CN113182056A - Cosmetic raw materials becomes powder device - Google Patents

Abstract

The invention relates to a powder forming device, in particular to a cosmetic raw material powder forming device which comprises a pre-powder forming grinding mechanism, a grinding box mechanism, a powder conveying mechanism and a powder stall collecting mechanism.

Description

Cosmetic raw materials becomes powder device

Technical Field

The invention relates to a powder forming device, in particular to a cosmetic raw material powder forming device.

Background

In the course of working of cosmetics, need carry out the crocus to the raw materials and handle, traditional milling equipment can only carry out the crocus when carrying out the crocus, can not be fine handle some bold materials of sneaking into, and powder transmission efficiency is low, and effective grinding area is little, and in the powder collection process, often need shut down the clearance after the dust accumulation, the clearance still causes the secondary raise dust easily, so designed a cosmetics raw materials becomes whitewashed device.

Disclosure of Invention

The invention mainly solves the technical problem of providing a cosmetic raw material powdering device, which can complete the pre-powdering of materials and reduce the powder discharge pressure while performing anti-blocking feeding, can grind and adjust the grinding gap, can collect powder, can complete the cleaning of filter cloth without stopping, and does not cause secondary pollution.

In order to solve the technical problem, the invention relates to a powder forming device, in particular to a cosmetic raw material powder forming device which comprises a powder pre-forming grinding mechanism, a grinding box mechanism, a powder conveying mechanism and a powder stall collecting mechanism.

The pre-powdering grinding mechanism is connected with the grinding box mechanism, the grinding box mechanism is connected with the powder conveying mechanism, and the powder conveying mechanism is connected with the powder stall collecting mechanism.

As a further optimization of the technical scheme, the pre-powdering grinding mechanism of the cosmetic raw material powdering device comprises a feed hopper, a rotating wheel, a powder collecting hole, an impact plate, a throwing cavity, a wind wheel, a main shaft, a rotating arm, a grinding head, a material activating plate, a connecting rod, a threaded hole disc, a lead screw, a band-pass hole disc, a cross shaft, a cross hole, a driven disc with a reinforcing rod, a coupler, a motor, a bearing seat, an accelerating hook plate, a spring, a pressure reducing cavity and a light hole, wherein the feed hopper is connected with the rotating wheel, the feed hopper is communicated with the throwing cavity, the throwing cavity is arranged in the rotating wheel, the throwing cavity is enclosed by the accelerating hook plate, the accelerating hook plate is connected with the rotating wheel, the powder collecting hole is arranged on the upper end surface and the lower end surface of the rotating wheel, the impact plate is fixed on the accelerating hook plate through a bolt, the wind wheel is connected with the main shaft, the main shaft is connected with the rotating wheel, the main shaft is connected with the rotating arm in a sliding manner, the grinding head is connected in the pressure reducing cavity in a sliding manner, the pressure reducing cavity is arranged on the rotating arm, the piston plate is connected with the main shaft, the connecting rod is connected in a unthreaded hole in a sliding mode, the unthreaded hole is arranged on the main shaft, the upper end of the connecting rod is connected with the rotating arm, the lower end of the connecting rod is connected with a threaded hole disc, the threaded hole disc is connected with a lead screw in a threaded mode, the lead screw is connected with the main shaft in a rotating mode, the lower end of the lead screw is connected with a threaded hole disc, a cross shaft is connected with the cross hole in a sliding mode, the cross hole is formed in a driven disc with a reinforcing rod, the driven disc with the reinforcing rod is connected with the threaded hole disc, the cross shaft is connected with a bearing seat in a rotating mode, the driven disc with the reinforcing rod is connected with a motor through a coupler, the motor is connected with the bearing seat, a spring is arranged in the pressure reducing cavity, and two ends of the spring are respectively connected with the rotating arm and the grinding head; the accelerating hook plate is provided with a straight line part and a bent part, and the impact plate is fixed on the bent part through a bolt.

As a further optimization of the technical scheme, the grinding box mechanism of the cosmetic raw material powdering device comprises a negative pressure pipe, an upper box cover, an air inlet valve, an air inlet pipe, a pressure box, a connecting pipe, an access door, a piston rod, a spring, a lining plate seat, a lining plate, a communicating port, an air injection valve, a grinding lining plate, a lower box body with supporting legs and a sliding chute, wherein the negative pressure pipe is connected and communicated with the upper box cover, the air inlet valve is arranged in the air inlet pipe, the air inlet pipe is connected and communicated with the pressure box, the pressure box is connected with the upper box cover, the pressure box is connected and communicated with the connecting pipe, the connecting pipe is inserted into the communicating port, the communicating port is arranged on the lower box body with the supporting legs, the lower box body with the access door is connected with the access door, the piston is connected in the pressure box in a sliding manner, the piston rod penetrates through the upper box cover and the pressure box and is connected to the piston rod in a sliding manner with the upper box cover, the spring housing is on the piston rod, and the spring both ends are connected respectively on last case lid and liner plate seat, and the liner plate seat links to each other with the piston rod, and the welt passes through the bolt fastening on the liner plate seat, liner plate seat and spout sliding connection, and the spout setting is on last case lid, and the air blast valve setting is in the connecting tube, grinds the welt and passes through the bolt fastening on taking the landing leg under the box, takes the landing leg under the box and links to each other with last case lid, and the feeder hopper rotates with last case lid to be connected, and the main shaft rotates with taking the landing leg under the box to be connected.

As a further optimization of the technical scheme, the powder conveying mechanism of the cosmetic raw material powdering device comprises a connecting pipe I, a wind wheel box, a wind wheel driving motor, a conveying pipe, a conversion box, a standby air outlet pipe, a standby filter core, a pipeline support, a main air outlet pipe, a motor base, a servo motor, a wind wheel with a shaft and a switching plate with the shaft, wherein the connecting pipe I is connected and communicated with a negative pressure pipe, the connecting pipe I is connected and communicated with the wind wheel box, the wind wheel driving motor is connected with the wind wheel with the shaft, the wind wheel with the shaft is rotatably connected with the wind wheel box, the wind wheel box is communicated with the conversion box through the conveying pipe, the conversion box is connected and communicated with the standby air outlet pipe, the standby air outlet pipe is connected with the pipeline support in a sliding manner, the pipeline support is connected with the main air outlet pipe, the main air outlet pipe is connected and communicated with the conversion box, the motor cabinet links to each other with the transfer case, and the motor cabinet links to each other with servo motor, and the tape spool switches board and is connected with the transfer case rotation, and the tape spool switches board and links to each other with servo motor.

As a further optimization of the technical scheme, the powder stall collecting mechanism of the cosmetic raw material powdering device comprises a powder collecting tank, a dust removing box inlet pipe, a steering wheel, filter cloth, a winding wheel I, a belt pulley, a belt, a driven wheel, a switching wheel, a sliding bearing seat, a servo motor I, a belt sliding groove seat, a rubber sleeve nozzle, an inner reversing wheel, a main air outlet, a main filter element, a vibration support, a sliding rod, a compression spring, a cam, a tensioning wheel, a fixed shaft, a fixed pulley, a movable bearing seat, a driving groove, two-side driving heads, a driving shaft, a driven groove and an adjusting cylinder, wherein the powder collecting tank is connected and communicated with the dust removing box, the dust removing box is connected and communicated with the dust removing box inlet pipe, the dust removing box inlet pipe is connected and communicated with the main air outlet pipe, the steering wheels are symmetrically arranged on two sides of the dust removing box, the steering wheel is rotatably connected with the dust removing box, the winding wheel is rotatably connected with the dust removing box, one end of the filter cloth is fixedly connected to a winding wheel, the filter cloth is in friction connection with a steering wheel, the other end of the filter cloth is fixedly connected to the winding wheel I and wound for a plurality of weeks, a belt pulley is in friction connection with a belt, the belt pulley is connected with the winding wheel I, the winding wheel I is in rotation connection with a dust removal box, a driven wheel is connected with the winding wheel, a switching wheel is in friction connection with the belt, the switching wheel is in rotation connection with a sliding bearing seat, the sliding bearing seat is in sliding connection with a sliding groove seat, a servo motor I is connected with the sliding bearing seat, the sliding groove seat is connected with the dust removal box, rubber sleeve nozzles are symmetrically arranged on two sides of the dust removal box, the filter cloth penetrates into the dust removal box from one side of the rubber sleeve nozzles and penetrates out of the dust removal box from the symmetrical side of the rubber sleeve nozzles, two inner reversing wheels are in rotation connection with the dust removal box, the inner reversing wheels are in friction connection with the filter cloth, a main air outlet is connected and communicated with the dust removal box, a main air outlet is in sliding connection with a main air outlet, a vibration support is connected with the inner wall of the dust removal box, the vibrations are supported and are linked to each other with the slide bar, the housing of pressure spring is on the slide bar, the housing of pressure spring is connected respectively on vibrations support and movable bearing seat at the both ends of take-up pulley, the take-up pulley is connected with filter cloth friction, the fixed axle rotates with the dust removal case to be connected, the fixed axle links to each other with fixed pulley, fixed pulley contacts with the cam, movable bearing seat sliding connection is on the slide bar, movable bearing seat rotates with the take-up pulley to be connected, the driving groove sets up on the driven wheel, two side driving head and driving groove sliding connection, two side driving head link to each other with the drive shaft, the drive shaft rotates with sliding bearing seat to be connected, driven groove sets up on the switching wheel, adjust cylinder fixed connection takes the sliding groove seat in, adjust cylinder's cylinder pole links to each other with sliding bearing seat.

As a further optimization of the technical scheme, the included angle between the straight line part and the bent part of the cosmetic raw material powdering device is 120 degrees.

As a further optimization of the technical scheme, the distance between the circular arc surface of the grinding head and the grinding lining plate of the cosmetic raw material powder forming device is 8-12 mm.

As a further optimization of the technical scheme, the lower end of the powder collecting tank of the cosmetic raw material powder forming device is provided with the electromagnetic powder discharge valve.

As a further optimization of the technical scheme, the driving groove and the driven groove of the cosmetic raw material powdering device are positioned on the same axis, have the same size and shape, and the driving heads on the two sides can be inserted into the driving groove or the driven groove by moving.

The cosmetic raw material powdering device has the beneficial effects that:

according to the cosmetic raw material powdering device, pre-powdering of materials can be completed while anti-blocking feeding is achieved, the powder discharging pressure is reduced, the device can grind and adjust the grinding gap, powder can be collected, the device can complete cleaning of filter cloth without stopping, and secondary pollution is avoided.

Drawings

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

Fig. 1 is a schematic structural diagram of a cosmetic raw material powdering device according to the present invention.

Fig. 2 is a schematic structural diagram of a cosmetic raw material powdering device according to the present invention.

Fig. 3 is a schematic structural diagram three of a cosmetic raw material powdering device according to the present invention.

Fig. 4 is a schematic structural diagram of a cosmetic raw material powdering device according to the present invention.

Fig. 5 is a first schematic structural diagram of the pre-powdering grinding mechanism 1 of the cosmetic raw material powdering device according to the present invention.

Fig. 6 is a second schematic structural diagram of the pre-powdering grinding mechanism 1 of the cosmetic raw material powdering device according to the present invention.

Fig. 7 is a third schematic structural diagram of the pre-powdering grinding mechanism 1 of the cosmetic raw material powdering device according to the present invention.

Fig. 8 is a fourth schematic structural diagram of the pre-powdering grinding mechanism 1 of the cosmetic raw material powdering device according to the present invention.

Fig. 9 is a first schematic structural diagram of a grinding box mechanism 2 of the cosmetic raw material powdering device of the present invention.

Fig. 10 is a second schematic structural view of a grinding box mechanism 2 of the cosmetic raw material powdering device of the present invention.

Fig. 11 is a third schematic structural view of a grinding box mechanism 2 of a cosmetic raw material powdering device according to the present invention.

Fig. 12 is a first structural schematic diagram of a powder conveying mechanism 3 of a cosmetic raw material powdering device according to the present invention.

Fig. 13 is a second schematic structural diagram of a powder conveying mechanism 3 of a cosmetic raw material powdering device according to the present invention.

Fig. 14 is a third schematic structural view of a powder conveying mechanism 3 of a cosmetic raw material powdering device according to the present invention.

Fig. 15 is a fourth schematic structural view of the powder conveying mechanism 3 of the cosmetic raw material powdering device of the present invention.

Fig. 16 is a fifth structural schematic diagram of the powder conveying mechanism 3 of the cosmetic raw material powdering device of the present invention.

Fig. 17 is a sixth schematic structural view of the powder conveying mechanism 3 of the cosmetic raw material powdering device of the present invention.

Fig. 18 is a first structural schematic diagram of a powder stall collection mechanism 4 of a cosmetic raw material powdering device according to the present invention.

Fig. 19 is a second structural schematic diagram of a powder stall collection mechanism 4 of the cosmetic raw material powdering device of the present invention.

Fig. 20 is a third schematic structural diagram of a powder stall collection mechanism 4 of a cosmetic raw material powdering device according to the present invention.

Fig. 21 is a fourth schematic structural diagram of a powder stall collection mechanism 4 of a cosmetic raw material powdering device according to the present invention.

In the figure: a pre-powder grinding mechanism 1; 1-1 parts of a feed hopper; a rotating wheel 1-2; 1-3 of powder collecting holes; 1-4 of an impact plate; 1-5 of a throwing cavity; 1-6 of wind wheel; 1-7 of a main shaft; 1-8 of a rotating arm; a grinding head 1-9; 1-10 parts of a movable material plate; connecting rods 1-11; 1-12 of a disk with a threaded hole; 1-13 parts of a screw rod; a holed disk 1-14; 1-15 parts of a cross shaft; 1-16 parts of cross holes; driven disks 1-17 with reinforcing rods; 1-18 of a coupler; motors 1-19; 1-20 parts of a bearing seat; 1-21 of an accelerating hook plate; straight portions 1-211; bending parts 1-212; springs 1-22; decompression chambers 1 to 23; a light hole 1-24; a grinding box mechanism 2; 2-1 of a negative pressure pipe; an upper box cover 2-2; an air intake valve 2-3; 2-4 of an air inlet pipe; 2-5 of a pressure tank; connecting pipes 2-6; 2-7 of an access door; 2-8 parts of a piston; a piston rod 2-9; 2-10 parts of spring; 2-11 of a liner plate seat; 2-12 parts of a lining plate; 2-13 of a communication port; 2-14 of a gas injection valve; grinding the lining plate 2-15; a lower box body 2-16 with supporting legs; 2-17 of a chute; a powder conveying mechanism 3; connecting pipe I3-1; 3-2 of a wind wheel box; a wind wheel driving motor 3-3; 3-4 of a conveying pipe; 3-5 of a conversion box; 3-6 parts of a spare air outlet pipe; 3-7 parts of a spare filter element; 3-8 parts of pipeline support; 3-9 parts of a main air outlet pipe; 3-10 parts of a motor base; 3-11 parts of a servo motor; 3-12 parts of wind wheel with shaft; a belt shaft switching plate 3-13; powder stall collection mechanism 4; 4-1 of a powder collecting tank; 4-2 of a dust removal box; 4-3 of a dust removal box inlet pipe; 4-4 of a steering wheel; 4-5 parts of filter cloth; 4-6 of a winding wheel; winding wheel I4-7; 4-8 of belt pulleys; 4-9 parts of a belt; 4-10 parts of a driven wheel; 4-11 of a switching wheel; 4-12 of a sliding bearing seat; a servo motor I4-13; 4-14 of a sliding groove seat; 4-15 parts of a rubber sleeve nozzle; 4-16 parts of inner reversing wheel; 4-17 parts of main air outlet; 4-18 parts of a main filter element; 4-19 of a vibration support; 4-20 parts of a slide bar; 4-21 parts of a compression spring; 4-22 of cam; 4-23 of tension wheel; 4-24 parts of a fixed shaft; 4-25 of a fixed pulley; movable bearing blocks 4-26; drive slots 4-27; double-sided drive heads 4-28; a drive shaft 4-29; 4-30 parts of passive tanks; adjusting cylinders 4-31.

Detailed Description

The first embodiment is as follows:

the present invention relates to a powder forming device, and more particularly to a cosmetic raw material powder forming device, which is described below with reference to fig. 1 to 21, and includes a pre-powder grinding mechanism 1, a grinding box mechanism 2, a powder conveying mechanism 3, and a powder stall collecting mechanism 4, wherein the device can perform pre-powder forming on materials while performing anti-blocking feeding, reduce the powder discharge pressure, perform grinding and adjust the grinding gap, collect powder, and perform cleaning of filter cloth without stopping the device, and does not cause secondary pollution.

The pre-powdering grinding mechanism 1 is connected with a grinding box mechanism 2, the grinding box mechanism 2 is connected with a powder conveying mechanism 3, and the powder conveying mechanism 3 is connected with a powder stall collecting mechanism 4.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 21, and the embodiment further describes the first embodiment, where the pre-powder grinding mechanism 1 includes a feed hopper 1-1, a rotating wheel 1-2, a powder collecting hole 1-3, an impact plate 1-4, a material throwing cavity 1-5, a wind wheel 1-6, a main shaft 1-7, a rotating arm 1-8, a grinding head 1-9, a material activating plate 1-10, a connecting rod 1-11, a threaded hole plate 1-12, a lead screw 1-13, a hole passing plate 1-14, a cross shaft 1-15, a cross hole 1-16, a driven plate with a reinforcing rod 1-17, a coupling 1-18, a motor 1-19, a bearing seat 1-20, an accelerating hook plate 1-21, a spring 1-22, a pressure reducing cavity 1-23, A unthreaded hole 1-24, a feed hopper 1-1 connected with a rotating wheel 1-2, a feed hopper 1-1 communicated with a material throwing cavity 1-5, the material throwing cavity 1-5 arranged in the rotating wheel 1-2, the material throwing cavity 1-5 enclosed by an accelerating hook plate 1-21, the accelerating hook plate 1-21 connected with the rotating wheel 1-2, the rotating wheel 1-2 having powder collecting holes 1-3 on the upper and lower end faces, an impact plate 1-4 fixed on the accelerating hook plate 1-21 by bolts, a wind wheel 1-6 connected with a main shaft 1-7, the main shaft 1-7 connected with the rotating wheel 1-2, the main shaft 1-7 connected with a rotating arm 1-8 in a sliding manner, a grinding head 1-9 connected in a pressure reducing cavity 1-23, the pressure reducing cavity 1-23 arranged on the rotating arm 1-8, the material activating plate 1-10 is connected with the main shaft 1-7, the connecting rod 1-11 is connected in the unthreaded hole 1-24 in a sliding way, the unthreaded hole 1-24 is arranged on the main shaft 1-7, the upper end of the connecting rod 1-11 is connected with the rotating arm 1-8, the lower end of the connecting rod 1-11 is connected with the threaded hole plate 1-12, the threaded hole plate 1-12 is connected with the screw rod 1-13 in a threaded way, the screw rod 1-13 is connected with the main shaft 1-7 in a rotating way, the lower end of the screw rod 1-13 is connected with the threaded hole plate 1-14, the cross shaft 1-15 is connected with the cross hole 1-16 in a sliding way, the cross hole 1-16 is arranged on the reinforcing rod driven plate 1-17, the reinforcing rod driven plate 1-17 is connected with the threaded hole plate 1-12, the cross shaft 1-15 is connected with the bearing seat 1-20 in a rotating way, the passive disc 1-17 with the reinforcing rod is connected with the motors 1-19 through the couplings 1-18, the motors 1-19 are connected with the bearing seats 1-20, the springs 1-22 are arranged in the decompression chambers 1-23, and two ends of the springs 1-22 are respectively connected with the rotating arms 1-8 and the grinding heads 1-9; the accelerating hook plate 1-21 is provided with straight line parts 1-211 and bent parts 1-212, the impact plate 1-4 is fixed on the bent parts 1-212 through bolts, the operation of the motor 1-19 drives the shaft coupling 1-18 to rotate, the shaft coupling 1-18 drives the cross shafts 1-15 to rotate, the cross shafts 1-15 drive the reinforcing rods to rotate by the movable disks 1-17, the reinforcing rods driven by the movable disks 1-17 drive the threaded hole disks 1-12 to rotate, the threaded hole disks 1-12 drive the connecting rods 1-11 to rotate, the connecting rods 1-11 drive the main shafts 1-7 to rotate, the main shafts 1-7 drive the rotating wheels 1-2 to rotate, and the rotating wheels 1-2 drive the feed hopper 1-1 to rotate, the materials to be ground are added into a material throwing cavity 1-5 from a feed hopper 1-1, centrifugal force is formed due to rotation of a rotating wheel 1-2, the materials are thrown to the outside of the rotating wheel 1-2, the materials firstly collide against an impact plate 1-4 to form sequential impact, a part of corners can be changed into powder, the other whole part can obliquely fly out along with the pushing of a bent part 1-212, the bent part 1-212 can play a role in accelerating the materials, kinetic energy provided by the centrifugal force alone cannot provide good impact, the bent part 1-212 can provide pushing force during centrifugal acceleration, so that the materials are accelerated to fly out better and then impact a lining plate 2-12 to perform secondary impact, a part of the materials can be divided into powder, the lining plate 2-12 can drive a lining plate seat 2-11 to compress a spring 2-10 under the impact, when the springs 2-10 rebound to drive the lining plate seats 2-11 to reset, the lining plates 2-12 can provide reverse acting force for thrown materials, so that the impact effect is enhanced, a better powder forming effect is achieved, a part of materials impacting the lining plates 2-12 can rebound to impact with the materials continuously thrown away to form triple crushing, and the powder forming effect is integrally improved, in the process, the lining plate seats 2-11 form reciprocating motion under the action of impact and the rebound of the springs 2-10, the lining plate seats 2-11 can drive the pistons 2-8 to form reciprocating motion through the piston rods 2-9, the reciprocating motion of the pistons 2-8 can cause pressure difference change in the pressure boxes 2-5, so that outside air is sucked into the pressure boxes 2-5 from the air inlet valves 2-3 and then is sprayed into the lower box bodies 2-16 with supporting legs from the air jet valves 2-14 after being pressurized, the grinding head is beneficial to the movement of materials between the grinding head 1-9 and the grinding lining plate 2-15, so that the materials are all in the working condition of effective grinding, and dust generated during feeding of the feeding hopper 1-1 is sucked by the air inlet pipe 2-4 and then discharged into the lower box body 2-16 with the supporting legs, thereby playing the role of purifying air.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 21, and the embodiment further describes the first embodiment, wherein the grinding box mechanism 2 comprises a negative pressure pipe 2-1, an upper box cover 2-2, an air inlet valve 2-3, an air inlet pipe 2-4, a pressure box 2-5, a connecting pipe 2-6, an access door 2-7, a piston 2-8, a piston rod 2-9, a spring 2-10, a lining plate seat 2-11, a lining plate 2-12, a communication port 2-13, an air injection valve 2-14, a grinding lining plate 2-15, a lower box body 2-16 with supporting legs and a sliding chute 2-17, the negative pressure pipe 2-1 is connected and communicated with the upper box cover 2-2, the air inlet valve 2-3 is arranged in the air inlet pipe 2-4, the air inlet pipe 2-4 is connected and communicated with the pressure box 2-5, a pressure box 2-5 is connected with an upper box cover 2-2, the pressure box 2-5 is connected and communicated with a connecting pipe 2-6, the connecting pipe 2-6 is inserted into a communicating port 2-13, the communicating port 2-13 is arranged on a lower box body 2-16 with supporting legs, the lower box body 2-16 with supporting legs is connected with an access door 2-7, a piston 2-8 is connected in the pressure box 2-5 in a sliding way, a piston rod 2-9 passes through the upper box cover 2-2 and the pressure box 2-5 and is connected on the piston 2-8, the piston rod 2-9 is connected with the upper box cover 2-2 in a sliding way, the piston rod 2-9 is connected with the pressure box 2-5 in a sliding way, a spring 2-10 is sleeved on the piston rod 2-9, two ends of the spring 2-10 are respectively connected on the upper box cover 2-2 and a lining plate seat 2-11, a lining plate seat 2-11 is connected with a piston rod 2-9, a lining plate 2-12 is fixed on the lining plate seat 2-11 through a bolt, the lining plate seat 2-11 is connected with a chute 2-17 in a sliding way, the chute 2-17 is arranged on an upper box cover 2-2, an air injection valve 2-14 is arranged in a connecting pipe 2-6, a grinding lining plate 2-15 is fixed on a lower box body 2-16 with supporting legs through a bolt, the lower box body 2-16 with the supporting legs is connected with the upper box cover 2-2, a feed hopper 1-1 is rotationally connected with the upper box cover 2-2, a main shaft 1-7 is rotationally connected with the lower box body 2-16 with the supporting legs, the connecting rod 1-11 can drive a rotating arm 1-8 to rotate when rotating, the rotating arm 1-8 can drive a grinding head 1-9 to perform circular motion, the grinding head 1-9 and the grinding lining plate 2-15 rotate relatively to grind materials, the material plate 1-10 pushes the materials at the center to the periphery and forms upward airflow to enable the powder formed after grinding to form upward pushing force, the airflow sprayed by the air spraying valve 2-14 forms upward hedging airflow to assist the powder to move upward, and the airflow sprayed by the air spraying valve 2-14 and the pushing of the material plate 1-10 enable the added materials to move between the grinding head 1-9 and the grinding lining plate 2-15, so that the grinding efficiency is improved to the maximum extent.

The fourth concrete implementation mode:

the following describes the embodiment with reference to fig. 1 to 21, which further describes the first embodiment, wherein the powder conveying mechanism 3 includes a connecting pipe I3-1, a wind wheel box 3-2, a wind wheel driving motor 3-3, a conveying pipe 3-4, a conversion box 3-5, a spare air outlet pipe 3-6, a spare filter element 3-7, a pipeline support 3-8, a main air outlet pipe 3-9, a motor base 3-10, a servo motor 3-11, a wind wheel with shaft 3-12, a switching plate with shaft 3-13, the connecting pipe I3-1 is connected and communicated with a negative pressure pipe 2-1, the connecting pipe I3-1 is connected and communicated with the wind wheel box 3-2, the wind wheel driving motor 3-3 is connected with the wind wheel with shaft 3-12, the wind wheel 3-12 with the shaft is rotatably connected with the wind wheel box 3-2, the wind wheel box 3-2 is communicated with the conversion box 3-5 through the delivery pipe 3-4, the conversion box 3-5 is connected and communicated with the spare air outlet pipe 3-6, the spare air outlet pipe 3-6 is internally and slidably connected with the spare filter element 3-7, the spare air outlet pipe 3-6 is connected with the pipeline support 3-8, the pipeline support 3-8 is connected with the main air outlet pipe 3-9, the main air outlet pipe 3-9 is connected and communicated with the conversion box 3-5, the motor base 3-10 is connected with the servo motor 3-11, the switching plate 3-13 with the shaft is rotatably connected with the conversion box 3-5, the switching plate 3-13 with the servo motor 3-11, the wind wheel 1-6 can form upward airflow along with the rotation of the main shaft 1-7, upward airflow formed by the opposite impact airflow and the movable plate 1-10 is matched, the wind wheel driving motor 3-3 is operated to drive the wind wheel with the shaft 3-12 to rotate, airflow flow can be formed by the rotation of the wind wheel with the shaft 3-12, negative pressure is formed at the connecting pipe I3-1, the upward airflow formed by the opposite impact airflow and the movable plate 1-10 is matched, the ground powder is sucked into the wind wheel box 3-2 through the negative pressure pipe 2-1 and then enters the dust removing box 4-2 through the conveying pipe 3-4, the conversion box 3-5, the main air outlet pipe 3-9 and the dust removing box inlet pipe 4-3, and is filtered by the filter cloth 4-5 in the dust removing box 4-2, and then falls into the powder collecting tank 4-1 to be collected, when the powder material rises in the lower box body 2-16 with the supporting legs along with the airflow, the powder material meeting the discharging size of the powder material can be sucked away through the powder collecting holes 1-3, the powder material not meeting the discharging size can be transversely thrown out by the wind wheel 1-6 which respectively rotates, then the powder material descends along the inner wall of the lower box body 2-16 with the supporting legs and is matched with the airflow sprayed by the air spraying valve 2-14 to continuously return to the grinding area for grinding, the grinding clearance is changed, a crow bar can be inserted into the inner disk 1-14 with the holes to drive the disk 1-14 with the holes after the machine is stopped, the disk 1-14 with the holes drives the lead screw 1-13 to rotate, the lead screw 1-13 can drive the disk 1-12 with the holes to move upwards, the disk 1-12 with the holes can drive the rotating arm 1-8 to move upwards through the connecting rod 1-11, the rotating arm 1-8 can drive the grinding head 1-9 to be far away from the grinding lining plate 2-15, therefore, the grinding distance is adjusted, the springs 1-22 can absorb the impact of the grinding head 1-9 in the grinding process, and the grinding head 1-9 is prevented from being damaged by over-hard raw materials.

The fifth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 21, and the present embodiment further describes the first embodiment, where the powder stall collection mechanism 4 includes a powder collection tank 4-1, a dust removal box 4-2, a dust removal box inlet pipe 4-3, a diverting pulley 4-4, a filter cloth 4-5, a winding pulley 4-6, a winding pulley I4-7, a belt pulley 4-8, a belt 4-9, a driven pulley 4-10, a switching pulley 4-11, a sliding bearing seat 4-12, a servo motor I4-13, a belt sliding groove seat 4-14, a rubber sleeve nozzle 4-15, an inner reversing pulley 4-16, a main air outlet 4-17, a main filter element 4-18, a vibration support 4-19, a sliding rod 4-20, a compression spring 4-21, a cam 4-22, a tension pulley 4-23, a rubber sleeve nozzle 4-15, an inner reversing pulley 4-16, a main air outlet 4-17, a vibration support 4-19, a sliding rod 4-20, a compression spring 4-21, a cam 4-22, a tension pulley 4-23, and a tension pulley 4-23, A fixed shaft 4-24, a fixed pulley 4-25, a movable bearing seat 4-26, a driving groove 4-27, a double-side driving head 4-28, a driving shaft 4-29, a driven groove 4-30, an adjusting cylinder 4-31, a powder collecting tank 4-1 connected and communicated with a dust removing box 4-2, the dust removing box 4-2 connected and communicated with a dust removing box inlet pipe 4-3, the dust removing box inlet pipe 4-3 connected and communicated with a main air outlet pipe 3-9, turning wheels 4-4 symmetrically arranged at two sides of the dust removing box 4-2, the turning wheels 4-4 rotationally connected with the dust removing box 4-2, a winding wheel 4-6 rotationally connected with the dust removing box 4-2, one end of a filter cloth 4-5 fixedly connected with the winding wheel 4-6, the filter cloth 4-5 frictionally connected with the turning wheel 4-4, the other end of the filter cloth 4-5 is fixedly connected to a winding wheel I4-7 and wound for a plurality of circles, a belt pulley 4-8 is connected with a belt 4-9 in a friction mode, the belt pulley 4-8 is connected with a winding wheel I4-7, the winding wheel I4-7 is connected with a dust removal box 4-2 in a rotating mode, a driven wheel 4-10 is connected with a winding wheel 4-6, a switching wheel 4-11 is connected with the belt 4-9 in a friction mode, the switching wheel 4-11 is connected with a sliding bearing seat 4-12 in a rotating mode, the sliding bearing seat 4-12 is connected in a sliding groove seat 4-14 in a sliding mode, a servo motor I4-13 is connected with the sliding bearing seat 4-12, the sliding groove seat 4-14 is connected with the dust removal box 4-2, rubber sleeve nozzles 4-15 are symmetrically arranged on two sides of the dust removal box 4-2, the filter cloth 4-5 penetrates into the dust removal box 4-2 from one side of the rubber sleeve nozzles 4-15, the dust removing box 4-2 penetrates out from the symmetrical side rubber sleeve mouths 4-15, two inner reversing wheels 4-16 are rotatably connected with the dust removing box 4-2, the inner reversing wheels 4-16 are in friction connection with the filter cloth 4-5, a main air outlet 4-17 is connected and communicated with the dust removing box 4-2, a main filter element 4-18 is in sliding connection with the main air outlet 4-17, a vibration support 4-19 is connected with the inner wall of the dust removing box 4-2, the vibration support 4-19 is connected with a slide bar 4-20, a compression spring 4-21 is sleeved on the slide bar 4-20, two ends of the compression spring 4-21 are respectively connected with the vibration support 4-19 and a movable bearing seat 4-26, cams 4-22 are symmetrically arranged at two ends of a tension wheel 4-23, the tension wheel 4-23 is in friction connection with the filter cloth 4-5, a fixed shaft 4-24 is rotationally connected with a dust removal box 4-2, the fixed shaft 4-24 is connected with a fixed pulley 4-25, the fixed pulley 4-25 is contacted with a cam 4-22, a movable bearing seat 4-26 is slidably connected with a sliding rod 4-20, the movable bearing seat 4-26 is rotationally connected with a tension pulley 4-23, a driving groove 4-27 is arranged on a driven wheel 4-10, a double-side driving head 4-28 is slidably connected with a driving groove 4-27, the double-side driving head 4-28 is connected with a driving shaft 4-29, the driving shaft 4-29 is rotationally connected with a sliding bearing seat 4-12, a driven groove 4-30 is arranged on a switching wheel 4-11, an adjusting cylinder 4-31 is fixedly connected in a sliding groove seat 4-14, a cylinder rod of the adjusting cylinder 4-31 is connected with the sliding bearing seat 4-12, when enough dust is accumulated on the filter cloth 4-5, the dust needs to be cleaned, at this time, the servo motor 3-11 can be operated to drive the belt shaft switching plate 3-13 to rotate, so that the belt shaft switching plate 3-13 guides the powder conveyed by the conveying pipe 3-4 into the standby air outlet pipe 3-6 to be filtered by the standby filter element 3-7, at this time, the conveying pipe 3-4 and the main air outlet pipe 3-9 are in an isolated state, then the servo motor I4-13 is operated to drive the driving shaft 4-29 to rotate, the rotation direction is anticlockwise seen from the servo motor I4-13 to the driving shaft 4-29, the driving shaft 4-29 can drive the driving head 4-28 to rotate, the double-side driving head 4-28 can drive the driven wheel 4-10 to rotate, and the driven wheel 4-10 can drive the winding wheel 4-6 to rotate, the winding wheel 4-6 rotates to wind the filter cloth 4-5 on the winding wheel 4-6, the tension wheel 4-23 rotates when the filter cloth 4-5 moves, the tension wheel 4-23 rotates to drive the cam 4-22 to rotate, the cam 4-22 rotates to drive the tension wheel 4-23 to move upwards through the reverse acting force of the fixed pulley 4-25, the tension wheel 4-23 drives the movable bearing seat 4-26 to move upwards to compress the compression spring 4-21, when the compression spring 4-21 rotates with the cam 4-22, the compression spring rebounds, the tension wheel 4-23 continuously tensions the filter cloth 4-5, so that dust can be shaken off and collected in the dust collecting tank 4-1 by circulation without stopping the grinding part, after cleaning, the servo motor 3-11 is operated in reverse to drive the belt shaft switching plate 3-13 to reset, airflow is introduced into the main air outlet pipe 3-9 from the conveying pipe 3-4 again and then enters the dust removal box 4-2 for filtering, the filtered air is filtered by the main filter element 4-18 and then is discharged from the main air outlet 4-17, when the filter cloth 4-5 wound on the winding wheel I4-7 is wound on the winding wheel 4-6, the sliding bearing seat 4-12 is pushed by the adjusting cylinder 4-31, the driving shaft 4-29 is driven by the sliding bearing seat 4-12, the driving shaft 4-29 drives the double-side driving head 4-28 to separate from the driving groove 4-27 and insert into the driven groove 4-30, then the servo motor I4-13 is operated in reverse, and the servo motor I4-13 drives the switching wheel 4-11 to rotate through the double-side driving head 4-28 And the switching wheel 4-11 drives the belt pulley 4-8 to rotate through the belt 4-9, the belt pulley 4-8 drives the winding wheel I4-7 to rotate, the filter cloth 4-5 is wound on the winding wheel I4-7 again, and the process of rewinding is also a process of cleaning the filter cloth 4-5.

The sixth specific implementation mode:

the present embodiment is described below with reference to fig. 1 to 21, and the present embodiment further describes the first embodiment, in which the included angle between the linear portion 1-211 and the bent portion 1-212 is 120 degrees.

The seventh embodiment:

the following describes the present embodiment with reference to fig. 1 to 21, and the first embodiment is further described in the present embodiment, in which the distance between the circular arc surface of the polishing head 1-9 and the polishing pad 2-15 is in the range of 8 to 12 mm.

The specific implementation mode is eight:

the present embodiment will be described with reference to fig. 1 to 21, and the present embodiment further describes the first embodiment, in which an electromagnetic powder discharge valve is disposed at the lower end of the powder collection tank 4-1.

The specific implementation method nine:

in the following, the present embodiment is described with reference to fig. 1 to 21, and the present embodiment further describes the first embodiment, the driving grooves 4-27 and the driven grooves 4-30 are located on the same axis, and have the same size and the same shape, and the double-sided driving heads 4-28 can be inserted into the driving grooves 4-27 or the driven grooves 4-30 by moving.

The working principle of the device is as follows: the device can prevent blockage and feed materials and simultaneously complete pre-powdering of materials to reduce powder discharge pressure, the motors 1-19 are operated to drive the couplers 1-18 to rotate, the couplers 1-18 can drive the cross shafts 1-15 to rotate, the cross shafts 1-15 can drive the reinforcing rods to rotate by the driven disks 1-17, the reinforcing rods by the driven disks 1-17 can drive the threaded hole disks 1-12 to rotate, the threaded hole disks 1-12 can drive the connecting rods 1-11 to rotate, the connecting rods 1-11 can drive the main shafts 1-7 to rotate, the main shafts 1-7 can drive the rotating wheels 1-2 to rotate, the rotating wheels 1-2 can drive the feed hoppers 1-1 to rotate, materials to be ground are added into the material throwing cavities 1-5 from the feed hoppers 1-1, because the rotating wheel 1-2 rotates to form centrifugal force, the material is thrown to the outside of the rotating wheel 1-2, the material firstly impacts the impact plate 1-4 to form sequential impact, a part of corners can become powder, the other whole part can obliquely fly out along with the pushing of the bent part 1-212, the bent part 1-212 can play a role in accelerating the material, kinetic energy provided by the centrifugal force alone cannot provide good impact, because the bent part 1-212 can provide driving force during centrifugal acceleration, the material can be better accelerated to fly out and then impact the lining plate 2-12 to perform second impact, a part of the material can be divided into powder, the lining plate 2-12 is impacted to drive the lining plate seat 2-11 to compress the spring 2-10, and when the spring 2-10 rebounds to drive the lining plate seat 2-11 to reset, the lining plates 2-12 can provide reverse acting force for thrown materials to enhance the impact effect and achieve better powder forming effect, part of the materials impacting the lining plates 2-12 can rebound and impact with the materials continuously thrown away to form triple crushing, so that the powder forming effect is integrally improved, in the process, the lining plate seats 2-11 can form reciprocating motion under the action of impact and the rebound of the springs 2-10, the lining plate seats 2-11 can drive the pistons 2-8 to form reciprocating motion through the piston rods 2-9, the reciprocating motion of the pistons 2-8 can cause pressure difference change in the pressure tanks 2-5, so that outside air is sucked into the pressure tanks 2-5 from the air inlet valves 2-3 and then is sprayed into the lower box bodies 2-16 with supporting legs from the air injection valves 2-14 after being pressurized, the grinding head is beneficial to the movement of materials between the grinding head 1-9 and the grinding lining plate 2-15, so that the materials are all in the working condition of effective grinding, and dust generated during feeding of the feeding hopper 1-1 is sucked by the air inlet pipe 2-4 and then discharged into the lower box body 2-16 with the supporting legs, thereby playing the role of purifying air; the device can grind and adjust grinding clearance, the connecting rod 1-11 can drive the rotating arm 1-8 to rotate when rotating, the rotating arm 1-8 can drive the grinding head 1-9 to do circular motion, the grinding head 1-9 can form relative rotation with the grinding lining plate 2-15, so as to grind the materials, the movable plates 1-10 can push the materials positioned at the center to the periphery, upward airflow is formed, so that the powder formed after grinding forms an upward driving force, upward hedging airflow can be formed by matching with the airflow sprayed by the air spraying valves 2-14 to assist the powder to move upwards, and the added materials move between the grinding head 1-9 and the grinding lining plate 2-15 by the airflow sprayed by the air spraying valves 2-14 and the pushing of the movable plate 1-10, so that the grinding efficiency is improved to the maximum extent; the device can collect powder, the wind wheel 1-6 can form upward airflow along with the rotation of the main shaft 1-7, the upward airflow formed by the hedging airflow and the material activating plate 1-10 is matched, simultaneously, the wind wheel driving motor 3-3 is operated to drive the wind wheel with the shaft 3-12 to rotate, the wind wheel with the shaft 3-12 can form airflow flow, negative pressure is formed at the connecting pipe I3-1, the powder generated by grinding is sucked into the wind wheel box 3-2 through the negative pressure pipe 2-1 and then enters the dust removing box 4-2 through the conveying pipe 3-4, the conversion box 3-5, the main air outlet pipe 3-9 and the dust removing box inlet pipe 4-3 in a matching manner of the hedging airflow and the upward airflow formed by the material activating plate 1-10, the powder falls into the powder collecting tank 4-1 to be collected after being filtered by the filter cloth 4-5 in the dust removing box 4-2, when the powder material rises in the lower box body 2-16 with the supporting legs along with the airflow, the powder material meeting the discharging size of the powder material can be sucked away through the powder collecting holes 1-3, the powder material not meeting the discharging size can be transversely thrown out by the wind wheel 1-6 which respectively rotates, then the powder material descends along the inner wall of the lower box body 2-16 with the supporting legs and is matched with the airflow sprayed by the air spraying valve 2-14 to continuously return to the grinding area for grinding, the grinding clearance is changed, a crow bar can be inserted into the inner disk 1-14 with the holes to drive the disk 1-14 with the holes after the machine is stopped, the disk 1-14 with the holes drives the lead screw 1-13 to rotate, the lead screw 1-13 can drive the disk 1-12 with the holes to move upwards, the disk 1-12 with the holes can drive the rotating arm 1-8 to move upwards through the connecting rod 1-11, the rotating arm 1-8 can drive the grinding head 1-9 to be far away from the grinding lining plate 2-15, therefore, the grinding distance is adjusted, the springs 1-22 can absorb the impact of the grinding head 1-9 in the grinding process, and the grinding head 1-9 is prevented from being damaged by over-hard raw materials; the device can finish the cleaning of the filter cloth without stopping the machine and can not cause secondary pollution, when enough dust is accumulated on the filter cloth 4-5, the ash needs to be cleaned, at the moment, the servo motor 3-11 can be operated to drive the belt shaft switching plate 3-13 to rotate, the belt shaft switching plate 3-13 can lead the powder conveyed by the conveying pipe 3-4 into the spare air outlet pipe 3-6 to be filtered by the spare filter element 3-7, at the moment, the conveying pipe 3-4 and the main air outlet pipe 3-9 are in an isolated state, then the servo motor I4-13 is operated to drive the driving shaft 4-29 to rotate, the rotation direction is anticlockwise seen from the servo motor I4-13 to the driving shaft 4-29, the driving shaft 4-29 can drive the bilateral driving heads 4-28 to rotate, and the bilateral driving heads 4-28 can drive the driven wheels 4-10 to rotate, the driven wheel 4-10 can drive the winding wheel 4-6 to rotate, the winding wheel 4-6 can rotate to wind the filter cloth 4-5 on the winding wheel 4-6, the tension wheel 4-23 can rotate in the movement process of the filter cloth 4-5, the tension wheel 4-23 can drive the cam 4-22 to rotate, the cam 4-22 can drive the tension wheel 4-23 to move upwards through the reverse acting force of the fixed pulley 4-25, the tension wheel 4-23 can drive the movable bearing seat 4-26 to move upwards to compress the compression spring 4-21, when the compression spring 4-21 rebounds along with the continuous rotation of the cam 4-22, the tension wheel 4-23 can continue to tension the filter cloth 4-5, and dust can be shaken off and collected in the dust collection tank 4-1 by the circulation, and the grinding part is not required to be stopped, the servo motor 3-11 is operated in reverse direction to drive the belt shaft switching plate 3-13 to reset after cleaning is finished, airflow is introduced into the main air outlet pipe 3-9 from the delivery pipe 3-4 and then enters the dust removal box 4-2 for filtering, the filtered air is discharged from the main air outlet 4-17 after being filtered by the main filter element 4-18, when the filter cloth 4-5 wound on the winding wheel I4-7 is wound on the winding wheel 4-6, the sliding bearing seat 4-12 can be pushed by the adjusting cylinder 4-31, the driving shaft 4-29 can be driven by the sliding bearing seat 4-12, the driving shaft 4-29 can drive the double-side driving heads 4-28 to be separated from the driving grooves 4-27 and inserted into the driven grooves 4-30, and then the servo motor I4-13 is operated in reverse direction, the servo motor I4-13 drives the switching wheel 4-11 to rotate through the double-side driving head 4-28, the switching wheel 4-11 drives the belt pulley 4-8 to rotate through the belt 4-9, the belt pulley 4-8 drives the winding wheel I4-7 to rotate, the filter cloth 4-5 is wound on the winding wheel I4-7 again, and the process of rewinding is also a process of cleaning dust on the filter cloth 4-5.

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 (9)

1. The utility model provides a cosmetic raw materials becomes whitewashed device, includes that powder grinding mechanism (1), grinding box mechanism (2), powder conveying mechanism (3), powder stall collect mechanism (4) in advance, its characterized in that: the pre-powdering grinding mechanism (1) is connected with the grinding box mechanism (2), the grinding box mechanism (2) is connected with the powder conveying mechanism (3), and the powder conveying mechanism (3) is connected with the powder stall collecting mechanism (4).

2. The cosmetic raw material powdering device according to claim 1, characterized in that: the pre-powdering grinding mechanism (1) comprises a feed hopper (1-1), a rotating wheel (1-2), a powder collecting hole (1-3), an impact plate (1-4), a material throwing cavity (1-5), a wind wheel (1-6), a main shaft (1-7), a rotating arm (1-8), a grinding head (1-9), a material activating plate (1-10), a connecting rod (1-11), a threaded hole disc (1-12), a lead screw (1-13), a threaded hole disc (1-14), a cross shaft (1-15), a cross hole (1-16), a driven disc (1-17) with a reinforcing rod, a coupler (1-18), a motor (1-19), a bearing seat (1-20), an accelerating hook plate (1-21), a spring (1-22), A pressure reduction cavity (1-23) and a light hole (1-24), wherein the feed hopper (1-1) is connected with a rotating wheel (1-2), the feed hopper (1-1) is communicated with a material throwing cavity (1-5), the material throwing cavity (1-5) is arranged in the rotating wheel (1-2), the material throwing cavity (1-5) is formed by enclosing an accelerating hook plate (1-21), the accelerating hook plate (1-21) is connected with the rotating wheel (1-2), powder collecting holes (1-3) are respectively arranged on the upper end surface and the lower end surface of the rotating wheel (1-2), an impact plate (1-4) is fixed on the accelerating hook plate (1-21) through bolts, a wind wheel (1-6) is connected with a main shaft (1-7), the main shaft (1-7) is connected with the rotating wheel (1-2), the main shaft (1-7) is connected with a rotating arm (1-8) in a sliding manner, the grinding head (1-9) is connected in a decompression cavity (1-23) in a sliding manner, the decompression cavity (1-23) is arranged on a rotating arm (1-8), a material activating plate (1-10) is connected with a main shaft (1-7), a connecting rod (1-11) is connected in a unthreaded hole (1-24) in a sliding manner, the unthreaded hole (1-24) is arranged on the main shaft (1-7), the upper end of the connecting rod (1-11) is connected with the rotating arm (1-8), the lower end of the connecting rod (1-11) is connected with a threaded hole disc (1-12), the threaded hole disc (1-12) is in threaded connection with a screw rod (1-13), the screw rod (1-13) is in rotating connection with the main shaft (1-7), the lower end of the screw rod (1-13) is connected with a threaded hole disc (1-14), a cross shaft (1-15) is in sliding connection with a cross hole (1-16), the cross holes (1-16) are arranged on the driven disc (1-17) with the reinforcing rod, the driven disc (1-17) with the reinforcing rod is connected with the disc (1-12) with the threaded hole, the cross shafts (1-15) are rotationally connected with the bearing seats (1-20), the driven disc (1-17) with the reinforcing rod is connected with the motors (1-19) through the couplings (1-18), the motors (1-19) are connected with the bearing seats (1-20), the springs (1-22) are arranged in the decompression cavities (1-23), and two ends of the springs (1-22) are respectively connected with the rotating arms (1-8) and the grinding heads (1-9); the accelerating hook plate (1-21) is provided with a straight line part (1-211) and a bent part (1-212), and the impact plate (1-4) is fixed on the bent part (1-212) through a bolt.

3. The cosmetic raw material powdering device according to claim 2, characterized in that: the grinding box mechanism (2) comprises a negative pressure pipe (2-1), an upper box cover (2-2), an air inlet valve (2-3), an air inlet pipe (2-4), a pressure box (2-5), a connecting pipe (2-6), an access door (2-7), a piston (2-8), a piston rod (2-9), a spring (2-10), a lining plate seat (2-11), a lining plate (2-12), a communication port (2-13), an air jet valve (2-14), a grinding lining plate (2-15), a lower box body (2-16) with supporting legs and a sliding chute (2-17), wherein the negative pressure pipe (2-1) is connected and communicated with the upper box cover (2-2), the air inlet valve (2-3) is arranged in the air inlet pipe (2-4), and the air inlet pipe (2-4) is connected and communicated with the pressure box (2-5), the pressure box (2-5) is connected with the upper box cover (2-2), the pressure box (2-5) is connected and communicated with the connecting pipe (2-6), the connecting pipe (2-6) is inserted into the communicating port (2-13), the communicating port (2-13) is arranged on the lower box body (2-16) with the supporting leg, the lower box body (2-16) with the supporting leg is connected with the access door (2-7), the piston (2-8) is connected in the pressure box (2-5) in a sliding way, the piston rod (2-9) penetrates through the upper box cover (2-2) and the pressure box (2-5) and is connected on the piston (2-8), the piston rod (2-9) is connected with the upper box cover (2-2) in a sliding way, the piston rod (2-9) is connected with the pressure box (2-5) in a sliding way, the spring (2-10) is sleeved on the piston rod (2-9), two ends of a spring (2-10) are respectively connected to an upper box cover (2-2) and a lining plate seat (2-11), the lining plate seat (2-11) is connected with a piston rod (2-9), a lining plate (2-12) is fixed on the lining plate seat (2-11) through a bolt, the lining plate seat (2-11) is in sliding connection with a sliding chute (2-17), the sliding chute (2-17) is arranged on the upper box cover (2-2), an air injection valve (2-14) is arranged in a connecting pipe (2-6), a grinding lining plate (2-15) is fixed on a lower box body (2-16) with supporting legs through a bolt, the lower box body (2-16) with the supporting legs is connected with the upper box cover (2-2), a feed hopper (1-1) is rotatably connected with the upper box cover (2-2), and a main shaft (1-7) is rotatably connected with the lower box body (2-16) with the supporting legs.

4. The cosmetic raw material powdering device according to claim 3, characterized in that: the powder conveying mechanism (3) comprises a connecting pipe I (3-1), a wind wheel box (3-2), a wind wheel driving motor (3-3), a conveying pipe (3-4), a conversion box (3-5), a standby air outlet pipe (3-6), a standby filter core (3-7), a pipeline support (3-8), a main air outlet pipe (3-9), a motor base (3-10), a servo motor (3-11), a shaft wind wheel (3-12) and a shaft switching plate (3-13), the connecting pipe I (3-1) is connected and communicated with a negative pressure pipe (2-1), the connecting pipe I (3-1) is connected and communicated with the wind wheel box (3-2), the wind wheel driving motor (3-3) is connected with the shaft wind wheel (3-12), the wind wheel with the shaft (3-12) is rotationally connected with a wind wheel box (3-2), the wind wheel box (3-2) is communicated with a conversion box (3-5) through a delivery pipe (3-4), the conversion box (3-5) is connected and communicated with a standby air outlet pipe (3-6), a standby filter element (3-7) is connected in the standby air outlet pipe (3-6) in a sliding way, the standby air outlet pipe (3-6) is connected with a pipeline support (3-8), the pipeline support (3-8) is connected with a main air outlet pipe (3-9), the main air outlet pipe (3-9) is connected and communicated with the conversion box (3-5), a motor base (3-10) is connected with the conversion box (3-5), the motor base (3-10) is connected with a servo motor (3-11), a switching plate with the shaft (3-13) is rotationally connected with the conversion box (3-5), the switching board (3-13) with shaft is connected with the servo motor (3-11).

5. The cosmetic raw material powdering device according to claim 4, characterized in that: the powder stall collecting mechanism (4) comprises a powder collecting tank (4-1), a dust removing box (4-2), a dust removing box inlet pipe (4-3), a steering wheel (4-4), filter cloth (4-5), a winding wheel (4-6), a winding wheel I (4-7), a belt pulley (4-8), a belt (4-9), a driven wheel (4-10), a switching wheel (4-11), a sliding bearing seat (4-12), a servo motor I (4-13), a sliding groove seat (4-14), a rubber sleeve nozzle (4-15), an inner reversing wheel (4-16), a main air outlet (4-17), a main filter element (4-18), a vibration support (4-19), a sliding rod (4-20), a compression spring (4-21), The dust collection device comprises cams (4-22), tension pulleys (4-23), fixed shafts (4-24), fixed pulleys (4-25), movable bearing seats (4-26), driving grooves (4-27), double-side driving heads (4-28), driving shafts (4-29), driven grooves (4-30) and adjusting cylinders (4-31), a dust collection tank (4-1) is connected and communicated with a dust collection box (4-2), the dust collection box (4-2) is connected and communicated with a dust collection box inlet pipe (4-3), the dust collection box inlet pipe (4-3) is connected and communicated with a main air outlet pipe (3-9), steering wheels (4-4) are symmetrically arranged on two sides of the dust collection box (4-2), the steering wheels (4-4) are rotatably connected with the dust collection box (4-2), the winding wheels (4-6) are rotatably connected with the dust removal box (4-2), one end of the filter cloth (4-5) is fixedly connected to the winding wheels (4-6), the filter cloth (4-5) is in friction connection with the steering wheel (4-4), the other end of the filter cloth (4-5) is fixedly connected to the winding wheels I (4-7) and wound for a plurality of weeks, the belt pulleys (4-8) are in friction connection with the belts (4-9), the belt pulleys (4-8) are connected with the winding wheels I (4-7), the winding wheels I (4-7) are rotatably connected with the dust removal box (4-2), the driven wheels (4-10) are connected with the winding wheels (4-6), the switching wheels (4-11) are in friction connection with the belts (4-9), the switching wheels (4-11) are rotatably connected with the sliding bearing seats (4-12), the sliding bearing seat (4-12) is connected in a sliding groove seat (4-14), the servo motor I (4-13) is connected with the sliding bearing seat (4-12), the sliding groove seat (4-14) is connected with a dust removal box (4-2), the rubber sleeve nozzles (4-15) are symmetrically arranged at two sides of the dust removal box (4-2), the filter cloth (4-5) penetrates into the dust removal box (4-2) from one side of the rubber sleeve nozzle (4-15), the dust removal box (4-2) penetrates out from the symmetrical side rubber sleeve nozzles (4-15), the two inner reversing wheels (4-16) are rotatably connected with the dust removal box (4-2), the inner reversing wheels (4-16) are connected with the filter cloth (4-5) in a friction mode, the main air outlet (4-17) is connected and communicated with the dust removal box (4-2), the main filter element (4-18) is connected with the main air outlet (4-17) in a sliding way, the vibration support (4-19) is connected with the inner wall of the dust removing box (4-2), the vibration support (4-19) is connected with the slide bar (4-20), the compression spring (4-21) is sleeved on the slide bar (4-20), two ends of the compression spring (4-21) are respectively connected with the vibration support (4-19) and the movable bearing seat (4-26), the cams (4-22) are symmetrically arranged at two ends of the tension wheel (4-23), the tension wheel (4-23) is in friction connection with the filter cloth (4-5), the fixed shaft (4-24) is rotationally connected with the dust removing box (4-2), the fixed shaft (4-24) is connected with the fixed pulley (4-25), the fixed pulley (4-25) is contacted with the cam (4-22), the adjustable pulley is characterized in that a movable bearing seat (4-26) is connected to a sliding rod (4-20) in a sliding mode, the movable bearing seat (4-26) is connected with a tensioning wheel (4-23) in a rotating mode, a driving groove (4-27) is formed in a driven wheel (4-10), a double-side driving head (4-28) is connected with the driving groove (4-27) in a sliding mode, the double-side driving head (4-28) is connected with a driving shaft (4-29), the driving shaft (4-29) is connected with a sliding bearing seat (4-12) in a rotating mode, a driven groove (4-30) is formed in a switching wheel (4-11), an adjusting cylinder (4-31) is fixedly connected into a sliding groove seat (4-14), and a cylinder rod of the adjusting cylinder (4-31) is connected with the sliding bearing seat (4-12).

6. The cosmetic raw material powdering device according to claim 2, characterized in that: the included angle between the straight line part (1-211) and the bending part (1-212) is 120 degrees.

7. The cosmetic raw material powdering device according to claim 3, characterized in that: the distance between the circular arc surface of the grinding head (1-9) and the grinding lining plate (2-15) ranges from 8 mm to 12 mm.

8. The cosmetic raw material powdering device according to claim 5, characterized in that: the lower end of the powder collecting tank (4-1) is provided with an electromagnetic powder discharge valve.

9. The cosmetic raw material powdering device according to claim 5, characterized in that: the driving grooves (4-27) and the driven grooves (4-30) are positioned on the same axis, are equal in size and shape, and the double-side driving heads (4-28) can be inserted into the driving grooves (4-27) or the driven grooves (4-30) through movement.

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