CN115368820A

CN115368820A - Corrosion-resistant aluminum alloy coating material

Info

Publication number: CN115368820A
Application number: CN202211084899.0A
Authority: CN
Inventors: 杨丹; 赵海强
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-09-06
Filing date: 2022-09-06
Publication date: 2022-11-22

Abstract

The invention relates to a coating material, in particular to a corrosion-resistant aluminum alloy coating material. The coating material is composed of the following raw materials in parts by weight: 1-6 parts of epoxy resin, 10-20 parts of fiber, 10 parts of silicone-acrylic emulsion, 25-30 parts of butanetriol, 10-12 parts of titanium dioxide, 10-15 parts of flaky mica powder, 10-20 parts of graphite powder, 1-18 parts of an accelerator, 5-8 parts of a thickening agent, 4-8 parts of a leveling agent, 4-6 parts of a dispersing agent, 2-6 parts of a defoaming agent, 2-4 parts of a preservative, 2-5 parts of a coupling agent and 5-20 parts of a toughening agent; and coating the aluminum alloy plate treated by the fiber combination device. The fiber combining device comprises a slide bar and triangular cutters, and the triangular cutters are fixed on the slide bar from front to back. The fiber combining device further comprises a rotating strip, a hydraulic cylinder I and guide rods, the guide rods are fixedly connected to the front end and the rear end of the rotating strip, and the front end and the rear end of the sliding strip are respectively connected to the two guide rods in a sliding mode. The coating material is provided with fibers, so that the crack resistance and the three-dimensional aesthetic property of the material are improved.

Description

Corrosion-resistant aluminum alloy coating material

Technical Field

The invention relates to a coating material, in particular to a corrosion-resistant aluminum alloy coating material.

Background

The coating is a solid continuous film obtained by coating once, and is a thin plastic layer coated on a substrate such as metal, fabric, plastic and the like for the purposes of protection, insulation, decoration and the like. The coating material can be in a gas state, a liquid state or a solid state, and the type and the state of the coating material are generally determined according to the substrate needing to be sprayed. In order to protect the aluminum alloy, the surface of the aluminum alloy needs to be coated, but the traditional coating only has color, does not have three-dimensional aesthetic property and has common cracking resistance.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides the corrosion-resistant aluminum alloy coating material, which has the beneficial effects that the fibers are arranged in the coating material, so that the crack resistance and the three-dimensional aesthetic property of the material are improved.

The corrosion-resistant aluminum alloy coating material is composed of the following raw materials in parts by weight: 1-6 parts of epoxy resin, 10-20 parts of fiber, 10 parts of silicone-acrylic emulsion, 25-30 parts of butanetriol, 10-12 parts of titanium dioxide, 10-15 parts of flake mica powder, 10-20 parts of graphite powder, 1-18 parts of an accelerator, 5-8 parts of a thickening agent, 4-8 parts of a leveling agent, 4-6 parts of a dispersing agent, 2-6 parts of a defoaming agent, 2-4 parts of a preservative, 2-5 parts of a coupling agent and 5-20 parts of a toughening agent; and coating the aluminum alloy plate treated by the fiber bonding device.

The fiber is nylon fiber yarn.

The fiber combining device comprises a slide bar and triangular cutters, and the triangular cutters are fixed on the slide bar from front to back.

The fiber combining device further comprises a rotating strip, a hydraulic cylinder I and guide rods, the guide rods are fixedly connected to the front end and the rear end of the rotating strip respectively, the front end and the rear end of the sliding strip are connected to the two guide rods in a sliding mode respectively, the hydraulic cylinder I is fixed to the rotating strip, and the movable end of the hydraulic cylinder I is fixed to the sliding strip.

Drawings

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

FIG. 1 is a first schematic structural view of a fiber bonding apparatus;

FIG. 2 is a schematic structural view II of the fiber bonding apparatus;

FIG. 3 is a third schematic view of the fiber bonding apparatus;

FIG. 4 is a first schematic structural view of a translation stage;

FIG. 5 is a second structural view of the translation stage;

FIG. 6 is a first schematic structural diagram of a pallet;

FIG. 7 is a second schematic structural view of a pallet;

FIG. 8 is a schematic structural view of a gantry;

FIG. 9 is a schematic structural view of the insert column;

fig. 10 is a schematic structural view of an arc-shaped sheet.

In the figure: a translation stage 101; a side shaft 102; a rotating bar 103; a hydraulic cylinder I104; a slide bar 105; a guide bar 106; a triangular cutter 107;

a pallet 201; a support bar 202; a track rod 203; a screw 204; a side seat 205; a ramp 206; a hydraulic cylinder II207; a right-angle clip 208;

a gantry 301; a post 302; a chute 303; a lifting column 304; a hydraulic cylinder III305; a hydraulic cylinder IV306; a T-shaped frame 307;

an arc piece 401; a side frame 402; a handle 403.

Detailed Description

The corrosion-resistant aluminum alloy coating material is composed of the following raw materials in parts by weight: 5 parts of epoxy resin, 15 parts of fiber, 5 parts of silicone-acrylic emulsion, 30 parts of butanetriol, 12 parts of titanium dioxide, 15 parts of flake mica powder, 10 parts of graphite powder, 9 parts of accelerator, 6 parts of thickener, 5 parts of flatting agent, 6 parts of dispersant, 3 parts of defoaming agent, 4 parts of preservative, 2 parts of coupling agent and 10 parts of toughening agent; and coating the aluminum alloy plate treated by the fiber bonding device.

Through adding the fibre in the coating for the fibre is flatly laid on the aluminum alloy, makes the fibre form the line, and fibre itself has certain width, makes to form fibrous three-dimensional line on the coating, not only makes the coating crack resistance, and makes the coating have a three-dimensional aesthetic property.

As shown in fig. 4 to 5, this example can achieve the effect of enhancing the three-dimensional aesthetic effect of the surface of the aluminum alloy sheet.

Since the fiber bonding apparatus includes the slide bar 105 and the triangular cutter 107, a plurality of triangular cutters 107 are welded to the slide bar 105 from front to rear. A plurality of triangular cutters 107 are obliquely tangent to the aluminum alloy plate by moving the sliding strip 105, a plurality of tilting parts are cut on the surface of the aluminum alloy plate, fibers are laid on the surface of the aluminum alloy plate, the tilting parts hook the fibers, then the surface of the aluminum alloy plate is coated with paint, the fibers are prevented from being separated from the aluminum alloy plate by the plurality of tilting parts, and the tilting parts further improve the three-dimensional aesthetic effect of the surface of the aluminum alloy plate.

This example can achieve the effect of making a plurality of triangular cutters 107 tangent to the aluminum alloy sheet as shown in FIGS. 4 to 5.

The fiber combining device further comprises a rotating strip 103, a hydraulic cylinder I104 and guide rods 106, the guide rods 106 are welded at the front end and the rear end of the rotating strip 103, the front end and the rear end of a sliding strip 105 are respectively connected to the two guide rods 106 in a sliding mode, the hydraulic cylinder I104 is connected to the rotating strip 103 through screws, and the movable end of the hydraulic cylinder I104 is connected to the sliding strip 105. And then the sliding strip 105 slides along the two guide rods 106 through the extension and retraction of the hydraulic cylinder I104, and then the plurality of triangular cutters 107 are driven to move, so that the plurality of triangular cutters 107 can be tangent to the aluminum alloy plate.

As shown in fig. 4 to 5, this example can achieve the effect of controlling the pattern of the cut-out plurality of raised portions.

Because fibre combination device still includes translation frame 101 and side shaft 102, the side shaft 102 has all been welded at the front and back both ends of commentaries on classics strip 103, two side shafts 102 rotate respectively through the bearing and connect in translation frame 101 front and back both ends, there is servo motor I on translation frame 101 through screwed connection, servo motor I's output shaft passes through the shaft coupling to be fixed on one of them side shaft 102, and then use the axis of side shaft 102 as the hub rotation through servo motor I drive translation frame 101, and then change the angle of a plurality of triangle-shaped cutters 107 tangential aluminium alloy plate, and then the pattern of a plurality of perk parts of control cutting.

As shown in FIGS. 6 to 7, this example can achieve the effect of making a plurality of the slitting knives 107 tangent to different positions on the aluminum alloy sheet.

Because the fiber bonding device further comprises the track rods 203 and the side seats 205, the two side seats 205 are oppositely arranged left and right, the two track rods 203 are welded between the two side seats 205, and the lower part of the translation frame 101 is connected on the two track rods 203 in a left-right sliding mode. So that the translation frame 101 can move left and right along the direction of the two track rods 203, and further adjust the left and right positions of the triangular cutters 107, and adjust the left and right positions of the triangular cutters 107, so that the triangular cutters 107 can be tangential to different positions on the aluminum alloy plate.

As shown in fig. 6 to 7, this example can achieve the effect that the pallet 201 supports the aluminum alloy plate.

Because the fiber combination device also comprises a supporting plate 201, a supporting strip 202 and an inclined frame 206, the inclined frame 206 is welded at the outer side of each of the two side seats 205, the supporting strip 202 is welded between the upper parts of the two inclined frames 206, and the supporting plate 201 is connected to the middle part of the upper side of the supporting strip 202 through a screw. And then can place the aluminium alloy plate that will wait to cut on layer board 201, layer board 201 supports aluminium alloy plate.

This example can achieve the effect of fixing the aluminum alloy sheet at the time of cutting, as shown in FIGS. 6 to 7.

Because fibre combination device still includes pneumatic cylinder II207 and right angle clamp 208, the equal sliding connection in both ends has right angle clamp 208 about holding in the palm strip 202, and both ends all have pneumatic cylinder II207 through the screw connection about holding in the palm strip 202, and two pneumatic cylinder II 207's flexible end passes through the screw connection respectively in the outside of two right angle clamps 208. And then through the flexible two right angle clamps 208 of control respectively of two pneumatic cylinder II207 slip from side to side on holding in the palm strip 202, and then control two right angle clamps 208 and press from both sides respectively in the left and right sides of aluminum alloy plate, it is fixed with the aluminum alloy plate when the cutting.

As shown in fig. 6 to 7, this example can achieve the effect that the lead screw 204 rotates to drive the translation frame 101 to slide along the two track rods 203.

Because the fiber combining device further comprises a screw rod 204, one of the side seats 205 is connected with a servo motor II through a screw, an output shaft of the servo motor II is connected with the screw rod 204 through a coupler, the screw rod 204 is in threaded fit with the translation frame 101, the servo motor II drives the screw rod 204 to rotate, and the screw rod 204 rotates to drive the translation frame 101 to slide along the two track rods 203.

This example can achieve the effect of pressing the drawn fibers against the aluminum alloy sheet as shown in FIGS. 8 to 9.

Because the fiber combination device further comprises the inserting columns 302, the chutes 303 and the T-shaped frames 307, a plurality of inserting columns 302 are welded on the lower sides of the two T-shaped frames 307 which are oppositely arranged front and back, from left to right, the two T-shaped frames 307 are arranged on the outer sides of the two inserting columns 302, the two T-shaped frames 307 are located above the supporting plate 201, when fibers need to be added on the aluminum alloy plate, the two T-shaped frames 307 are close to each other, the inserting columns 302 on the two T-shaped frames 307 are inserted into a cluster of fibers, the fibers are hooked through the chutes 303 on the inserting columns 302, the two T-shaped frames 307 are far away from each other, the fiber cluster is pulled to the front side and the back side through the inserting columns 302, the fibers are pulled back and forth, the pulled fibers are pressed on the aluminum alloy plate, and then the coating is coated on the aluminum alloy plate, so that the fibers are adhered on the aluminum alloy plate.

The fiber combining device further comprises a door-shaped frame 301, lifting columns 304, hydraulic cylinders III305 and hydraulic cylinders IV306, the door-shaped frame 301 is arranged in the middle of the lower side of the supporting plate 201, the front end and the rear end of the door-shaped frame 301 are vertically connected with the lifting columns 304 in a sliding mode, the two T-shaped frames 307 are respectively connected to the upper portions of the two lifting columns 304 in the front-rear direction in a sliding mode, the front end and the rear end of the door-shaped frame 301 are respectively connected with the hydraulic cylinders III305 through screws, the movable ends of the two hydraulic cylinders III305 are respectively fixedly connected to the two lifting columns 304 through screws, the upper portion of each lifting column 304 is respectively connected with the hydraulic cylinder IV306 through screws, and the telescopic ends of the two hydraulic cylinders IV306 are respectively fixed to the outer portions of the two T-shaped frames 307 through screws.

This example, as shown in fig. 8-9, can achieve the effect of facilitating the plurality of posts 302 on the two T-shaped brackets 307 to spread the fibers apart and spread them on the aluminum alloy sheet.

Two hydraulic cylinders III305 control two lifting columns 304 to move up and down in a telescopic mode, so that the upper and lower positions of two T-shaped frames 307 and a plurality of inserting columns 302 are controlled, the two hydraulic cylinders IV306 respectively control the two T-shaped frames 307 to slide back and forth on the upper portions of the two lifting columns 304 when extending and retracting, the front and rear positions of the two T-shaped frames 307 and the plurality of inserting columns 302 are further driven, and therefore the plurality of inserting columns 302 on the two T-shaped frames 307 can pull fibers open and lay the fibers on an aluminum alloy plate conveniently.

The fiber combining device further comprises an arc-shaped piece 401, a side frame 402 and a handle 403, wherein the side frame 402 is arranged on the left direction of the supporting plate 201, the arc-shaped piece 401 is inserted at the upper part of the side frame 402 in a clearance fit mode, the handle 403 is welded at the left part of the arc-shaped piece 401, and the arc-shaped piece 401 can slide to the upper side of the supporting plate 201.

This example can achieve the effect of facilitating the placement of the fiber mass, as shown in fig. 10.

Before a plurality of inserting columns 302 on two T-shaped frames 307 are needed to pull the fibers apart, the arc-shaped sheet 401 is moved to the upper side of the supporting plate 201, then the fiber cluster is placed on the arc-shaped sheet 401, after the plurality of inserting columns 302 lift the fiber cluster on the arc-shaped sheet 401, the arc-shaped sheet 401 is manually moved leftwards through a handle 403, and then the placement of the fiber cluster is facilitated, and the fiber cluster is conveniently pulled apart.

Claims

1. The corrosion-resistant aluminum alloy coating material is characterized by comprising the following raw materials in parts by weight: 1-6 parts of epoxy resin, 10-20 parts of fiber, 10 parts of silicone-acrylic emulsion, 25-30 parts of butanetriol, 10-12 parts of titanium dioxide, 10-15 parts of flake mica powder, 10-20 parts of graphite powder, 1-18 parts of an accelerator, 5-8 parts of a thickening agent, 4-8 parts of a leveling agent, 4-6 parts of a dispersing agent, 2-6 parts of a defoaming agent, 2-4 parts of a preservative, 2-5 parts of a coupling agent and 5-20 parts of a toughening agent; and coating the aluminum alloy plate treated by the fiber combination device.

2. A corrosion-resistant aluminum alloy coating material as recited in claim 1, wherein: the fiber is nylon fiber yarn.

3. A corrosion-resistant aluminum alloy coating material as recited in claim 1, wherein: the fiber combining device comprises a slide bar (105) and a triangular cutter (107), wherein the triangular cutters (107) are fixed on the slide bar (105) from front to back.

4. A corrosion-resistant aluminum alloy coating material as recited in claim 3, wherein: the fiber combining device further comprises a rotating strip (103), a hydraulic cylinder I (104) and guide rods (106), the guide rods (106) are fixedly connected to the front end and the rear end of the rotating strip (103), the front end and the rear end of the sliding strip (105) are respectively connected to the two guide rods (106) in a sliding mode, the hydraulic cylinder I (104) is fixed to the rotating strip (103), and the movable end of the hydraulic cylinder I (104) is fixed to the sliding strip (105).

5. A corrosion-resistant aluminum alloy coating material as recited in claim 4, wherein: the fiber combining device further comprises a translation frame (101) and side shafts (102), the front end and the rear end of each rotating strip (103) are fixedly connected with the side shafts (102), the two side shafts (102) are respectively and rotatably connected to the front end and the rear end of the translation frame (101), a servo motor I is fixedly connected to the translation frame (101), and an output shaft of the servo motor I is fixed on one of the side shafts (102).

6. A corrosion-resistant aluminum alloy coating material as recited in claim 5, wherein: the fiber combining device further comprises rail rods (203) and side seats (205), the two side seats (205) are arranged on the left and right sides, the two rail rods (203) are fixedly connected between the two side seats (205), and the lower portion of the translation frame (101) is connected to the two rail rods (203) in the left and right directions in a sliding mode.

7. A corrosion-resistant aluminum alloy coating material as recited in claim 6, wherein: the fiber combination device further comprises a supporting plate (201), supporting strips (202) and inclined frames (206), the outer sides of the two side seats (205) are fixedly connected with the inclined frames (206), the supporting strips (202) are fixed between the upper portions of the two inclined frames (206), and the supporting plate (201) is fixed in the middle of the upper side of the supporting strips (202).

8. A corrosion-resistant aluminum alloy coating material as recited in claim 7, wherein: the fiber combining device further comprises a hydraulic cylinder II (207) and a right-angle clamp (208), the right-angle clamp (208) is connected to each of the left end and the right end of the support strip (202) in a sliding mode, the hydraulic cylinder II (207) is fixed to each of the left end and the right end of the support strip (202), and the telescopic ends of the two hydraulic cylinders II (207) are fixed to the outer sides of the two right-angle clamps (208) respectively.

9. A corrosion-resistant aluminum alloy coating material as recited in claim 8, wherein: the fiber combining device further comprises a screw rod (204), a servo motor II is fixedly connected to one side seat (205), the screw rod (204) is fixedly connected to an output shaft of the servo motor II, and the screw rod (204) is in threaded fit with the translation frame (101).

10. A corrosion-resistant aluminum alloy coating material as recited in claim 9, wherein: the fiber combination device further comprises inserting columns (302), chutes (303) and T-shaped frames (307), wherein the two T-shaped frames (307) are arranged front and back, a plurality of inserting columns (302) are arranged on the lower side of each T-shaped frame (307) from left to right, each inserting column (302) is provided with a chute (303) on the outer side, and the two T-shaped frames (307) are located above the supporting plate (201).