paint grinding equipment, which realizes the functions of regulating and controlling the proportion of discharged paint and the single paint discharging speed through an adjustable proportion feeding device, regulating and discharging and lifting speed, extruding and grinding the paint by a crushing device, grinding and stirring paint blocks reaching the size specification by a grinding and stirring device, and the like.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

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

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

Fig. 3 is a third schematic view of the overall structure of the present invention.

FIG. 4 is a schematic structural diagram of an adjustable-ratio feeding device according to the present invention.

FIG. 5 is a schematic structural diagram of an adjustable-ratio feeding device according to the present invention.

FIG. 6 is a third schematic structural view of an adjustable-ratio feeding device of the present invention.

FIG. 7 is a fourth schematic structural view of the adjustable-ratio feeding device of the present invention.

FIG. 8 is a schematic structural diagram of an adjustable-ratio feeding device according to the present invention.

Fig. 9 is a schematic structural diagram six of the adjustable-ratio feeding device of the present invention.

Fig. 10 is a first structural schematic diagram of the crushing device of the invention.

Fig. 11 is a schematic structural diagram of a crushing device of the invention.

Fig. 12 is a third structural schematic diagram of the crushing device of the invention.

Fig. 13 is a fourth schematic structural view of the crushing device of the present invention.

Fig. 14 is a fifth structural schematic diagram of the crushing device of the invention.

Fig. 15 is a first schematic structural view of the polishing stirring apparatus of the present invention.

Fig. 16 is a second schematic structural view of the polishing and stirring apparatus of the present invention.

Fig. 17 is a third schematic structural view of the polishing and stirring apparatus of the present invention.

In the figure: the proportion-adjustable feeding device 1; a solid material storage box 1-1; a rotating shaft 1-2; 1-3 of a discharging wheel; 1-4 of a solid material storage box; 1-5 of a first rotating shaft; 1-6 parts of a first discharging wheel; 1-7 of connecting columns; 1-8 of an adjusting box; a first blocking groove 1-9 of the solid material storage box; a second blocking groove 1-10 of the solid material storage box; a blocking groove I1-11 of the solid material storage box; a blocking groove II 1-12 of the solid material storage box; rotating the connecting rods 1-13; rotating the first connecting rod 1-14; 1-15 of a motor; an output pulley 1-16; 1-17 of a transmission belt; a drive shaft 1-18; drive receiving pulleys 1-19; output pinions 1-20; an output gearwheel 1-21; transmission sleeves 1-22; receiving the bull gear 1-23; receiving pinions 1-24; adjusting the sliding ring 1-25; adjusting rods 1-26; output pinions 1-27; the output gearwheel I is 1-28; a first transmission sleeve 1-29; receiving a bull gear 1-30; receiving pinions 1-21; 1-32 of the adjusting sliding ring; adjusting rods I1-33; a crushing device 2; 2-1 of a crushing cylinder; a feed inlet 2-2; 2-3 discharging sieve pores; 2-4 of a second rotating shaft; 2-5 of a second motor; 2-6 parts of bevel gears; 2-7 parts of a half bevel gear I; 2-8 parts of a half bevel gear II; extruding the semi-cylinders 2-9; 2-10 parts of a third motor; bevel gears three 2-11; a third transmission shaft 2-12; receiving bevel gears three 2-13; rotating discs three 2-14; stirring the column for 2-15; top tooth surface swing blocks 2-16; racks 2-17; 2-18 parts of an extrusion plate; 2-19 parts of a motor; output gear four 2-20; a transmission shaft IV 2-21; receiving gears four 2-22; rotating the half bevel gear four by 2-23; rotating the half bevel gear five by 2-24; connecting shaft IV 2-25; receiving bevel gears four 2-26; 2-27 of a grinding disc; a grinding and stirring device 3; 3-1 of a grinding stirring box; a feed inlet III is 3-2; grinding the discharge holes 3-3; mounting frame III 3-4; mounting a third mounting plate 3-5; motor six 3-6; six bevel gears 3-7; rotating shaft six 3-8; receiving bevel gears six 3-9; rotating a disc six by 3-10; stirring the column six by 3-11; 3-12 parts of a trapezoidal push rod; pushing the plug 3-13; grinding hemispheres 3-14; six springs 3-15; 3-16 parts of stirring legs; grinding motors 3-17; drive gears seven 3-18.

Detailed Description

The first embodiment is as follows:

in order to solve the technical problems, the invention relates to a paint grinding device, in particular to a building wall paint grinding device, which comprises an adjustable proportion feeding device 1, a crushing device 2 and a grinding and stirring device 3, wherein the proportion of discharged paint and the single speed of discharged paint can be regulated and controlled through the adjustable proportion feeding device, the crushing device extrudes and crushes the paint in a grinding mode, the grinding and stirring device grinds paint blocks reaching size specifications and then performs functions of stirring and the like, the adjustable proportion feeding device 1 is fixedly arranged on the crushing device 2, and the crushing device 2 is fixedly arranged on the grinding and stirring device 3.

The second embodiment is as follows:

this embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, and 17, and further described as an embodiment, the architectural wall coating grinding apparatus is characterized in that: the adjustable proportional feeding device 1 comprises a solid material storage box 1-1, a rotating shaft 1-2, a discharging wheel 1-3, a solid material storage box 1-4, a rotating shaft I1-5, a discharging wheel I1-6, a connecting column 1-7, an adjusting box 1-8, a solid material storage box baffle groove I1-9, a solid material storage box baffle groove II 1-10, a solid material storage box baffle groove I1-11, a solid material storage box baffle groove II 1-12, a rotating connecting rod 1-13, a rotating connecting rod I1-14, a motor 1-15, an output belt wheel 1-16, a transmission belt 1-17, a transmission shaft 1-18, a transmission receiving belt wheel 1-19, an output pinion 1-20, an output gearwheel 1-21, a transmission sleeve 1-22, a receiving gearwheel 1-23, an output gearwheel 1-23, a transmission belt pulley 1-17, a transmission shaft, 1-24 parts of receiving pinion gears, 1-25 parts of adjusting sliding rings, 1-26 parts of adjusting rods, 1-27 parts of first output pinion gears, 1-28 parts of first output bull gears, 1-29 parts of transmission sleeves, 1-30 parts of first receiving bull gears, 1-21 parts of first receiving pinion gears, 1-32 parts of adjusting sliding rings and 1-33 parts of adjusting rods, wherein motors 1-15 of an adjustable proportional feeding device 1 drive output belt wheels 1-16 to rotate, the output belt wheels 1-16 drive transmission receiving belt wheels 1-19 to rotate through transmission belts 1-17, the transmission receiving belt wheels 1-19 drive transmission shafts 1-18 to rotate, the transmission shafts 1-18 drive the 1-20 parts of the output pinion gears, 1-21 parts of the output bull gears, 1-27 parts of the output pinion gears and 1-28 parts of the output bull gears to rotate, then the output rotation conditions of the rotating connecting rods 1-13 and the rotating connecting rods 1-14 are changed by adjusting the positions of the adjusting rods 1-26 and the adjusting rods 1-33, when the adjusting rods 1-26 are positioned to adjust the rods 1-26, the output small gears 1-20 are meshed with the receiving large gears 1-23, the output small gears 1-20 drive the receiving large gears 1-23 to rotate, the receiving large gears 1-23 drive the transmission sleeves 1-22 to rotate at a low speed, the transmission sleeves 1-22 drive the rotating connecting rods 1-13 to rotate, when the adjusting rods 1-26 are positioned in the grade grooves two 1-10 of the solid material storage box, the rotating connecting rods 1-13 rotate at a high speed, and similarly, when the adjusting rods 1-33 are positioned in the grade grooves one 1-11 of the solid material storage box, the rotating connecting rods one 1-14 output at, when the first adjusting rods 1-33 are positioned in the first baffle grooves 1-12 of the solid material storage box, the first rotating connecting rods 1-14 output at high speed and rotate, so that a lower output combination is formed, and the following steps are carried out in sequence: the device comprises a rotating shaft 1-2, a rotating shaft 1-5, a rotating shaft 1-2 and a rotating shaft 1-5 are respectively driven to rotate by a rotating connecting rod 1-13 and a rotating connecting rod 1-14, a solid material storage box 1-1 and a solid material storage box 1-4 are discharged into a crushing device 2 by driving the rotating shaft 1-2 and the rotating shaft 1-5 to respectively drive a discharging wheel 1-3 and a discharging wheel 1-6 to rotate, the rotating shaft 1-2 is rotatably arranged in the solid material storage box 1-1, the discharging wheel 1-3 is fixedly arranged on the rotating shaft 1-2, the rotating shaft 1-5 is rotatably arranged in the solid material storage box 1-4, the discharging wheel 1-6 is fixedly arranged on the rotating shaft 1-5, the connecting column 1-7 is fixedly arranged on the solid material storage tank 1-1 and the solid material storage tank 1-4, the adjusting tank 1-8 is fixedly arranged on the connecting column 1-7, the solid material storage tank baffle groove 1-9 is arranged on the adjusting tank 1-8, the solid material storage tank baffle groove two 1-10 is arranged on the adjusting tank 1-8, the solid material storage tank baffle groove one 1-11 is arranged on the adjusting tank 1-8, the solid material storage tank baffle groove two 1-12 is arranged on the adjusting tank 1-8, the rotating connecting rod 1-13 is slidably arranged in the transmission sleeve 1-22, the rotating connecting rod 1-13 is fixedly arranged on the rotating shaft 1-2, the rotating connecting rod one 1-14 is fixedly arranged on the rotating shaft one 1-5, the rotating connecting rod one 1-14 is slidably arranged in the transmission sleeve one 1-29, the motors 1-15 are fixedly arranged in the adjusting boxes 1-8, the output belt wheels 1-16 are fixedly arranged on the motors 1-15, the transmission belts 1-17 are arranged on the output belt wheels 1-16 and the transmission receiving belt wheels 1-19, the transmission shafts 1-18 are rotatably arranged in the adjusting boxes 1-8, the transmission receiving belt wheels 1-19 are fixedly arranged on the transmission shafts 1-18, the output small gears 1-20 are fixedly arranged on the transmission shafts 1-18, the output large gears 1-21 are fixedly arranged on the transmission shafts 1-18, the transmission sleeves 1-22 are rotatably arranged in the adjusting boxes 1-8, the receiving large gears 1-23 are fixedly arranged on the transmission sleeves 1-22, the receiving small gears 1-24 are fixedly arranged on the transmission sleeves 1-22, the adjusting sliding rings 1-25 are rotatably arranged on the transmission sleeves 1-22, the adjusting rods 1-26 are fixedly arranged on the adjusting sliding rings 1-25, the output small gears 1-27 are fixedly arranged on the transmission shafts 1-18, the output large gears 1-28 are fixedly arranged on the transmission shafts 1-18, the transmission sleeves 1-29 are rotatably arranged in the adjusting boxes 1-8, the receiving large gears 1-30 are fixedly arranged on the transmission sleeves 1-29, the receiving small gears 1-21 are fixedly arranged on the transmission sleeves 1-29, the adjusting sliding rings 1-32 are rotatably arranged on the transmission sleeves 1-29, and the adjusting rods 1-33 are fixedly arranged on the adjusting sliding rings 1-32.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16 and 17, and the embodiment further describes the first embodiment, wherein the crushing device 2 comprises a crushing cylinder 2-1, a feed inlet 2-2, a discharge sieve pore 2-3, a second rotating shaft 2-4, a second motor 2-5, a bevel gear 2-6, a first half bevel gear 2-7, a second half bevel gear 2-8, an extrusion half cylinder 2-9, a third motor 2-10, a third bevel gear 2-11, a third transmission shaft 2-12, a third receiving bevel gear 2-13, a third rotating disc 2-14, a toggle cylinder 2-15, a top tooth surface swing block 2-16, a rack 2-17, an extrusion plate 2-18, a fourth motor 2-19, a third transmission shaft 2-12, a third receiving bevel gear 2-13, a third rotating disc 2-, 2-20 parts of an output gear four, 2-21 parts of a transmission shaft four, 2-22 parts of a receiving gear four, 2-23 parts of a rotating half bevel gear four, 2-24 parts of a rotating half bevel gear five, 2-25 parts of a connecting shaft four, 2-26 parts of a receiving bevel gear four and 2-27 parts of a grinding disc, 2-5 parts of a motor two drives a bevel gear 2-6 to rotate, 2-7 parts of the half bevel gear one drives a rotating shaft two 2-4 to rotate forwards when the bevel gear 2-6 is meshed with 2-7 parts of the half bevel gear one, 2-8 parts of the half bevel gear two drives the rotating shaft two 2-4 to rotate backwards when the bevel gear 2-6 is meshed with 2-8 parts of the half bevel gear two, so that the rotating shaft two 2-4 drives an extrusion semi-cylinder 2-9 to rotate and extrude coating in a reciprocating manner in the crushing cylinder 2-1, the bevel gear III 2-11 drives the receiving bevel gear III 2-13 to rotate, the receiving bevel gear III 2-13 drives the transmission shaft III 2-12 to rotate, the transmission shaft III 2-12 drives the rotating disc III 2-14 to rotate, the rotating disc III 2-14 pushes the top end tooth surface swinging block 2-16 to swing in a reciprocating manner through the toggle column 2-15, the top end tooth surface swinging block 2-16 drives the rack 2-17 to move in a reciprocating manner, the rack 2-17 drives the extrusion plate 2-18 to move in a reciprocating manner for secondary extrusion, meanwhile, the motor IV 2-19 drives the output gear IV 2-20 to rotate, the output gear IV 2-20 drives the receiving gear IV 2-22 to rotate, the receiving gear IV 2-22 drives the transmission shaft IV 2-21 to rotate, the transmission shaft IV 2-21 drives the rotating half bevel gear IV 2-23 and the rotating half bevel gear IV 2-24 to rotate, when the rotating half bevel gear four 2-23 is meshed with the receiving bevel gear four 2-26, the receiving bevel gear four 2-26 rotates forwards, when the rotating half bevel gear five 2-24 is meshed with the receiving bevel gear four 2-26, the receiving bevel gear four 2-26 rotates backwards, the receiving bevel gear four 2-26 drives the connecting shaft four 2-25 to rotate in a reciprocating way, the connecting shaft four 2-25 drives the grinding disc 2-27 to grind the coating, the ground coating falls into the grinding stirring box 3-1 through the discharge sieve holes 2-3, the solid material storage box 1-1 is fixedly arranged on the crushing cylinder 2-1, the solid material storage box 1-4 is fixedly arranged on the crushing cylinder 2-1, the feed port 2-2 is arranged on the crushing cylinder 2-1, the discharge sieve holes 2-3 are arranged on the crushing cylinder 2-1, a second rotating shaft 2-4 is rotatably arranged on the crushing cylinder 2-1, a second motor 2-5 and a bevel gear 2-6 are fixedly arranged on the second motor 2-5, a first half bevel gear 2-7 is fixedly arranged on the second rotating shaft 2-4, a second half bevel gear 2-8 is fixedly arranged on the second rotating shaft 2-4, an extrusion semi-cylinder 2-9 is fixedly arranged on the second rotating shaft 2-4, a third motor 2-10 is fixedly arranged inside the extrusion semi-cylinder 2-9, a third bevel gear 2-11 is fixedly arranged on a third motor 2-10, a third transmission shaft 2-12 is rotatably arranged on the extrusion semi-cylinder 2-9, a third receiving bevel gear 2-13 is fixedly arranged on a third transmission shaft 2-12, and a third rotating disc 2-14 is fixedly arranged on the third transmission shaft 2-12, a toggle column 2-15 is fixedly arranged on a third rotating disc 2-14, the toggle column 2-15 is slidably arranged inside a top end tooth surface swing block 2-16, the top end tooth surface swing block 2-16 is rotatably arranged inside an extrusion semi-cylinder 2-9, a rack 2-17 is meshed with the top end tooth surface swing block 2-16, the rack 2-17 is slidably arranged inside the extrusion semi-cylinder 2-9, an extrusion plate 2-18 is fixedly arranged on the rack 2-17, a motor four 2-19 is fixedly arranged inside a crushing cylinder 2-1, an output gear four 2-20 is fixedly arranged on a motor four 2-19, an output gear four 2-20 is meshed with a receiving gear four 2-22, a transmission shaft four 2-21 is rotatably arranged inside the crushing cylinder 2-1, and a receiving gear four 2-22 is fixedly arranged on a transmission shaft four 2-21, the four 2-23 rotating half bevel gears are fixedly arranged on the four 2-21 transmission shafts, the five 2-24 rotating half bevel gears are fixedly arranged on the four 2-21 transmission shafts, the four 2-25 connecting shafts are rotatably arranged in the crushing barrel 2-1, and the four 2-26 receiving bevel gears are fixedly arranged on the four 2-25 connecting shafts, and the 2-27 grinding discs are fixedly arranged on the four 2-25 connecting shafts.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, and the embodiment further describes the first embodiment, wherein the grinding and stirring device 3 comprises a grinding and stirring box 3-1, a feed inlet three 3-2, a grinding and discharge hole 3-3, a mounting frame three 3-4, a mounting plate three 3-5, a motor six 3-6, a bevel gear six 3-7, a rotating shaft six 3-8, a receiving bevel gear six 3-9, a rotating disc six 3-10, a toggle column six 3-11, a trapezoidal push rod 3-12, a push bolt 3-13, a grinding hemisphere 3-14, a spring six 3-15, a stirring leg 3-16, a grinding motor 3-17, and a transmission gear seven 3-18, then a motor six 3-6 drives a bevel gear six 3-7 to rotate, the bevel gear six 3-7 drives a receiving bevel gear six 3-9 to rotate, the receiving bevel gear six 3-9 drives a rotating shaft six 3-8 to rotate, the rotating shaft six 3-8 drives a rotating disc six 3-10 to rotate, a rotating disc six 3-10 toggle column six 3-11 rotates, the toggle column six 3-11 pushes a trapezoidal push rod 3-12 to move up and down in a reciprocating manner, the trapezoidal push rod 3-12 drives a push bolt 3-13 to move in a reciprocating manner, the push bolt 3-13 enables the grinding hemisphere 3-14 to be in reciprocating contact with the inside of the grinding stirring box 3-1 through a spring six 3-15, the pressure between the grinding hemisphere 3-14 and the grinding stirring box 3-1 is also continuously changed, and meanwhile, a grinding motor 3-17 drives a transmission, the transmission gear seven 3-18 drives the grinding hemispheres 3-14 to move and rotate at the same time, the grinding hemispheres 3-14 drive the stirring legs 3-16 to grind the mixture in the stirring box 3-1 and then discharge the mixture from the grinding discharge hole 3-3, the crushing cylinder 2-1 is fixedly arranged on the grinding stirring box 3-1, the feed inlet three 3-2 is arranged on the grinding stirring box 3-1, the grinding discharge hole 3-3 is arranged on the grinding stirring box 3-1, the mounting frame three 3-4 is fixedly arranged in the grinding stirring box 3-1, the mounting frame three 3-5 is fixedly arranged in the grinding stirring box 3-1, the motor six 3-6 is fixedly arranged on the mounting frame three 3-4, and the bevel gear six 3-7 is fixedly arranged on the motor six 3-6, a sixth bevel gear 3-7 is meshed with a sixth receiving bevel gear 3-9, a sixth rotating shaft 3-8 is rotatably arranged on a third mounting plate 3-5, the sixth receiving bevel gear 3-9 is fixedly arranged on a sixth moving shaft 3-18, a sixth rotating disc 3-10 is fixedly arranged on the sixth moving shaft 3-18, a sixth toggle column 3-11 is fixedly arranged on a sixth rotating disc 3-10, the sixth toggle column 3-11 is slidably arranged on a trapezoidal push rod 3-12, the trapezoidal push rod 3-12 is slidably arranged on a third mounting frame 3-4, a push bolt 3-13 is fixedly arranged on the trapezoidal push rod 3-12, a grinding hemisphere 3-14 is slidably arranged on a push bolt 3-13, a sixth spring 3-15 is arranged inside the grinding hemisphere 3-14, a stirring leg 3-16 is hinged on the grinding hemisphere 3-14, The grinding motors 3-17 are fixedly arranged on the mounting frame III 3-4, the transmission gears seven 3-18 are fixedly arranged on the grinding motors 3-17, and the transmission gears seven 3-18 are meshed with the grinding hemispheres 3-14.

The fifth concrete implementation mode:

the present embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, and 17, and the present embodiment further describes an embodiment four, in which the number of the feed ports three 3-2 of the milling and stirring device 3 is two, and the number of the stirring legs 3-16 is four.

The working principle of the invention is as follows:

a building wall coating grinding device has the working principle that whether the connection condition between devices meets requirements is checked before the device is used, a motor 1-15 of an adjustable proportion feeding device 1 drives an output belt wheel 1-16 to rotate, the output belt wheel 1-16 drives a transmission receiving belt wheel 1-19 to rotate through a transmission belt 1-17, the transmission receiving belt wheel 1-19 drives a transmission shaft 1-18 to rotate, the transmission shaft 1-18 drives an output pinion 1-20, an output gearwheel 1-21, an output pinion 1-27 and an output gearwheel 1-28 to simultaneously rotate, then the output rotation condition of a rotating connecting rod 1-13 and a rotating connecting rod 1-14 is changed by adjusting the positions of an adjusting rod 1-26 and an adjusting rod 1-33, when the positions of the adjusting rod 1-26 are adjusted by adjusting rods 1-26, the output small gear 1-20 is meshed with the receiving big gear 1-23, the output small gear 1-20 drives the receiving big gear 1-23 to rotate, the receiving big gear 1-23 drives the transmission sleeve 1-22 to rotate at low speed, the transmission sleeve 1-22 drives the rotation connecting rod 1-13 to rotate, the rotation connecting rod 1-13 rotates at high speed when the adjusting rod 1-26 is positioned in the grade groove two 1-10 of the solid material storage box, similarly, the rotation connecting rod 1-14 rotates at low speed when the adjusting rod 1-33 is positioned in the grade groove one 1-11 of the solid material storage box, and the rotation connecting rod 1-14 rotates at high speed when the adjusting rod 1-33 is positioned in the grade groove two 1-12 of the solid material storage box, so that the output combination under the condition is formed, and the sequence is that: low speed, high speed, no low speed, no high speed, then rotating connecting rod 1-13 and rotating connecting rod 1-14 to drive rotating shaft 1-2 and rotating shaft 1-5 to rotate respectively, driving rotating shaft 1-2 and rotating shaft 1-5 to drive discharging wheel 1-3 and discharging wheel 1-6 to rotate respectively to discharge solid material storage tank 1-1 and solid material storage tank 1-4 into crushing device 2, then motor two 2-5 to drive bevel gear 2-6 to rotate, when bevel gear 2-6 and half bevel gear one 2-7 are meshed, half bevel gear one 2-7 drives rotating shaft two 2-4 to rotate forwardly, when bevel gear 2-6 and half bevel gear two 2-8 are meshed, half bevel gear two 2-8 drives rotating shaft two 2-4 to rotate reversely, therefore, the second rotating shaft 2-4 drives the extruding semi-cylinders 2-9 to rotate in a reciprocating manner in the crushing cylinder 2-1 to extrude the coating, meanwhile, the third motor 2-10 drives the third bevel gear 2-11 to rotate, the third bevel gear 2-11 drives the third receiving bevel gear 2-13 to rotate, the third receiving bevel gear 2-13 drives the third transmission shaft 2-12 to rotate, the third transmission shaft 2-12 drives the third rotating disc 2-14 to rotate, the third rotating disc 2-14 pushes the top tooth surface oscillating block 2-16 to oscillate in a reciprocating manner through the toggle column 2-15, the top tooth surface oscillating block 2-16 drives the rack 2-17 to move in a reciprocating manner, the rack 2-17 drives the extruding plates 2-18 to move in a reciprocating manner to carry out secondary extrusion, and meanwhile, the fourth motor 2-19 drives the fourth output gear 2-20 to, the output gear four 2-20 drives the receiving gear four 2-22 to rotate, the receiving gear four 2-22 drives the transmission shaft four 2-21 to rotate, the transmission shaft four 2-21 drives the rotating half bevel gear four 2-23 and the rotating half bevel gear five 2-24 to rotate, the receiving bevel gear four 2-26 rotates forwards when the rotating half bevel gear four 2-23 is meshed with the receiving bevel gear four 2-26, the receiving bevel gear four 2-26 rotates backwards when the rotating half bevel gear five 2-24 is meshed with the receiving bevel gear four 2-26, so the receiving bevel gear four 2-26 drives the connecting shaft four 2-25 to rotate in a reciprocating way, the connecting shaft four 2-25 drives the grinding disc 2-27 to grind the coating, the ground coating falls into the grinding stirring box 3-1 through the discharging sieve holes 2-3, then a motor six 3-6 drives a bevel gear six 3-7 to rotate, the bevel gear six 3-7 drives a receiving bevel gear six 3-9 to rotate, the receiving bevel gear six 3-9 drives a rotating shaft six 3-8 to rotate, the rotating shaft six 3-8 drives a rotating disc six 3-10 to rotate, a rotating disc six 3-10 toggle column six 3-11 rotates, the toggle column six 3-11 pushes a trapezoidal push rod 3-12 to move up and down in a reciprocating manner, the trapezoidal push rod 3-12 drives a push bolt 3-13 to move in a reciprocating manner, the push bolt 3-13 enables the grinding hemisphere 3-14 to be in reciprocating contact with the inside of the grinding stirring box 3-1 through a spring six 3-15, the pressure between the grinding hemisphere 3-14 and the grinding stirring box 3-1 is also continuously changed, and meanwhile, a grinding motor 3-17 drives a transmission, the transmission gears seven 3-18 drive the grinding hemispheres 3-14 to move and rotate at the same time, and the grinding hemispheres 3-14 drive the stirring legs 3-16 to grind the mixture in the stirring box 3-1 and then discharge the mixture from the grinding discharge hole 3-3.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (5)

1. The utility model provides a building wall coating grinding device, includes adjustable proportion feeder (1), breaker (2), grinding agitating unit (3), its characterized in that: the adjustable proportion feeding device (1) is installed and fixed on the crushing device (2), and the crushing device (2) is installed and fixed on the grinding and stirring device (3).

2. The building wall paint grinding apparatus of claim 1, wherein: the adjustable proportional feeding device (1) comprises a solid material storage box (1-1), a rotating shaft (1-2), a discharging wheel (1-3), a solid material storage box I (1-4), a rotating shaft I (1-5), a discharging wheel I (1-6), a connecting column (1-7), an adjusting box (1-8), a solid material storage box baffle groove I (1-9), a solid material storage box baffle groove II (1-10), a solid material storage box baffle groove I (1-11), a solid material storage box baffle groove II (1-12), a rotating connecting rod (1-13), a rotating connecting rod I (1-14), a motor (1-15), an output belt wheel (1-16), a transmission belt (1-17), a transmission shaft (1-18), a transmission receiving belt wheel (1-19), An output pinion (1-20), an output gearwheel (1-21), a transmission sleeve (1-22), a receiving gearwheel (1-23), a receiving pinion (1-24), an adjusting sliding ring (1-25), an adjusting rod (1-26), an output pinion I (1-27), an output gearwheel I (1-28), a transmission sleeve I (1-29), a receiving gearwheel I (1-30), a receiving pinion I (1-21), an adjusting sliding ring I (1-32) and an adjusting rod I (1-33), a rotating shaft (1-2) is rotatably arranged in a solid material storage box (1-1), a discharging wheel (1-3) is fixedly arranged on the rotating shaft (1-2), a rotating shaft I (1-5) is rotatably arranged in a solid material storage box I (1-4), a first discharge wheel (1-6) is fixedly arranged on a first rotating shaft (1-5), a connecting column (1-7) is fixedly arranged on a first solid material storage box (1-1) and a first solid material storage box (1-4), an adjusting box (1-8) is fixedly arranged on the connecting column (1-7), a first solid material storage box baffle groove (1-9) is arranged on the adjusting box (1-8), a second solid material storage box baffle groove (1-10) is arranged on the adjusting box (1-8), a first solid material storage box baffle groove (1-11) is arranged on the adjusting box (1-8), a second solid material storage box baffle groove (1-12) is arranged on the adjusting box (1-8), a rotating connecting rod (1-13) is slidably arranged in the driving sleeve (1-22), and a rotating connecting rod (1-13) is fixedly arranged on the rotating shaft (1-2), a first rotating connecting rod (1-14) is fixedly arranged on a first rotating shaft (1-5), the first rotating connecting rod (1-14) is slidably arranged inside a first transmission sleeve (1-29), a motor (1-15) is fixedly arranged inside an adjusting box (1-8), an output belt wheel (1-16) is fixedly arranged on the motor (1-15), a transmission belt (1-17) is arranged on the output belt wheel (1-16) and a transmission receiving belt wheel (1-19), a transmission shaft (1-18) is rotatably arranged inside the adjusting box (1-8), the transmission receiving belt wheel (1-19) is fixedly arranged on the transmission shaft (1-18), an output pinion (1-20) is fixedly arranged on the transmission shaft (1-18), and an output gearwheel (1-21) is fixedly arranged on the transmission shaft (1-18), the transmission sleeve (1-22) is rotatably arranged inside the adjusting box (1-8), the receiving gearwheel (1-23) is fixedly arranged on the transmission sleeve (1-22), the receiving pinion (1-24) is fixedly arranged on the transmission sleeve (1-22), the adjusting sliding ring (1-25) is rotatably arranged on the transmission sleeve (1-22), the adjusting rod (1-26) is fixedly arranged on the adjusting sliding ring (1-25), the output pinion I (1-27) is fixedly arranged on the transmission shaft (1-18), the output gearwheel I (1-28) is fixedly arranged on the transmission shaft (1-18), the transmission sleeve I (1-29) is rotatably arranged inside the adjusting box (1-8), and the receiving gearwheel I (1-30) is fixedly arranged on the transmission sleeve I (1-29), the receiving pinion I (1-21) is fixedly arranged on the transmission sleeve I (1-29), the adjusting sliding ring I (1-32) is rotatably arranged on the transmission sleeve I (1-29), and the adjusting rod I (1-33) is fixedly arranged on the adjusting sliding ring I (1-32).

3. The building wall paint grinding apparatus of claim 1, wherein: the crushing device (2) comprises a crushing cylinder (2-1), a feeding hole (2-2), a discharging sieve hole (2-3), a rotating shaft II (2-4), a motor II (2-5), a bevel gear (2-6), a half bevel gear I (2-7), a half bevel gear II (2-8), an extruding semi-cylinder (2-9), a motor III (2-10), a bevel gear III (2-11), a transmission shaft III (2-12), a receiving bevel gear III (2-13), a rotating disc III (2-14), a toggle column (2-15), a top end tooth surface swinging block (2-16), a rack (2-17), an extruding plate (2-18), a motor IV (2-19), an output gear IV (2-20), a transmission shaft IV (2-21), A receiving gear four (2-22), a rotating half bevel gear four (2-23), a rotating half bevel gear five (2-24), a connecting shaft four (2-25), a receiving bevel gear four (2-26) and a grinding disc (2-27), a solid material storage box (1-1) is fixedly arranged on a crushing cylinder (2-1), a solid material storage box I (1-4) is fixedly arranged on the crushing cylinder (2-1), a feeding port (2-2) is arranged on the crushing cylinder (2-1), a discharging sieve pore (2-3) is arranged on the crushing cylinder (2-1), a rotating shaft two (2-4) is rotatably arranged on the crushing cylinder (2-1), a motor two (2-5) and a bevel gear (2-6) are fixedly arranged on the motor two (2-5), a half bevel gear I (2-7) is fixedly arranged on the rotating shaft two (2-4), a half-cone gear II (2-8) is fixedly arranged on a rotating shaft II (2-4), an extrusion semi-cylinder (2-9) is fixedly arranged on the rotating shaft II (2-4), a motor III (2-10) is fixedly arranged inside the extrusion semi-cylinder (2-9), a bevel gear III (2-11) is fixedly arranged on the motor III (2-10), a transmission shaft III (2-12) is rotatably arranged on the extrusion semi-cylinder (2-9), a receiving bevel gear III (2-13) is fixedly arranged on the transmission shaft III (2-12), a rotating disc III (2-14) is fixedly arranged on the transmission shaft III (2-12), a toggle column (2-15) is fixedly arranged on the rotating disc III (2-14), and the toggle column (2-15) is slidably arranged inside a top tooth surface swinging block (2-16), the top end tooth surface swing block (2-16) is rotatably arranged inside the extrusion semi-cylinder (2-9), a rack (2-17) is meshed with the top end tooth surface swing block (2-16), the rack (2-17) is slidably arranged inside the extrusion semi-cylinder (2-9), an extrusion plate (2-18) is fixedly arranged on the rack (2-17), a motor four (2-19) is fixedly arranged inside the crushing cylinder (2-1), an output gear four (2-20) is fixedly arranged on the motor four (2-19), the output gear four (2-20) is meshed with a receiving gear four (2-22), a transmission shaft four (2-21) is rotatably arranged inside the crushing cylinder (2-1), and the receiving gear four (2-22) is fixedly arranged on the transmission shaft four (2-21), a rotating half bevel gear four (2-23) is fixedly arranged on a transmission shaft four (2-21), a rotating half bevel gear five (2-24) is fixedly arranged on the transmission shaft four (2-21), a connecting shaft four (2-25) is rotatably arranged in the crushing barrel (2-1), and a receiving bevel gear four (2-26) is fixedly arranged on a grinding disc (2-27) on the connecting shaft four (2-25) and is fixedly arranged on the connecting shaft four (2-25).

4. The building wall paint grinding apparatus of claim 1, wherein: the grinding and stirring device (3) comprises a grinding and stirring box (3-1), a feed inlet III (3-2), a grinding discharge hole (3-3), a mounting rack III (3-4), a mounting plate III (3-5), a motor VI (3-6), a bevel gear VI (3-7), a rotating shaft VI (3-8), a receiving bevel gear VI (3-9), a rotating disc VI (3-10), a toggle column VI (3-11), a trapezoidal push rod (3-12), a push bolt (3-13), a grinding hemisphere (3-14), a spring VI (3-15), a stirring leg (3-16), a grinding motor (3-17) and a transmission gear seven (3-18), wherein a crushing cylinder (2-1) is fixedly arranged on the grinding and stirring box (3-1), a feed inlet III (3-2) is arranged on the grinding and stirring box (3-1), a grinding discharge hole (3-3) is arranged on the grinding and stirring box (3-1), a mounting frame III (3-4) is fixedly arranged inside the grinding and stirring box (3-1), a mounting plate III (3-5) is fixedly arranged inside the grinding and stirring box (3-1), a motor VI (3-6) is fixedly arranged on the mounting frame III (3-4), a bevel gear VI (3-7) is fixedly arranged on the motor VI (3-6), the bevel gear VI (3-7) is meshed with a receiving bevel gear VI (3-9), a rotating shaft VI (3-8) is rotatably arranged on the mounting plate III (3-5), and the receiving bevel gear VI (3-9) is fixedly arranged on a moving shaft VI (3-18), a rotating disc six (3-10) is fixedly arranged on a moving shaft six (3-18), a toggle column six (3-11) is fixedly arranged on the rotating disc six (3-10), the toggle column six (3-11) is slidably arranged on a trapezoidal push rod (3-12), the trapezoidal push rod (3-12) is slidably arranged on a mounting frame three (3-4), a push bolt (3-13) is fixedly arranged on the trapezoidal push rod (3-12), a grinding hemisphere (3-14) is slidably arranged on the push bolt (3-13), a spring six (3-15) is arranged inside the grinding hemisphere (3-14), a stirring leg (3-16) is hinged on the grinding hemisphere (3-14), a grinding motor (3-17) is fixedly arranged on the mounting frame three (3-4), a transmission gear seven (3-18) is fixedly arranged on the grinding motor (3-17), the transmission gears seven (3-18) are meshed with the grinding hemispheres (3-14).

5. The building wall paint grinding apparatus of claim 4, wherein: the number of the feed inlets three (3-2) of the grinding and stirring device (3) is two, and the number of the stirring legs (3-16) is four.

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