CN112317034A

CN112317034A - Intelligent coating treatment equipment

Info

Publication number: CN112317034A
Application number: CN202011331534.4A
Authority: CN
Inventors: 余粉粉
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-11-24
Filing date: 2020-11-24
Publication date: 2021-02-05

Abstract

The invention relates to a coating treatment device, in particular to an intelligent coating treatment device which comprises a linkage mechanism, a coating box mechanism and a grinding mechanism, wherein the device can automatically supplement raw materials, can mix, can grind and can collect powder, the linkage mechanism is connected with the coating box mechanism, the coating box mechanism is connected with the grinding mechanism, and the grinding mechanism is connected with the linkage mechanism.

Description

Intelligent coating treatment equipment

Technical Field

The invention relates to coating treatment equipment, in particular to intelligent coating treatment equipment.

Background

In the manufacturing process of the coating, in the traditional manufacturing process, the coating can be mixed only by the cooperation of a plurality of motors, the power is wasted, and a plurality of control units are needed, so that the intelligent coating processing equipment is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing intelligent coating processing equipment, wherein the equipment can automatically supplement raw materials, can mix, can grind and can collect powder.

In order to solve the technical problem, the invention relates to a coating treatment device, and particularly relates to an intelligent coating treatment device which comprises a linkage mechanism, a coating box mechanism and a grinding mechanism, wherein the device can automatically supplement raw materials, can mix, can grind and can collect powder.

The linkage mechanism is connected with the coating box mechanism, the coating box mechanism is connected with the grinding mechanism, and the grinding mechanism is connected with the linkage mechanism.

As a further optimization of the technical scheme, the linkage mechanism of the intelligent coating processing equipment comprises a rack with a rod, a rotating wheel, a belt, a shell, a belt pulley, a bearing seat, a belt pulley with a shaft, a belt I, a transmission belt pulley, a belt impeller with a shaft, a coupler, a motor, a piston with a rod, a hinged arm, a waist groove, a sliding seat, a limit sliding rod, a spring and a connecting shaft with a belt pulley, wherein the rack with the rod is connected with the shell in a sliding way, the rotating wheel is connected with the connecting shaft with the belt pulley, the connecting shaft with the belt pulley is rotationally connected with the shell, the connecting shaft with the belt pulley is connected with the belt in a friction way, the belt is connected with the belt pulley in a friction way, the belt pulley is connected with the belt pulley with the shaft, the belt pulley with the shell is rotationally connected with the bearing seat, the belt pulley with the, the driving belt pulley is connected with the belt shaft impeller, the belt shaft impeller is connected with the motor through the coupler, the belt rod piston is connected with the shell in a sliding mode, the articulated arm is hinged to the sliding seat, the sliding seat is connected with the shell in a sliding mode, the waist grooves are symmetrically arranged on two sides of the shell, the limiting sliding rod is connected with the sliding seat in a sliding mode, the spring sleeve is arranged on the limiting sliding rod in a sleeved mode, two ends of the spring sleeve are connected to the inner wall of the sliding seat and the inner.

As a further optimization of the technical scheme, the coating box mechanism of the intelligent coating treatment equipment comprises a base, a valve seat, a finished product box, a filter plate, a connecting pipe seat, a connecting pipe, a pipe supporting seat, a mixed flow box, a connecting bent pipe, a straight pipe, a box body, a secondary straight pipe, a raw material box, a pull pipe, a pipe orifice, a raw material inlet pipe, a one-way valve I, a hydraulic cylinder, a hydraulic rod and a gate, wherein the base is connected with a shell, the base is connected with a motor, the base is connected with the finished product box, the finished product box is provided with the valve seat, the filter plate is in sliding connection with the connecting pipe seat, the connecting pipe seat is used for communicating the finished product box with the connecting pipe, the connecting pipe is connected with the pipe supporting seat, the pipe supporting seat is connected with the mixed flow box, the mixed flow box is connected with the base, the connecting pipe is, lean on the box of downside to link to each other with the base, the box links to each other and communicates with second grade direct current pipe, second grade direct current pipe links to each other and communicates with raw material tank, be equipped with the raw materials admission pipe on the raw material tank, the mouth of pipe sets up on the pull pipe, the pull pipe links to each other and communicates with the box, the check valve sets up in the direct current pipe, check valve I sets up in the second grade direct current pipe, the pneumatic cylinder links to each other with the finished product case, the pneumatic cylinder links to each other with the valve seat, the pneumatic cylinder links to each other with the hydraulic stem, the hydraulic stem links to each other with the gate, gate and valve seat sliding connection, band pole piston and pull pipe sliding connection, band pole piston and.

As a further optimization of the technical scheme, the grinding mechanism of the intelligent coating processing equipment comprises a wind wheel driving motor, a wind wheel cavity, a powder collecting box, a powder pipe, a bearing seat a, a grinding box, a gear with a shaft, a feed inlet, a threaded plug, a grinding wheel and a wind wheel a with a shaft.

As further optimization of the technical scheme, the number of the box bodies of the intelligent coating processing equipment is two.

As a further optimization of the technical scheme, the wind wheel on the wind wheel A with the shaft of the intelligent coating processing equipment is made of high manganese steel.

The intelligent coating treatment equipment has the beneficial effects that:

according to the intelligent coating processing equipment, the equipment can automatically supplement raw materials, the equipment can mix, the equipment can grind, and the equipment can collect powder.

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 an intelligent paint processing apparatus according to the present invention.

Fig. 2 is a schematic structural diagram of an intelligent paint processing apparatus according to the present invention.

Fig. 3 is a schematic structural diagram three of an intelligent paint processing apparatus according to the present invention.

Fig. 4 is a schematic structural diagram of an intelligent paint processing apparatus according to a fourth embodiment of the present invention.

Fig. 5 is a schematic structural diagram of an intelligent paint processing apparatus according to a fifth embodiment of the present invention.

Fig. 6 is a first structural schematic diagram of a linkage mechanism 1 of an intelligent coating processing device according to the present invention.

Fig. 7 is a schematic structural diagram of a linkage mechanism 1 of an intelligent paint processing apparatus according to the second embodiment of the present invention.

Fig. 8 is a third schematic structural diagram of a linkage mechanism 1 of an intelligent paint processing apparatus according to the present invention.

Fig. 9 is a first structural schematic diagram of a paint tank mechanism 2 of an intelligent paint processing apparatus according to the present invention.

Fig. 10 is a schematic structural diagram of a paint tank mechanism 2 of an intelligent paint processing apparatus according to the present invention.

Fig. 11 is a third schematic structural diagram of a paint tank mechanism 2 of an intelligent paint processing apparatus according to the present invention.

Fig. 12 is a fourth schematic structural diagram of a paint tank mechanism 2 of an intelligent paint processing apparatus according to the present invention.

Fig. 13 is a fifth schematic structural diagram of a paint tank mechanism 2 of an intelligent paint processing apparatus according to the present invention.

Fig. 14 is a first schematic structural diagram of a grinding mechanism 3 of an intelligent paint processing apparatus according to the present invention.

Fig. 15 is a schematic structural diagram of a second grinding mechanism 3 of the intelligent paint processing apparatus according to the present invention.

Fig. 16 is a third schematic structural diagram of the grinding mechanism 3 of the intelligent paint processing apparatus according to the present invention.

Fig. 17 is a fourth schematic structural diagram of the grinding mechanism 3 of the intelligent paint processing apparatus of the present invention. In the figure: a link mechanism 1; a rack with a rod 1-1; 1-2 of a rotating wheel; 1-3 of a belt; 1-4 of a shell; 1-5 of belt pulleys; 1-6 of a bearing seat; belt pulley 1-7 with shaft; belt I1-8; 1-9 of a transmission belt pulley; 1-10 parts of impeller with shaft; 1-11 of a coupler; 1-12 of a motor; 1-13 of a piston with a rod; articulated arms 1-14; 1-15 parts of a waist groove; 1-16 of sliding seat; 1-17 of a limiting slide bar; springs 1-18; belt pulley connecting shafts 1 to 19; a paint tank mechanism 2; a base 2-1; a valve seat 2-2; 2-3 of a finished product box; 2-4 parts of a filter plate; connecting tube seats 2-5; connecting pipes 2-6; 2-7 parts of a pipe supporting seat; 2-8 of a mixed flow box; connecting bent pipes 2-9; 2-10 of straight-flow pipes; 2-11 parts of a box body; 2-12 parts of a secondary straight-flow pipe; 2-13 parts of a raw material box; 2-14 parts of a pull pipe; 2-15 parts of a pipe orifice; raw material inlet pipes 2 to 16; 2-17 of a one-way valve; a one-way valve I2-18; 2-19 of a hydraulic cylinder; 2-20 parts of hydraulic rod; 2-21 of gates; a grinding mechanism 3; a wind wheel driving motor 3-1; 3-2 of a wind wheel cavity; 3-3 of a powder collecting box; 3-4 parts of a powder pipe; bearing seat A3-5; grinding box 3-6; 3-7 parts of a gear with a shaft; a feed inlet is 3-8; 3-9 parts of a threaded plug; 3-10 parts of grinding wheel; the wind wheel A3-11 with the shaft.

Detailed Description

The first embodiment is as follows:

the present embodiment will be described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, and fig. 17, and the present invention relates to a paint processing apparatus, and more specifically, to an intelligent paint processing apparatus including a link mechanism 1, a paint tank mechanism 2, and a grinding mechanism 3, which can automatically replenish raw materials, can mix, can grind, and can collect powder.

The linkage mechanism 1 is connected with the coating box mechanism 2, the coating box mechanism 2 is connected with the grinding mechanism 3, and the grinding mechanism 3 is connected with the linkage mechanism 1.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and the embodiment further describes the embodiment, wherein the linkage mechanism 1 comprises a belt bar rack 1-1, a rotating wheel 1-2, a belt 1-3, a housing 1-4, a belt pulley 1-5, a bearing seat 1-6, a belt shaft belt pulley 1-7, a belt I1-8, a transmission belt pulley 1-9, a belt shaft impeller 1-10, a coupling 1-11, a motor 1-12, a belt bar piston 1-13, an articulated arm 1-14, a waist slot 1-15, a sliding seat 1-16, a limit sliding bar 1-17, a spring 1-18, a belt pulley connecting shaft 1-19, the belt rod rack 1-1 is connected with the shell 1-4 in a sliding way, the rotating wheel 1-2 is connected with the belt pulley connecting shaft 1-19, the belt pulley connecting shaft 1-19 is connected with the shell 1-4 in a rotating way, the belt pulley connecting shaft 1-19 is connected with the belt 1-3 in a friction way, the belt 1-3 is connected with the belt pulley 1-5 in a friction way, the belt pulley 1-5 is connected with the belt pulley 1-7 in a belt shaft way, the belt pulley 1-7 in a belt shaft way is connected with the shell 1-4 in a rotating way, the bearing seat 1-6 is connected with the shell 1-4 in a friction way, the bearing seat 1-6 is connected with the belt pulley 1-7 in a rotation way, the belt pulley 1-7 in a belt shaft way is connected with the belt I1-8 in a friction way, the belt I1-8 is connected with, the impeller with the shaft 1-10 is connected with the motor 1-12 through the shaft coupling 1-11, the piston with the rod 1-13 is connected with the shell 1-4 in a sliding way, the hinge arm 1-14 is hinged with the sliding seat 1-16, the sliding seat 1-16 is connected with the shell 1-4 in a sliding way, the waist grooves 1-15 are symmetrically arranged at two sides of the shell 1-4, the limit sliding rod 1-17 is connected with the sliding seat 1-16 in a sliding way, the spring 1-18 is sleeved on the limit sliding rod 1-17, two ends of the spring are connected with the sliding seat 1-16 and the inner wall of the shell 1-4, and the hinge arm 1-14 is hinged with the rotating.

The third concrete implementation mode:

the present embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, and fig. 17, and the present embodiment further describes the present embodiment, where the paint tank mechanism 2 includes a base 2-1, a valve seat 2-2, a product tank 2-3, a filter plate 2-4, a connection pipe seat 2-5, a connection pipe 2-6, a pipe support seat 2-7, a mixed flow tank 2-8, a connection elbow pipe 2-9, a straight flow pipe 2-10, a tank body 2-11, a secondary straight flow pipe 2-12, a raw material tank 2-13, a pull pipe 2-14, a pipe orifice 2-15, a raw material inlet pipe 2-16, a check valve 2-17, a check valve I2-18, a check, A hydraulic cylinder 2-19, a hydraulic rod 2-20, a gate 2-21, a base 2-1 connected with a shell 1-4, a motor 1-12 connected with the base 2-1, a finished product box 2-3 connected with the base 2-1, a valve seat 2-2 arranged on the finished product box 2-3, a filter plate 2-4 connected with a connecting pipe seat 2-5 in a sliding manner, a connecting pipe seat 2-5 connected with the finished product box 2-3 and a connecting pipe 2-6, a connecting pipe 2-6 connected with a pipe supporting seat 2-7, a pipe supporting seat 2-7 connected with a mixed flow box 2-8, a mixed flow box 2-8 connected with the base 2-1, a connecting pipe 2-6 connected with and communicated with the mixed flow box 2-8, a mixed flow box 2-8 connected with a straight flow pipe 2-10 through a connecting elbow 2-9, the straight-flow pipe 2-10 is connected with the box body 2-11, the box body 2-11 close to the lower side is connected with the base 2-1, the box body 2-11 is connected and communicated with the second-stage straight-flow pipe 2-12, the second-stage straight-flow pipe 2-12 is connected and communicated with the raw material box 2-13, the raw material inlet pipe 2-16 is arranged on the raw material box 2-13, the pipe orifice 2-15 is arranged on the pull pipe 2-14, the pull pipe 2-14 is connected and communicated with the box body 2-11, the one-way valve 2-17 is arranged in the straight-flow pipe 2-10, the one-way valve I2-18 is arranged in the second-stage straight-flow pipe 2-12, the hydraulic cylinder 2-19 is connected with the finished product box 2-3, the hydraulic cylinder 2-19 is connected with the valve seat 2-, the hydraulic rod 2-20 is connected with the gate 2-21, the gate 2-21 is connected with the valve seat 2-2 in a sliding way, the rod-equipped piston 1-13 is connected with the pull-out pipe 2-14 in a sliding way, the rod-equipped piston 1-13 is connected with the pipe orifice 2-15 in a sliding way, the shaft-equipped impeller 1-10 is connected with the mixed flow box 2-8 in a rotating way, the shaft coupling 1-11 is driven to rotate by the running of the motor 1-12, the shaft coupling 1-11 drives the shaft-equipped impeller 1-10 to rotate, the shaft-equipped impeller 1-10 drives the transmission belt pulley 1-9 to rotate, the transmission belt pulley 1-9 drives the rotating wheel 1-2 to rotate by the belt I1-8, the shaft-equipped belt pulley 1-7, the belt pulley 1-5 and the transmission belt pulley connecting shaft 1-19 of the belt 1-3, the rotating wheel 1-2 drives the sliding seat 1-16 to reciprocate through the articulated arm 1-14, the sliding seat 1-16 drives the piston 1-13 with the rod to reciprocate, the piston 1-13 with the rod can cause the pressure difference change in the pull pipe 2-14, thereby continuously flushing the one-way valve I2-18 from the raw material box 2-13 to suck the raw materials into the box body 2-11, then pressurizing and flushing the one-way valve 2-17 to enter the mixed flow box 2-8 to finish feeding, the two raw materials can be automatically premixed under the action of gravity when entering the mixed flow box 2-8, the rotation of the impeller 1-10 with the shaft can stir the two raw materials, then accelerating is carried out, the stirred coating enters the finished product box 2-3 from the connecting pipe 2-6, and is filtered by the filter plate 2-4 in the process, when the finished product needs to be taken out, the hydraulic cylinder 2-19 can pull the hydraulic rod 2-20, and the hydraulic rod 2-20 can pull the gate 2-21 upwards, so that the finished product flows out.

The fourth concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and the embodiment further describes the embodiment, wherein the grinding mechanism 3 comprises a wind wheel driving motor 3-1, a wind wheel cavity 3-2, a powder collecting box 3-3, a powder pipe 3-4, a bearing seat A3-5, a grinding box 3-6, a shaft gear 3-7, a feed inlet 3-8, a threaded plug 3-9, a grinding wheel 3-10, a shaft wind wheel A3-11, the wind wheel driving motor 3-1 is connected with the wind wheel cavity 3-2, the wind wheel cavity 3-2 is connected and communicated with the powder collecting box 3-3, the powder collecting box 3 is communicated with the grinding box 3-6 through a powder pipe 3-4, the bearing seat A3-5 is arranged on the grinding box 3-6, the bearing seat A3-5 is rotationally connected with the gear with a shaft 3-7, the gear with a shaft 3-7 is engaged with the rack with a rod 1-1, the feed inlet 3-8 is arranged on the grinding box 3-6, the screw plug 3-9 is in threaded connection with the grinding box 3-6, the grinding wheel 3-10 is connected with the gear with a shaft 3-7, the wind wheel with a shaft A3-11 is rotationally connected with the wind wheel cavity 3-2, the wind wheel with a shaft A3-11 is connected with the wind wheel driving motor 3-1, the rack with a rod 1-1 is driven to do reciprocating linear motion in the reciprocating motion process of the sliding seat 1-16, the rack with a rod 1-1 drives the gear with a shaft 3-7 to do reciprocating motion, the gear with a shaft 3-7 drives the grinding wheel 3-10 to do reciprocating motion, the two grinding wheels 3-10 are turned in opposite directions to grind the raw material and grind the raw material oppositely. Materials to be ground are added from a feed inlet 3-8, a wind wheel A3-11 with a shaft is driven to rotate by the operation of a wind wheel driving motor 3-1, negative pressure can be formed by the rotation of the wind wheel A3-11 with the shaft, ground powder is sucked into a powder collecting box 3-3, and the powder automatically sinks when the wind wheel A3-11 with the shaft stops rotating because the position of the wind wheel A3-11 with the shaft is located above, so that material accumulation on the wind wheel A3-11 with the shaft cannot be formed.

The fifth concrete implementation mode:

the present 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 the first embodiment will be further described with reference to the present embodiment, in which the number of the cases 2 to 11 is two.

The sixth specific implementation mode:

the present embodiment will be described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, and fig. 17, and the present embodiment further describes the first embodiment, in which the material of the rotor on the axis-bearing rotor a3-11 is high manganese steel.

The working principle of the device is as follows: the equipment can automatically supplement raw materials, the operation of the motor 1-12 drives the shaft coupling 1-11 to rotate, the shaft coupling 1-11 can drive the belt shaft impeller 1-10 to rotate, the belt shaft impeller 1-10 can drive the transmission belt pulley 1-9 to rotate, the transmission belt pulley 1-9 can drive the belt pulley connecting shaft 1-19 to rotate through the belt I1-8, the belt shaft pulley 1-7, the belt pulley 1-5 and the belt 1-3, the belt pulley connecting shaft 1-19 can drive the rotating wheel 1-2 to rotate, the rotating wheel 1-2 can drive the sliding seat 1-16 to reciprocate through the articulated arm 1-14, the sliding seat 1-16 can drive the belt rod piston 1-13 to reciprocate, and the belt rod piston 1-13 can cause the pressure difference change in the drawing pipe 2-14, thus, raw materials are continuously pumped into the box body 2-11 from the raw material box 2-13 by opening the one-way valve I2-18, then the raw materials are pressurized by opening the one-way valve 2-17 and then enter the mixed flow box 2-8, and feeding is finished; the equipment can mix, two raw materials can be automatically premixed under the action of gravity when entering the mixed flow box 2-8, the two raw materials can be stirred by the rotation of the impeller 1-10 with the shaft and then accelerated, so that the stirred coating enters the finished product box 2-3 from the connecting pipe 2-6, and is filtered by the filter plate 2-4 during the process, when a finished product needs to be taken out, the hydraulic rod 2-20 can be pulled by the hydraulic cylinder 2-19, and the gate 2-21 can be pulled upwards by the hydraulic rod 2-20, so that the finished product flows out; the equipment can grind, in the process of reciprocating the sliding seats 1-16, the rack with the rod 1-1 can be driven to do reciprocating linear motion, the rack with the rod 1-1 can drive the gear with the shaft 3-7 to do reciprocating rotation, the gear with the shaft 3-7 can drive the grinding wheels 3-10 to do reciprocating rotation, and the rotation directions of the two grinding wheels 3-10 are opposite, so that the raw material grinding and relative grinding functions are achieved. Adding materials to be ground from a feed inlet 3-8; the device can collect powder, the wind wheel driving motor 3-1 operates to drive the wind wheel with the shaft A3-11 to rotate, the wind wheel with the shaft A3-11 rotates to form negative pressure, ground powder is sucked into the powder collecting box 3-3, and the position of the wind wheel with the shaft A3-11 is located above the wind wheel with the shaft A3-11, so that the powder automatically sinks when the wind wheel with the shaft A3-11 stops rotating, and material accumulation on the wind wheel with the shaft A3-11 cannot be formed.

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

1. The utility model provides an intelligence coating treatment facility, includes link gear (1), scribbles paint box mechanism (2), grinds mechanism (3), its characterized in that: the linkage mechanism (1) is connected with the coating box mechanism (2), the coating box mechanism (2) is connected with the grinding mechanism (3), and the grinding mechanism (3) is connected with the linkage mechanism (1).

2. The intelligent paint processing apparatus of claim 1, wherein: the linkage mechanism (1) comprises a rack with a rod (1-1), a rotating wheel (1-2), a belt (1-3), a shell (1-4), belt pulleys (1-5), bearing seats (1-6), belt pulleys with a shaft (1-7), a belt I (1-8), a transmission belt pulley (1-9), an impeller with a shaft (1-10), a coupler (1-11), a motor (1-12), pistons with a rod (1-13), articulated arms (1-14), a waist groove (1-15), a sliding seat (1-16), a limiting sliding rod (1-17), a spring (1-18) and a connecting shaft with a belt wheel (1-19), the rack with a rod (1-1) is connected with the shell (1-4) in a sliding manner, the rotating wheel (1-2) is connected with the connecting shaft with the belt wheel (1-19), a belt pulley connecting shaft (1-19) is rotationally connected with a shell (1-4), the belt pulley connecting shaft (1-19) is frictionally connected with a belt (1-3), the belt (1-3) is frictionally connected with a belt pulley (1-5), the belt pulley (1-5) is connected with a belt shaft belt pulley (1-7), the belt shaft belt pulley (1-7) is rotationally connected with the shell (1-4), a bearing seat (1-6) is connected with the shell (1-4), the bearing seat (1-6) is rotationally connected with the belt shaft belt pulley (1-7), the belt shaft belt pulley (1-7) is frictionally connected with a belt I (1-8), the belt I (1-8) is frictionally connected with a transmission belt pulley (1-9), the transmission belt pulley (1-9) is connected with a belt shaft impeller (1-10), the impeller (1-10) with the shaft is connected with the motor (1-12) through the shaft coupling (1-11), the piston (1-13) with the rod is connected with the shell (1-4) in a sliding way, the articulated arm (1-14) is hinged with the sliding seat (1-16), the sliding seat (1-16) is connected with the shell (1-4) in a sliding way, the waist grooves (1-15) are symmetrically arranged at two sides of the shell (1-4), the limiting sliding rod (1-17) is connected with the sliding seat (1-16) in a sliding way, the spring (1-18) is sleeved on the limiting sliding rod (1-17) and two ends are connected with the sliding seat (1-16), the articulated arm (1-14) is hinged with the rotating wheel (1-2) on the inner wall of the shell (1-4).

3. The intelligent paint processing apparatus of claim 1, wherein: the coating box mechanism (2) comprises a base (2-1), a valve seat (2-2), a finished product box (2-3), a filter plate (2-4), a connecting pipe seat (2-5), a connecting pipe (2-6), a pipe supporting seat (2-7), a mixed flow box (2-8), a connecting bent pipe (2-9), a straight flow pipe (2-10), a box body (2-11), a secondary straight flow pipe (2-12), a raw material box (2-13), a drawing pipe (2-14), a pipe orifice (2-15), a raw material inlet pipe (2-16), a one-way valve (2-17), a one-way valve I (2-18), a hydraulic cylinder (2-19), a hydraulic rod (2-20) and a gate (2-21), wherein the base (2-1) is connected with a shell (1-4), the base (2-1) is connected with a motor (1-12), the base (2-1) is connected with a finished product box (2-3), a valve seat (2-2) is arranged on the finished product box (2-3), a filter plate (2-4) is connected with a connecting pipe seat (2-5) in a sliding manner, the connecting pipe seat (2-5) is used for communicating the finished product box (2-3) with a connecting pipe (2-6), the connecting pipe (2-6) is connected with a pipe supporting seat (2-7), the pipe supporting seat (2-7) is connected with a mixed flow box (2-8), the mixed flow box (2-8) is connected with the base (2-1), the connecting pipe (2-6) is connected and communicated with the mixed flow box (2-8), the mixed flow box (2-8) is communicated with a straight flow pipe (2-10) through a connecting elbow (2-9), the straight flow pipe (2-10) is connected with the box body (2-11), the box body (2-11) close to the lower side is connected with the base (2-1), the box body (2-11) is connected and communicated with the second-stage straight flow pipe (2-12), the second-stage straight flow pipe (2-12) is connected and communicated with the raw material box (2-13), the raw material inlet pipe (2-16) is arranged on the raw material box (2-13), the pipe orifice (2-15) is arranged on the pull pipe (2-14), the pull pipe (2-14) is connected and communicated with the box body (2-11), the check valve (2-17) is arranged in the straight flow pipe (2-10), the check valve I (2-18) is arranged in the second-stage straight flow pipe (2-12), the hydraulic cylinder (2-19) is connected with the finished product box (2-3), the hydraulic cylinder (2-19) is connected with the valve seat (2-2), the hydraulic cylinder (2-19) is connected with the hydraulic rod (2-20), the hydraulic rod (2-20) is connected with the gate (2-21), the gate (2-21) is connected with the valve seat (2-2) in a sliding manner, the piston (1-13) with the rod is connected with the pull pipe (2-14) in a sliding manner, the piston (1-13) with the rod is connected with the pipe orifice (2-15) in a sliding manner, and the impeller (1-10) with the shaft is connected with the mixed flow box (2-8) in a rotating manner.

4. The intelligent paint processing apparatus of claim 1, wherein: the grinding mechanism (3) comprises a wind wheel driving motor (3-1), a wind wheel cavity (3-2), a powder collecting box (3-3), a powder pipe (3-4), a bearing seat A (3-5), a grinding box (3-6), a gear (3-7) with a shaft, a feed inlet (3-8), a threaded plug (3-9), a grinding wheel (3-10) and a wind wheel A (3-11) with a shaft, wherein the wind wheel driving motor (3-1) is connected with the wind wheel cavity (3-2), the wind wheel cavity (3-2) is connected and communicated with the powder collecting box (3-3), the powder collecting box (3-3) is communicated with the grinding box (3-6) through the powder pipe (3-4), the bearing seat A (3-5) is arranged on the grinding box (3-6), the bearing seat A (3-5) is rotatably connected with a gear (3-7) with a shaft, the gear (3-7) with the shaft is meshed with a rack (1-1) with a rod, a feed inlet (3-8) is arranged on a grinding box (3-6), a threaded plug (3-9) is in threaded connection with the grinding box (3-6), a grinding wheel (3-10) is connected with the gear (3-7) with the shaft, a wind wheel A (3-11) with the shaft is rotatably connected with a wind wheel cavity (3-2), and a wind wheel A (3-11) with the shaft is connected with a wind wheel driving motor (3-1).

5. The intelligent paint processing apparatus of claim 3, wherein: the number of the box bodies (2-11) is two.

6. The intelligent paint processing apparatus of claim 4, wherein: the wind wheel on the wind wheel A (3-11) with the shaft is made of high manganese steel.