CN112190999A - Wear-resistant coating processing and preparing system - Google Patents

Abstract

The invention relates to the technical field of coating processing, in particular to a wear-resistant coating processing and preparing system which comprises a supporting mechanism, a filtering box body, a stirring mechanism, a filtering mechanism, a power mechanism and a transmission mechanism, the upper part of the supporting mechanism is fixedly connected with a filtering box body, the stirring mechanism is connected with the upper side in the filtering box body, the filtering mechanism is connected with the lower side in the filtering box body in a sliding way, two ends of the power mechanism are fixedly connected on the supporting mechanism, two sides of the transmission mechanism are connected on the supporting mechanism, the transmission mechanism is connected with the power mechanism in a sliding way, can remove about the in-process of stirring, increase the stirring efficiency of device, utilize the pressure differential that filtering mechanism removed the in-process and produced, carry out further grinding and secondary filter in paint conveying to power unit, can prevent to block up on the filter screen influence filter effect for filterable paint.

Description

Wear-resistant coating processing and preparing system

Technical Field

The invention relates to the technical field of coating processing, in particular to a wear-resistant coating processing and preparing system.

Background

For example, publication number CN109224585A discloses a high-efficiency filtering device for paint processing, which comprises a filtering box body, wherein two symmetrical sliding grooves are formed in the inner side wall of the filtering box body, a filtering tank is placed in the filtering box body, a filter screen is fixedly embedded in the inner bottom wall of the filtering tank, the upper parts of the left side surface and the right side surface of the filtering tank are fixedly connected with connecting blocks, one side surface, away from each other, of the two connecting blocks is fixedly connected with a sliding block matched with the sliding grooves, the sliding block is clamped in the sliding groove, the inner side wall of the filtering box body is provided with two symmetrical through holes, a sliding rod is placed in each through hole, the upper surface and the bottom surface of each sliding rod are fixedly connected with the inner top wall and the inner bottom wall of the two through holes respectively, connecting rods are fixedly connected with the left side surface and the right side surface of the filtering tank body, and one end, the upper surfaces of the ends, far away from each other, of the two connecting rods are fixedly connected with vibrating motors, the upper surface of each connecting rod is fixedly embedded with a sliding ring matched with the sliding rod, the sliding ring is sleeved with the sliding rod, and the outer surface of the bottom end of each sliding rod is fixedly connected with a baffle; in the device, only filtration can be performed, and the coating which does not pass through the filter plate cannot be discharged, so that continuous work cannot be performed, cleaning is required, and the working efficiency of the device is reduced.

Disclosure of Invention

The invention aims to provide a wear-resistant paint processing and preparing system which can grind and filter paint which does not pass through filtration for the second time.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a wear-resisting coating processing preparation system, includes supporting mechanism, filters box, rabbling mechanism, filtering mechanism, power unit and drive mechanism, the upper portion fixedly connected with of supporting mechanism filters the box, and the rabbling mechanism is connected at the inside upside of filtering the box, and filtering mechanism sliding connection is at the inside downside of filtering the box, and the equal fixed connection in both ends of power unit is on the supporting mechanism, and drive mechanism's both sides are all connected on the supporting mechanism, sliding connection between drive mechanism and the power unit.

According to the further optimization of the technical scheme, the wear-resistant paint processing and preparing system comprises a supporting frame, fixing frames I, fixing lugs and sliding rails, wherein two ends of each fixing frame I are fixedly connected to the supporting frame, the left side and the right side of each supporting frame I are fixedly connected with the two fixing frames I, and the upper side of each fixing frame I is fixedly connected with the sliding rail.

As further optimization of the technical scheme, the wear-resistant paint processing and preparing system comprises a filtering box body, a liquid pumping box body, fixing frames II, one-way valves I, feeding ports and electromagnetic valves, wherein the filtering box body comprises a stirring box body, the liquid pumping box body, the fixing frames II, the one-way valves I, the feeding ports and the electromagnetic valves, the stirring box body is fixedly connected to a supporting frame, the liquid pumping box body is arranged on two sides inside the stirring box body, the one-way valves I are fixedly connected to each liquid pumping box body, the two fixing frames II are respectively and fixedly connected to two sides inside the stirring box body, the feeding ports are arranged at the top of.

As further optimization of the technical scheme, the wear-resistant paint processing and preparing system comprises a shaft I, belt wheels I, a stirring frame and sliding grooves, wherein the shaft I is rotatably connected to two sides of a stirring box body, the belt wheels I are fixedly connected to two ends of the shaft I, the stirring frame is connected to the shaft I through keys, the sliding grooves are formed in two sides of the stirring frame, and the two sliding grooves are respectively in sliding connection with two fixing frames II.

As the further optimization of the technical scheme, the wear-resistant coating processing and preparing system comprises a support I, a filter plate, a support II, a one-way valve II and a sliding block I, wherein the support I is connected inside a stirring box in a sliding mode, the filter plate is fixedly connected onto the support I, the supports II are fixedly connected to two sides of the support I, the two supports II are respectively connected inside two liquid pumping boxes in a sliding mode, the two one-way valves II are fixedly connected to two sides of each support II, and the sliding blocks I are fixedly connected to two ends of the support I.

As the further optimization of the technical scheme, the wear-resistant coating processing and preparing system comprises a shaft II, a worm wheel, cams, belt wheels II and sliding blocks II, wherein two sides of the shaft II are rotatably connected to a support frame, two ends of the shaft II are fixedly connected with the belt wheels II, two sides of the shaft II are fixedly connected with the cams, the middle of the shaft II is fixedly connected with the worm wheel, the two sliding blocks II are respectively and slidably connected to sliding rails on two sides, a spring is arranged between each sliding block II and a fixing lug on two sides, the two sliding blocks II are respectively in contact with the two cams, the two sliding blocks II are respectively in contact with the two sliding blocks I, and the belt wheel II on each side is rotatably connected with the belt wheel I through a belt.

As further optimization of the technical scheme, the wear-resistant coating processing and preparing system comprises a support III, a motor I, a worm and a bevel gear I, wherein two ends of the support III are fixedly connected to a support frame, the motor I is fixedly connected to the support III, two sides of the worm are rotatably connected to the support III, one end of the worm is fixedly connected with an output shaft of the motor I, the bevel gear I is fixedly connected to the worm, and the worm gear are in transmission connection.

1. As further optimization of the technical scheme, the power mechanism of the wear-resistant paint processing and preparing system further comprises a grinding mechanism I, a grinding mechanism II and a screening mechanism, wherein the grinding mechanism is rotatably connected to the support III, the grinding mechanism II is fixedly connected to the fixing frame I, and the screening mechanism is fixedly connected to the support frame;

grind mechanism includes helical gear II, gear I, gear II and grinding miller, and helical gear II rotates to be connected on support III, rotates between helical gear II and the helical gear I to be connected, and the lower extreme fixedly connected with gear I of helical gear II, gear II rotate to be connected on support III, and the transmission is connected between gear I and the gear II, and the line segment fixedly connected with grinding miller of gear I.

As further optimization of the technical scheme, the wear-resistant paint processing and preparing system comprises a grinding mechanism II, a grinding body, an inner gear ring and springs I, wherein the lower end of the grinding box body is fixedly connected with the four springs I, the other end of each spring I is fixedly connected to a fixing frame I, the grinding body is rotatably connected to the inside of the grinding box body, the inner gear ring is fixedly connected to the grinding body, the inner gear ring is in transmission connection with a gear II, and the two liquid pumping boxes are communicated with the grinding box body through a guide pipe.

As further optimization of the technical scheme, the wear-resistant coating processing and preparing system comprises a screening box body, a filter plate, a feed opening, a water pump, a motor II and a scraper plate, wherein the screening box body is fixedly connected to a support frame, the filter plate is fixedly connected to the inside of the screening box body, the feed opening and the water pump are both fixedly connected to the bottom of the screening box body, the water pump is communicated with a stirring box body through a guide pipe, the motor II is fixedly connected to the upper end of the screening box body, and the scraper plate is fixedly connected to an output shaft of the motor II.

The wear-resistant coating processing and preparing system has the beneficial effects that:

according to the wear-resistant paint processing and preparing system, the paint is firstly filtered by the filtering box body, the stirring mechanism can be arranged to move left and right in the stirring process, the stirring efficiency of the device is increased, the paint which does not meet the filtering requirement and is not completely mixed is conveyed into the power mechanism for further grinding and secondary filtering by utilizing the pressure difference generated in the moving process of the filtering mechanism, impurities in the paint can be completely filtered, the paint is conveyed into the filtering box body for stirring, and the movement of the filtering mechanism can prevent the filtering effect from being influenced by the blockage of the filtered paint on the filtering net.

Drawings

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

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

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

FIG. 2 is a second overall structural view of the present invention;

FIG. 3 is a schematic structural view of the support mechanism of the present invention;

FIG. 4 is a schematic view of the construction of the filtration tank of the present invention;

FIG. 5 is a schematic structural view of the stirring mechanism of the present invention;

FIG. 6 is a schematic view of the construction of the filter mechanism of the present invention;

FIG. 7 is a schematic diagram of the power mechanism of the present invention;

FIG. 8 is a schematic structural view of the transmission mechanism of the present invention;

FIG. 9 is a schematic view of the grinding mechanism I of the present invention;

FIG. 10 is a schematic view of the grinding mechanism II of the present invention;

FIG. 11 is a first schematic structural view of a screening mechanism of the present invention;

FIG. 12 is a second schematic structural view of the screening mechanism of the present invention.

In the figure: a support mechanism 1; a support frame 101; a fixing frame I102; a fixing lug 103; a slide rail 104; a filter box body 2; a stirring tank 201; a liquid extraction tank body 202; a fixed mount II 203; a one-way valve I204; a feed inlet 205; a solenoid valve 206; a stirring mechanism 3; a shaft I301; a belt wheel I302; a stirring frame 303; a chute 304; a filtering mechanism 4; a bracket I401; a filter plate 402; a bracket II 403; a check valve II 404; a sliding block I405; a power mechanism 5; a bracket III 501; a motor I502; a worm 503; a bevel gear I504; a transmission mechanism 6; a shaft II 601; a worm gear 602; a cam 603; a pulley II 604; a sliding block II 605; a grinding mechanism I7; a bevel gear II 701; a gear I702; a gear II 703; a grinding wheel 704; a grinding mechanism II 8; a grinding box 801; a grinding body 802; an inner toothed ring 803; a spring I804; a screening mechanism 9; selecting a box body 901; a filter board 902; a feed opening 903; a water pump 904; a motor II 905; a squeegee 906.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 12, and a wear-resistant paint processing and preparing system includes a supporting mechanism 1, a filtering box 2, a stirring mechanism 3, a filtering mechanism 4, a power mechanism 5 and a transmission mechanism 6, wherein the upper portion of the supporting mechanism 1 is fixedly connected with the filtering box 2, the stirring mechanism 3 is connected to the upper side inside the filtering box 2, the filtering mechanism 4 is slidably connected to the lower side inside the filtering box 2, both ends of the power mechanism 5 are fixedly connected to the supporting mechanism 1, both sides of the transmission mechanism 6 are connected to the supporting mechanism 1, and the transmission mechanism 6 is slidably connected to the power mechanism 5; filter box 2 and at first filter coating, the setting of rabbling mechanism 3 can remove about the in-process of stirring, increase the stirring efficiency of device, be not conform to the coating of filtering requirement and incomplete mixing, will utilize the pressure differential that the filtering mechanism 4 removal in-process produced to carry out further grinding and secondary filter in power unit 5, can filter the impurity in the coating completely, stir in carrying to filtering box 2, the removal of filtering mechanism 4 can prevent to block up on the filter screen for filterable coating and influence the filter effect.

The second embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 12, and the present embodiment further describes the first embodiment, the supporting mechanism 1 includes a supporting frame 101, a fixing frame i 102, fixing lugs 103 and sliding rails 104, two ends of the fixing frame i 102 are fixedly connected to the supporting frame 101, two fixing frames i 102 are fixedly connected to the left and right sides of the supporting frame 101, and the sliding rails 104 are fixedly connected to the upper side of each fixing frame i 102.

The third concrete implementation mode:

the second embodiment is further described with reference to fig. 1 to 12, where the filter box 2 includes a stirring box 201, a liquid-extracting box 202, two fixing frames ii 203, a one-way valve i 204, a feeding port 205 and an electromagnetic valve 206, the stirring box 201 is fixedly connected to the supporting frame 101, the liquid-extracting box 202 is disposed on both sides of the inside of the stirring box 201, the one-way valve i 204 is fixedly connected to each liquid-extracting box 202, the two fixing frames ii 203 are respectively fixedly connected to both sides of the inside of the stirring box 201, the feeding port 205 is disposed on the top of the stirring box 201, the electromagnetic valve 206 is disposed on the feeding port 205, and the discharging port is disposed on the front side of the stirring box 201; can make rabbling mechanism 3 carry out the removal about at the in-process of stirring through setting up mount II 203, the stirring effect of multiplicable device through setting up drawing liquid box 202 and check valve I204, utilizes the pressure differential of filter mechanism 4 in the removal in-process production, carries the material of caking to grinding mechanism I7 in with stirring box 201 and grinds.

The fourth concrete implementation mode:

the third embodiment is further described with reference to fig. 1 to 12, in which the stirring mechanism 3 includes a shaft i 301, a pulley i 302, a stirring frame 303 and sliding chutes 304, the shaft i 301 is rotatably connected to two sides of the stirring tank 201, two ends of the shaft i 301 are fixedly connected to the pulley i 302, the stirring frame 303 is connected to the shaft i 301 through keys, two sides of the stirring frame 303 are provided with the sliding chutes 304, and the two sliding chutes 304 are respectively connected to two fixing frames ii 203 in a sliding manner; when the transmission mechanism 6 rotates, the belt wheel I302 is driven to rotate through the belt, the belt wheel I302 drives the shaft I301 and the stirring frame 303 to rotate, and the two ends of the stirring frame 303 are provided with the sliding grooves 304 which are connected with the two fixing frames II 203 in a sliding manner, so that when the stirring frame 303 rotates, the left and right movement can be accompanied.

The fifth concrete implementation mode:

the fourth embodiment is further described with reference to fig. 1 to 12, where the filter mechanism 4 includes a support i 401, a filter plate 402, a support ii 403, a check valve ii 404, and a sliding block i 405, the support i 401 is slidably connected inside the agitator tank 201, the filter plate 402 is fixedly connected to the support i 401, the supports ii 403 are fixedly connected to both sides of the support i 401, the two supports ii 403 are respectively slidably connected inside the two pumping tanks 202, the two check valves ii 404 are fixedly connected to both sides of each support ii 403, and the sliding block i 405 is fixedly connected to both ends of the support i 401; the transmission mechanism 6 pushes the filtering mechanism 4 to move left and right, when the materials are stirred, the materials are not completely stirred, the materials after being caked can not pass through the filtering plate 402, the materials after being caked can not be sucked into the liquid pumping box 202 due to the left and right movement of the filtering mechanism 4, the materials after being caked can be conveyed to the middle of the grinding mechanism I7 to be ground by utilizing the pressure difference in the liquid pumping box 202, and meanwhile, the materials after being caked can be conveyed to the middle of the grinding mechanism I7 by utilizing the one-way valve II 404.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1 to 12, and the fifth embodiment is further described, where the transmission mechanism 6 includes a shaft ii 601, a worm wheel 602, a cam 603, a pulley ii 604, and a sliding block ii 605, both sides of the shaft ii 601 are rotatably connected to the support frame 101, both ends of the shaft ii 601 are fixedly connected to the pulley ii 604, both sides of the shaft ii 601 are fixedly connected to the cam 603, a middle portion of the shaft ii 601 is fixedly connected to the worm wheel 602, two sliding blocks ii 605 are respectively slidably connected to the sliding rails 104 on both sides, a spring is disposed between each sliding block ii 605 and the fixing lugs 103 on both sides, the two sliding blocks ii 605 are respectively contacted with the two cams 603, the two sliding blocks ii 605 are respectively contacted with the two i 405, and the pulley ii 604 on each side is rotatably connected to the pulley i 302 through a belt; the worm wheel 602 can be driven to rotate by the driving power mechanism 5, the worm wheel 602 drives the cam 603 and the belt wheel II 604 which are fixedly connected to the shaft II 601 to rotate, the rotation of the cam 603 can push the sliding block II 605 to move up and down, the sliding block II 605 can be pushed to move alternatively due to the angle arrangement between the two cams 603, and the sliding block I40 can be pushed due to the alternative movement of the sliding block II 605, so that the filtering mechanism 4 moves left and right.

The seventh embodiment:

the embodiment is described below with reference to fig. 1 to 12, and the sixth embodiment is further described in the present embodiment, where the power mechanism 5 includes a support iii 501, a motor i 502, a worm 503 and a bevel gear i 504, two ends of the support iii 501 are fixedly connected to the support 101, the motor i 502 is fixedly connected to the support iii 501, two sides of the worm 503 are both rotatably connected to the support iii 501, one end of the worm 503 is fixedly connected to an output shaft of the motor i 502, the bevel gear i 504 is fixedly connected to the worm 503, and the worm 503 is in transmission connection with the worm wheel 602; when the device is used, the driving motor I502 drives the worm 503 to rotate, and the worm 503 drives the bevel gear I504 to rotate.

The specific implementation mode is eight:

the embodiment is described below with reference to fig. 1 to 12, and the seventh embodiment is further described in the present embodiment, the power mechanism 5 further includes a grinding mechanism i 7, a grinding mechanism ii 8, and a screening mechanism 9, the grinding mechanism 7 is rotatably connected to the bracket iii 501, the grinding mechanism ii 8 is fixedly connected to the fixing frame i 102, and the screening mechanism 9 is fixedly connected to the supporting frame 101;

the grinding mechanism 7 comprises a bevel gear II 701, a gear I702, a gear II 703 and a grinding wheel 704, wherein the bevel gear II 701 is rotatably connected to a support III 501, the bevel gear II 701 is rotatably connected with a bevel gear I504, the lower end of the bevel gear II 701 is fixedly connected with the gear I702, the gear II 703 is rotatably connected to the support III 501, the gear I702 is in transmission connection with the gear II 703, and the line segment of the gear I702 is fixedly connected with the grinding wheel 704; when helical gear I504 rotated, the intermeshing drives helical gear II 701 and rotates between helical gear II 701 and the helical gear I504, and the rotation of helical gear II 701 will drive gear I702 and grinding miller 704 and rotate, and the rotation of grinding miller 704 can grind the material, because the transmission is connected between gear I702 and gear II 703, will drive gear II 703 and rotate when I702 of gear rotates.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1 to 12, and the embodiment further describes an eighth embodiment, where the grinding mechanism ii 8 includes a grinding box 801, a grinding body 802, an internal toothed ring 803 and a spring i 804, the lower end of the grinding box 801 is fixedly connected with four springs i 804, the other end of each spring i 804 is fixedly connected to the fixing frame i 102, the grinding body 802 is rotatably connected to the inside of the grinding box 801, the internal toothed ring 803 is fixedly connected to the grinding body 802, the internal toothed ring 803 is in transmission connection with the gear ii 703, and the two liquid pumping boxes 202 are communicated with the grinding box 801 through a conduit; because gear II 703 is connected with inner ring gear 803 transmission, the rotation of gear II 703 will drive rinding body 802 and rotate, because inner ring gear 803 and the setting of gear II 703, can make rinding body 802 opposite with the direction of rotation of grinding miller 704, the grinding effect that can effectual increase device, the setting of spring I804 can be guaranteed at the grinding in-process, if when hard impurity can't grind appearing, the clearance between rinding body 802 and the grinding miller 704 will change, make impurity drop in screening mechanism 9.

The detailed implementation mode is ten:

the following describes the present embodiment with reference to fig. 1 to 12, and the present embodiment further describes an eighth embodiment, where the screening mechanism 9 includes a screening box 901, a filtering plate 902, a material outlet 903, a water pump 904, a motor ii 905 and a scraping plate 906, the screening box 901 is fixedly connected to the supporting frame 101, the filtering plate 902 is fixedly connected to the inside of the screening box 901, the material outlet 903 and the water pump 904 are both fixedly connected to the bottom of the screening box 901, the water pump 904 is communicated with the stirring box 201 through a conduit, the motor ii 905 is fixedly connected to the upper end of the screening box 901, and the scraping plate 906 is fixedly connected to an output shaft of the motor ii 905; grind material and impurity after mechanism II 8 grinds and will carry to screening box 901 in the middle of, the filtration through filter 902 can stay the impurity that the diameter is too big on filter 902, drives scraper blade 906 through driving motor II 905 and rotates, and scraper blade 906's rotation can concentrate the impurity on filter 902 and locate the discharge at feed opening 903, and the material through filter 902 will be carried to stirring box 201 in the middle of through water pump 904.

The invention relates to a wear-resistant paint processing and preparing system, which has the working principle that:

when in use, the worm 503 is driven to rotate by the driving motor I502, the helical gear I504 is driven to rotate by the worm 503, the helical gear I504 rotates to drive the helical gear II 701 to rotate by the mutual meshing between the helical gear II 701 and the helical gear I504, the helical gear II 701 rotates to drive the gear I702 and the grinding wheel 704 to rotate, the grinding wheel 704 rotates to grind materials, the gear I702 is in transmission connection with the gear II 703, the gear I702 rotates to drive the gear II 703 to rotate, the gear II 703 rotates to drive the grinding body 802 to rotate due to the transmission connection between the gear II 703 and the inner gear ring 803, the rotation directions of the grinding body 802 and the grinding wheel 704 are opposite due to the arrangement of the inner gear ring 803 and the gear II, the grinding effect of the device can be effectively increased, the arrangement of the spring I804 can ensure that in the grinding process, if hard impurities cannot be ground, the gap between the grinding body 802 and the grinding wheel 704 is changed, so that the impurities fall into the screening mechanism 9, the impurities with overlarge diameters can be left on the filter plate 902 through the filtration of the filter plate 902, the scraper 906 is driven to rotate through the driving motor II 905, the impurities on the filter plate 902 can be concentrated and discharged at the discharge port 903 through the rotation of the scraper 906, the materials passing through the filter plate 902 are conveyed into the stirring box 201 through the water pump 904, the worm wheel 602 drives the cam 603 and the belt wheel II 604 fixedly connected to the shaft II 601 to rotate, the sliding block II 605 is driven to move up and down through the rotation of the cam 603, the sliding block II 605 can be alternately driven to move due to the angle setting between the two cams 603, the sliding block I40 is driven due to the alternate movement of the sliding block II 605, so that the filtering mechanism 4 moves left and right, when the belt wheel II 604 rotates, the belt wheel I302 is driven by a belt to rotate, the belt wheel I302 drives the shaft I301 and the stirring frame 303 to rotate, as the two ends of the stirring frame 303 are provided with the sliding chutes 304, the sliding chutes 304 are connected with the two fixing frames II 203 in a sliding way, when the stirring frame 303 rotates, the stirring mechanism 3 moves left and right during stirring along with the left and right movement, the stirring effect of the device can be increased, the liquid pumping box body 202 and the one-way valve I204 are arranged, the transmission mechanism 6 pushes the filtering mechanism 4 to move left and right, when the materials are stirred, the materials are agglomerated in the filtering box body 2 due to incomplete stirring, the agglomerated materials can not pass through the filtering plate 402, due to the left and right movement of the filtering mechanism 4, the caked materials are sucked into the liquid pumping box 202 by utilizing the pressure difference in the liquid pumping box 202, meanwhile, materials agglomerated in the stirring tank body 201 are conveyed to the grinding mechanism I7 to be ground by using the one-way valve II 404.

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 (10)

1. The utility model provides a wear-resisting coating processing preparation system, includes supporting mechanism (1), filters box (2), rabbling mechanism (3), filtering mechanism (4), power unit (5) and drive mechanism (6), its characterized in that: the upper portion fixedly connected with of supporting mechanism (1) filters box (2), and rabbling mechanism (3) are connected at the inside upside of filtering box (2), and filtering mechanism (4) sliding connection is at the inside downside of filtering box (2), and the equal fixed connection in both ends of power unit (5) is on supporting mechanism (1), and the both sides of drive mechanism (6) are all connected on supporting mechanism (1), sliding connection between drive mechanism (6) and power unit (5).

2. The wear-resistant paint processing and preparing system according to claim 1, wherein: the supporting mechanism (1) comprises a supporting frame (101), a fixing frame I (102), fixing lugs (103) and sliding rails (104), wherein two ends of the fixing frame I (102) are fixedly connected to the supporting frame (101), two fixing frames I (102) are fixedly connected to the left side and the right side of the supporting frame (101), and the sliding rails (104) are fixedly connected to the upper side of each fixing frame I (102).

3. The wear-resistant paint processing and preparing system according to claim 2, wherein: filter box (2) including agitator tank (201), drawing liquid box (202), mount II (203), check valve I (204), feed inlet (205) and solenoid valve (206), agitator tank (201) fixed connection is on support frame (101), the inside both sides of agitator tank (201) all are provided with drawing liquid box (202), equal fixedly connected with check valve I (204) on every drawing liquid box (202), two mount II (203) fixed connection are respectively in the inside both sides of agitator tank (201), feed inlet (205) set up the top at agitator tank (201), be provided with solenoid valve (206) on feed inlet (205), the front side of agitator tank (201) is provided with the discharge gate.

4. The wear-resistant paint processing and preparing system according to claim 3, wherein: rabbling mechanism (3) are including axle I (301), band pulley I (302), stirring frame (303) and spout (304), and axle I (301) are rotated and are connected in the both sides of stirring box (201), and the equal fixedly connected with band pulley I (302) in both ends of axle I (301), and stirring frame (303) are through the key connection on axle I (301), and the both sides of stirring frame (303) all are provided with spout (304), two spout (304) respectively with two mount II (203) sliding connection.

5. The wear-resistant paint processing and preparing system according to claim 3, wherein: filter equipment (4) are including support I (401), filter (402), support II (403), check valve II (404) and sliding block I (405), support I (401) sliding connection is in the inside of agitator tank (201), fixedly connected with filter (402) is gone up in support I (401), the equal fixedly connected with support II (403) in both sides of support I (401), two support II (403) sliding connection are inside two drawing liquid boxes (202) respectively, two check valve II (404) of the equal fixedly connected with in both sides of every support II (403), the equal fixedly connected with sliding block I (405) in both ends of support I (401).

6. The wear-resistant paint processing and preparing system according to claim 5, wherein: the transmission mechanism (6) comprises a shaft II (601) and a worm wheel (602), cam (603), band pulley II (604) and sliding block II (605), the both sides of axle II (601) are all rotated and are connected on support frame (101), the equal fixedly connected with band pulley II (604) in both ends of axle II (601), the equal fixedly connected with cam (603) in both sides of axle II (601), the middle part fixedly connected with worm wheel (602) of axle II (601), two sliding block II (605) sliding connection respectively are on slide rail (104) of both sides, every sliding block II (605) respectively with both sides fixed ear (103) between all be provided with the spring, two sliding block II (605) contact with two cam (603) respectively, two sliding block II (605) contact respectively with between two sliding block I (405), be connected through the belt rotation between the band pulley II (604) of each side and band pulley I (302).

7. The wear-resistant paint processing and preparing system according to claim 6, wherein: the power mechanism (5) comprises a support III (501), a motor I (502), a worm (503) and a bevel gear I (504), two ends of the support III (501) are fixedly connected to the support frame (101), the motor I (502) is fixedly connected to the support III (501), two sides of the worm (503) are rotatably connected to the support III (501), one end of the worm (503) is fixedly connected with an output shaft of the motor I (502), the bevel gear I (504) is fixedly connected to the worm (503), and the worm (503) is in transmission connection with a worm wheel (602).

8. The wear-resistant paint processing and preparing system according to claim 7, wherein: the power mechanism (5) further comprises a grinding mechanism I (7), a grinding mechanism II (8) and a screening mechanism (9), the grinding mechanism (7) is rotatably connected to the support frame III (501), the grinding mechanism II (8) is fixedly connected to the fixing frame I (102), and the screening mechanism (9) is fixedly connected to the support frame (101);

grind mechanism (7) including helical gear II (701), gear I (702), gear II (703) and grinding miller (704), helical gear II (701) rotate to be connected on support III (501), rotate between helical gear II (701) and helical gear I (504) to be connected, the lower extreme fixedly connected with gear I (702) of helical gear II (701), gear II (703) rotate to be connected on support III (501), the transmission is connected between gear I (702) and gear II (703), the line segment fixedly connected with grinding miller (704) of gear I (702).

9. The system for processing and preparing the wear-resistant coating according to claim 8, wherein: grind II (8) of mechanism including grinding box (801), rinding body (802), interior ring gear (803) and spring I (804), grind four springs I (804) of lower extreme fixedly connected with of box (801), the equal fixed connection of the other end of every spring I (804) is on mount I (102), the inside rotation of grinding box (801) is connected with rinding body (802), fixedly connected with interior ring gear (803) on rinding body (802), transmission is connected between interior ring gear (803) and gear II (703), communicate through the pipe between two drawing liquid boxes (202) and the grinding box (801).

10. The system for processing and preparing the wear-resistant coating according to claim 9, wherein: screening mechanism (9) are including screening box (901), filter (902), feed opening (903), water pump (904), motor II (905) and scraper blade (906), screening box (901) fixed connection is on support frame (101), filter (902) fixed connection is inside screening box (901), equal fixed connection in the bottom of screening box (901) feed opening (903) and water pump (904), through the pipe intercommunication between water pump (904) and stirring box (201), the upper end of motor II (905) fixed connection screening box (901), fixedly connected with scraper blade (906) on the output shaft of motor II (905).

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