CN219793150U - Anodic oxidation device for aluminum alloy profile - Google Patents

Abstract

The utility model relates to the technical field of anodic oxidation devices and discloses an anodic oxidation device for aluminum alloy profiles, which comprises a shell, wherein the center of the front end surface of the shell, the center of the rear end surface of the shell, the center of one side wall of the shell and the center of the other side wall of the shell are respectively provided with an observation window, the positions of the two sides of the center of the upper end surface of the shell, which are close to the rear, are symmetrically provided with first sliding grooves, the positions of the front end and the rear end of the interior of the two first sliding grooves are respectively and slidably connected with sliding blocks, the positions of the two first sliding grooves, which are close to the front end and the rear end, of the center of the upper end surface of the shell are symmetrically and fixedly connected with first motors, and the output ends of the two first motors respectively penetrate through the shell and are communicated with the interiors of the two first sliding grooves. According to the utility model, the two second motors drive the two first screw rods and the two second screw rods to rotate, and the four second clamping blocks move towards the center of the outer shell along the two second sliding grooves, so that the bottom of the aluminum alloy section is clamped and limited, and unstable clamping is prevented.

Description

Anodic oxidation device for aluminum alloy profile

Technical Field

The utility model relates to the technical field of anodic oxidation devices, in particular to an anodic oxidation device for aluminum alloy profiles.

Background

In the existing aluminum alloy profile, the overall wear resistance is increased by processing the aluminum alloy profile by an anodic oxidation device, the electrolyte is a conductive solution, and a plurality of positive ions and negative ions which want to be exchanged are arranged in the electrolyte, positive charges are applied to aluminum to form an anode, negative charges are applied to plates suspended in the electrolyte, current in the circuit causes the positive ions to be attracted to a negative plate, and the negative ions are gathered to a positive electrode (aluminum sheet) for processing the aluminum alloy profile.

Among the existing anodic oxidation devices, the mechanical arm is usually used to clamp the aluminum alloy profile to be placed in the electrolyte, or the clamping is performed through the clamping structure, but there is no limitation in the electrolyte, and the situation that the aluminum alloy profile is toppled over due to unstable clamping may exist, so the skilled person provides an anodic oxidation device for the aluminum alloy profile to solve the problems in the prior art.

Disclosure of Invention

The utility model aims to solve the defects in the prior art, and provides an anodic oxidation device for an aluminum alloy section, wherein the aluminum alloy section is placed in electrolyte in a shell, and by starting two second motors, the two second motors drive two first screw rods and two second screw rods to rotate, and four second clamping blocks move towards the center of the shell along two second sliding grooves to clamp and limit the bottom of the aluminum alloy section, so that the aluminum alloy section is prevented from being inclined due to unstable clamping.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the anodic oxidation device for the aluminum alloy section comprises a shell, wherein the center of the front end surface of the shell, the center of the rear end surface of the shell, the center of one side wall of the shell and the center of the other side wall of the shell are respectively provided with an observation window, the positions of the two sides of the upper end surface of the shell, which are close to the rear, are symmetrically provided with first sliding grooves, the positions of the front end and the rear end of the inner part of each first sliding groove are respectively connected with a sliding block in a sliding manner, and the positions of the inner parts, which are close to the rear, of each first sliding groove are respectively provided with a limiting block;

the two ends of the first motor are respectively communicated with the inside of the two first sliding grooves through the shell, the end parts of the first motor are respectively fixedly connected with a third screw rod, the rear ends of the two third screw rods are respectively communicated with the rear ends of the two sliding blocks through the two sliding blocks at the front parts, the end parts of the first screw rods are respectively fixedly connected with a fourth screw rod, the rear ends of the two fourth screw rods are respectively communicated with the sliding blocks at the rear parts, the end parts of the fourth screw rods are respectively rotationally connected to the front end surfaces of the two limiting blocks, the centers of one side walls of the four sliding blocks are respectively fixedly connected with an electric telescopic rod, the output ends of the four electric telescopic rods are respectively fixedly connected with a first clamping block, and the centers of one side walls of the four first clamping blocks are respectively fixedly connected with anode contacts;

the two sides of the center of the lower inner wall of the shell are respectively provided with a second chute, second clamping blocks are symmetrically arranged at the positions close to the two sides in the second chute, a second motor is fixedly connected at the positions close to the lower front and rear sides in the center of one side wall of the shell, the output ends of the second motor penetrate through the shell respectively and are communicated with the inside of the two second chutes, the end parts of the second motor are fixedly connected with second screw rods, one end of each second screw rod penetrates through the two second clamping blocks close to one side and are communicated with the other side of the two second clamping blocks, the end parts of the second screw rods are fixedly connected with first screw rods, the other end parts of the two first screw rods penetrate through the two second clamping blocks close to the other side, and the end parts of the second screw rods are respectively and rotatably connected to the other inner side walls of the two second chutes;

through above-mentioned technical scheme, place aluminium alloy ex-trusions in the middle of the inside electrolyte of shell, through starting two second motors, two second motors drive two first lead screws and two second lead screws and rotate, four second clamp splice remove to shell central point put along two second spouts, carry out the centre gripping spacing to aluminium alloy ex-trusions bottom, prevent that the centre gripping is unstable, lead to aluminium alloy ex-trusions to empty.

Further, a control box is fixedly connected to the front part of the center of one side wall of the shell, and the control box is electrically connected with four electric telescopic rods, four anode contacts, two first motors and two second motors;

through above-mentioned technical scheme, conveniently carry out integrated control through the control box.

Further, cathode contacts are arranged at the positions, close to the centers of the side walls, of the four second clamping blocks;

through the technical scheme, the processing is convenient.

Further, the side walls of the four second clamping blocks and the four first clamping blocks are provided with anti-skid patterns;

through the technical scheme, the friction force between the aluminum alloy profile and the aluminum alloy profile is increased.

Further, the threads between the two first screw rods and the two second screw rods are oppositely arranged, and the threads between the two third screw rods and the two fourth screw rods are oppositely arranged;

through the technical scheme, the four sliding blocks and the four second clamping blocks can conveniently move towards the center at the same time.

Further, grooves are formed in the centers of one side wall of each of the two limiting blocks, limiting rods are arranged at the positions, close to the upper positions, of the rear ends of the two side walls of the shell, one ends of the two limiting rods penetrate through the two side walls of the shell and the two first sliding grooves in sequence and are communicated with the interiors of the two grooves;

through above-mentioned technical scheme, conveniently carry out spacingly, prevent to drop.

Further, the two first motors are synchronously controlled, the two second motors are synchronously controlled, and the four electric telescopic rods are synchronously controlled;

through above-mentioned technical scheme, conveniently make four sliders remove simultaneously, four first clamp splice remove simultaneously, four second clamp splice remove simultaneously.

Further, a liquid leakage hole is formed in the lower part of the center of the front end face of the shell, and a plug is arranged in the front part of the liquid leakage hole;

through the technical scheme, the electrolyte is convenient to replace.

The utility model has the following beneficial effects:

1. according to the utility model, the aluminum alloy section is placed in electrolyte in the shell by the anodic oxidation device for the aluminum alloy section, and the two second motors are started to drive the two first screw rods and the two second screw rods to rotate, and the four second clamping blocks move towards the center of the shell along the two second sliding grooves, so that the bottom of the aluminum alloy section is clamped and limited, and the aluminum alloy section is prevented from being inclined due to unstable clamping.

2. According to the utility model, by starting the two first motors, the two first motors drive the two third screw rods and the two fourth screw rods to rotate, the four sliding blocks are moved to the center of the shell along the two first sliding grooves, and the four electric telescopic rods are started to extend, so that the aluminum profiles are clamped, and aluminum profiles with different sizes are conveniently clamped.

3. According to the utility model, the reaction condition of the aluminum profile in the electrolyte is conveniently observed in an omnibearing manner through the four observation windows, and the inclination angle and the position of the aluminum profile in the electrolyte can be prevented, so that the aluminum profile is prevented from being toppled due to the fact that the four second clamping blocks are not clamped.

Drawings

FIG. 1 is a perspective view of an anodic oxidation apparatus for aluminum alloy profiles according to the present utility model;

FIG. 2 is a front cross-sectional view of an anodic oxidation apparatus for aluminum alloy profiles according to the present utility model;

FIG. 3 is a side sectional view of an anodic oxidation apparatus for aluminum alloy profiles according to the present utility model;

fig. 4 is an enlarged schematic view at a in fig. 2.

Legend description:

1. a housing; 2. an observation window; 3. a first motor; 4. a slide block; 5. a first chute; 6. an electric telescopic rod; 7. a first clamping block; 8. anti-skid lines; 9. a limiting block; 10. a limit rod; 11. a second motor; 12. a control box; 13. a second clamping block; 14. a first screw rod; 15. a cathode contact; 16. a second chute; 17. a second screw rod; 18. a groove; 19. a third screw rod; 20. a fourth screw rod; 21. an anode contact.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, one embodiment provided by the present utility model is: the utility model provides an anodic oxidation device for aluminum alloy section bar, including shell 1, when using, to the inside electrolyte that adds of shell 1, place aluminum alloy section bar in the middle of the electrolyte, shell 1 front end face center department, shell 1 rear end face center department, shell 1 side wall center department and shell 1 another lateral wall center department all are equipped with observation window 2, shell 1 up end center is close to the back both sides department symmetry and has been seted up first spout 5, both ends department all sliding connection has slider 4 around two first spouts 5 are inside, two first spouts 5 are inside all to be equipped with stopper 9 back.

The first motor 3 of symmetry fixedly connected with is located in both sides before shell 1 up end center, two first motor 3 output runs through shell 1 respectively and lets go of to inside two first spouts 5, and the equal fixedly connected with third lead screw 19 of tip, two third lead screw 19 rear ends run through two sliders 4 in front to two slider 4 rear ends respectively, and the equal fixedly connected with fourth lead screw 20 of tip, two fourth lead screw 20 rear ends run through two sliders 4 in back respectively, and the tip rotates respectively and connects on the terminal surface before two stopper 9, through starting two first motors 3, two first motors 3 drive two third lead screws 19 and two fourth lead screws 20 rotate, the equal fixedly connected with electric telescopic handle 6 in four slider 4 side wall centers, the equal fixedly connected with first clamp splice 7 of four electric telescopic handle 6 output, the equal fixedly connected with anode contact 21 in four first clamp splice 7 side wall centers, start four electric telescopic handle 6 and extend, carry out the centre gripping to the aluminium alloy, the aluminium alloy of convenient centre gripping different sizes.

The second sliding grooves 16 are formed in the front and rear sides of the center of the lower inner wall of the shell 1, the second clamping blocks 13 are symmetrically arranged at the positions, close to the two sides, of the inner wall of the shell 1, the second motors 11 are fixedly connected at the positions, close to the front and rear sides, of the center of one side wall of the shell 1, the output ends of the two second motors 11 penetrate through the shell 1 respectively and are communicated with the inner side of the two second sliding grooves 16, the second lead screws 17 are fixedly connected at the ends of the two second lead screws 17, one ends of the two second lead screws 17 penetrate through the two second clamping blocks 13 close to one side of the second clamping blocks 13 respectively and are communicated with the other side of the two second clamping blocks 13, the ends of the two second lead screws 17 are fixedly connected with the first lead screws 14 through starting the two second motors 11, the two first lead screws 14 and the two second lead screws 17 to rotate, the other ends of the two first lead screws 14 penetrate through the two second clamping blocks 13 close to the other side of the second clamping blocks, and the ends of the two second lead screws 16 are respectively connected to the other inner side walls of the two second sliding grooves 16, the two second lead screws 16 move towards the center of the shell 1, the bottom of the aluminum alloy profile is clamped and limited, and the aluminum alloy profile is prevented from being unstable.

The shell 1 side wall center is by preceding department fixedly connected with control box 12, electric connection between control box 12 and four electric telescopic handle 6, four positive pole contacts 21, two first motors 3 and two second motors 11, conveniently carry out integrated control through control box 12, four second clamp splice 13 side wall centers are all equipped with cathode contact 15 by the department, conveniently process, four second clamp splice 13 and four first clamp splice 7 lateral walls all are equipped with anti-skidding line 8, increase the frictional force with the aluminum alloy section bar, screw thread between two first lead screw 14 and two second lead screw 17 is the opposite setting, screw thread between two third lead screw 19 and two fourth lead screw 20 is the opposite setting, conveniently make four slider 4 and four second clamp splice 13 remove to central point simultaneously, recess 18 has all been seted up to two stopper 9 lateral wall centers department, shell 1 both sides wall rear end is by the department all being equipped with gag lever post 10, two gag lever post 10 one ends run through shell 1 both sides wall respectively in proper order and two first spout 5 are led to two recess 18 inside, increase the frictional force with aluminum alloy section bar, screw thread between two first lead screw 14 and two second lead screw 17 is the opposite setting, the screw thread between two fourth lead screw 11 and two fourth motor 5 is convenient for the synchronous, make the four slider 4 and four second clamp splice 13 move towards central point simultaneously, two positive side 13 leak hole synchronous hole is convenient, two first side 1, two positive side 1 side wall 5 is convenient to move, two first slider 5 is convenient, two positive side leak hole is convenient to move.

Working principle: when the aluminum alloy profile plug is used, electrolyte is added into the shell 1, aluminum alloy profiles are placed in the electrolyte, two second motors 11 are started through a control box 12, two second motors 11 drive two first screw rods 14 and two second screw rods 17 to rotate, four second clamping blocks 13 move towards the center of the shell 1 along two second sliding grooves 16, clamping limiting is carried out on the bottom of the aluminum alloy profiles, the aluminum alloy profiles are prevented from being unstable in clamping, the aluminum alloy profiles are prevented from toppling over, two first motors 3 are started, two first motors 3 drive two third screw rods 19 and two fourth screw rods 20 to rotate, four sliding blocks 4 move towards the center of the shell 1 along two first sliding grooves 5, four electric telescopic rods 6 are started to extend, aluminum profiles are clamped, aluminum profiles with different sizes are conveniently clamped, anodic oxidation treatment is started through the control box 12, the aluminum profiles are conveniently and comprehensively observed through four observation windows 2, when the electrolyte is required to be replaced, the electrolyte is opened, the shell is enabled to pass through a drain plug 1, and a new plug is added.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present utility model, and although the present utility model has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present utility model.

Claims (8)

1. Anodic oxidation device for aluminum alloy profile, including shell (1), its characterized in that: the novel sliding block type solar cell module is characterized in that the center of the front end face of the shell (1), the center of the rear end face of the shell (1), the center of one side wall of the shell (1) and the center of the other side wall of the shell (1) are respectively provided with an observation window (2), first sliding grooves (5) are symmetrically formed in the positions, close to the rear, of the center of the upper end face of the shell (1), the front end and the rear end of the inner part of each first sliding groove (5) are respectively connected with a sliding block (4) in a sliding manner, and limiting blocks (9) are respectively arranged in the positions, close to the rear, of the inner parts of the two first sliding grooves (5);

the two sides of the center of the upper end face of the shell (1) close to the front are symmetrically and fixedly connected with a first motor (3), the output ends of the two first motors (3) penetrate through the shell (1) respectively and are communicated to the inside of two first sliding grooves (5), the end parts of the two first motors are fixedly connected with a third screw rod (19), the rear ends of the two third screw rods (19) penetrate through two sliding blocks (4) close to the front respectively and are communicated to the rear ends of the two sliding blocks (4), the end parts of the two fourth screw rods (20) penetrate through two sliding blocks (4) close to the rear respectively, the end parts of the two fourth screw rods are respectively and rotatably connected to the front end faces of two limiting blocks (9), the centers of one side walls of the four sliding blocks (4) are fixedly connected with electric telescopic rods (6), the output ends of the four electric telescopic rods (6) are fixedly connected with first clamping blocks (7), and the centers of one side walls of the four first clamping blocks (7) are fixedly connected with anode contacts (21);

the utility model discloses a motor, including shell (1) and second slide groove (16), the both sides department all has been seted up around inner wall center under shell (1), two second slide groove (16) are inside to lean on both sides department to all symmetry to be equipped with second clamp splice (13), the both sides department all fixedly connected with second motor (11) around shell (1) side wall center is leaned on down, two second motor (11) output runs through shell (1) respectively and lets go into inside two second slide groove (16), and tip all fixedly connected with second lead screw (17), two second lead screw (17) one end runs through respectively and leans on two second clamp splice (13) opposite sides of one side department to lead to two second clamp splice (13), and tip all fixedly connected with first lead screw (14), two first lead screw (14) other end runs through respectively and leans on two second clamp splice (13) of opposite side, and the tip rotates respectively to be connected on another inside wall of two second slide grooves (16).

2. An anodic oxidation apparatus for aluminum alloy profiles according to claim 1, wherein: the electric telescopic device is characterized in that a control box (12) is fixedly connected to the front part of the center of one side wall of the shell (1), and the control box (12) is electrically connected with four electric telescopic rods (6), four anode contacts (21), two first motors (3) and two second motors (11).

3. An anodic oxidation apparatus for aluminum alloy profiles according to claim 1, wherein: cathode contacts (15) are arranged at the positions, close to the centers of the side walls, of the four second clamping blocks (13).

4. An anodic oxidation apparatus for aluminum alloy profiles according to claim 1, wherein: the side walls of the four second clamping blocks (13) and the four first clamping blocks (7) are respectively provided with anti-skid patterns (8).

5. An anodic oxidation apparatus for aluminum alloy profiles according to claim 1, wherein: threads between the two first screw rods (14) and the two second screw rods (17) are oppositely arranged, and threads between the two third screw rods (19) and the two fourth screw rods (20) are oppositely arranged.

6. An anodic oxidation apparatus for aluminum alloy profiles according to claim 1, wherein: the two limiting blocks (9) are respectively provided with a groove (18) at the center of one side wall, limiting rods (10) are respectively arranged at the positions, close to the upper positions, of the rear ends of the two side walls of the shell (1), one ends of the two limiting rods (10) respectively penetrate through the two side walls of the shell (1) and the two first sliding grooves (5) in sequence, and the two limiting rods are communicated to the insides of the two grooves (18).

7. An anodic oxidation apparatus for aluminum alloy profiles according to claim 1, wherein: the two first motors (3) are synchronously controlled, the two second motors (11) are synchronously controlled, and the four electric telescopic rods (6) are synchronously controlled.

8. An anodic oxidation apparatus for aluminum alloy profiles according to claim 1, wherein: the front end face of the shell (1) is provided with a liquid leakage hole at the lower part of the center, and a plug is arranged at the front part inside the liquid leakage hole.