CN215799966U - Traveling crane for anodic oxidation production - Google Patents

Abstract

The utility model provides a traveling crane for anodic oxidation production, which comprises a bracket, a horizontal driving mechanism, a vertical driving mechanism, a carrier, a horizontal inner annular rail and a concentric outer annular rail, wherein the inner annular rail is arranged at the same height as the horizontal inner annular rail; horizontal drive mechanism and vertical actuating mechanism set up on the support, and the carrier setting can reciprocate through vertical actuating mechanism at vertical actuating mechanism downside, and on track and outer track including the support setting, drive the support through horizontal drive mechanism and do clockwise or anticlockwise rotation along inner track and outer track, the support is equipped with a gyro wheel in the one side of rotating the inboard, is equipped with two gyro wheels in the one side of rotating the outside, and the rotatable setting of gyro wheel is on the support. The utility model can simultaneously carry out the feeding and the blanking of the workpiece at the same position through the annular inner track and the annular outer track, and can increase the production efficiency of workers compared with the traditional production tank which is arranged linearly.

Description

Traveling crane for anodic oxidation production

Technical Field

The utility model relates to the field of anodic oxidation production, in particular to a travelling crane for anodic oxidation production.

Background

Anodic oxidation (anodic oxidation), is the electrochemical oxidation of metals or alloys. The process of forming an oxide film on an aluminum product (anode) by aluminum and its alloy under the action of corresponding electrolyte and specific process conditions and an external current. Anodization is generally referred to as sulfuric acid anodization if not specifically indicated.

In order to overcome the defects of the aluminum alloy in the aspects of surface hardness, wear resistance and the like, expand the application range and prolong the service life, the surface treatment technology is an indispensable ring in the use of the aluminum alloy, and the anodic oxidation technology is most widely and successfully applied.

The so-called anodic oxidation of aluminium is an electrolytic oxidation process in which the surface of aluminium and aluminium alloys is generally converted into an oxide film having protective, decorative and some other functional properties.

In the existing anodic oxidation production line, all production tanks are arranged in a straight line, and feeding is carried out at one end of the production line while discharging is carried out at the other end of the production line. If only one traveling crane is arranged, the production efficiency is very low; if a plurality of traveling cranes are arranged to grab and release the object carriers for placing workpieces back and forth between respective stations, frequent operation is required in the production process, and the system is complex.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems in the prior art, the utility model provides a travelling crane for anodic oxidation production, which comprises a bracket, a horizontal driving mechanism, a vertical driving mechanism, a carrier, an annular inner track and an annular outer track, wherein the annular inner track is arranged horizontally at the same height; horizontal drive mechanism and vertical actuating mechanism set up on the support, and the carrier setting can reciprocate through vertical actuating mechanism at vertical actuating mechanism downside, and on track and outer track including the support setting, drive the support through horizontal drive mechanism and do clockwise or anticlockwise rotation along inner track and outer track, the support is equipped with a gyro wheel in the one side of rotating the inboard, is equipped with two gyro wheels in the one side of rotating the outside, and the rotatable setting of gyro wheel is on the support.

Furthermore, the support is provided with a plurality of supports, and the supports are arranged on the inner rail and the outer rail according to a uniform rotating direction.

Furthermore, horizontal drive mechanism includes first motor, first speed reducer and first transmission shaft, and first motor transmission connects first speed reducer input, and first transmission shaft is connected in the transmission of first speed reducer output, and the gyro wheel is connected in the transmission of first transmission shaft, and first motor and first speed reducer setting are in the support.

Furthermore, the vertical driving mechanism comprises a second motor, a second speed reducer, a gear and a rack, the second motor is in transmission connection with the input end of the second speed reducer, the output end of the second speed reducer is in transmission connection with the gear, the gear is meshed with the rack, the rack is vertically and slidably arranged on the support, and the carrier is fixed at the lower end of the rack.

Furthermore, the object carrier comprises an object carrying frame and a plurality of object carrying hooks, the upper end of the object carrying frame is open, a plurality of water through holes are formed in the side wall, and the object carrying hooks are fixedly connected to the lower side of the object carrying frame.

The utility model can simultaneously carry out the feeding and the blanking of the workpiece at the same position through the annular inner track and the annular outer track, and can increase the production efficiency of workers compared with the traditional production tank which is arranged linearly.

The number of the supports can be multiple, so that each production process in the anodic oxidation can be simultaneously produced, and the next process can be waited to be vacated in the water washing pool after the process with faster production is completed, thereby realizing the flow line production and greatly increasing the production efficiency.

Drawings

FIG. 1 is a schematic view of example 1 of the present invention;

FIG. 2 is a schematic view of a horizontal driving mechanism in embodiment 1 of the present invention;

FIG. 3 is a schematic view of a vertical driving mechanism in embodiment 1 of the present invention;

figure 4 is a schematic view of a carrier in accordance with embodiment 1 of the present invention;

in the figure: 1. a support; 2. a carrier; 3. an inner rail; 4. an outer rail; 5. a roller; 6. a first motor; 7. a first speed reducer; 8. a first drive shaft; 9. a second speed reducer; 10. a gear; 11. a rack; 12. a carrying frame; 13. the object carrying hook.

Detailed Description

Example 1:

as shown in fig. 1, the traveling crane for anodic oxidation production of the present embodiment includes a support 1, a horizontal driving mechanism, a vertical driving mechanism, a carrier 2, an annular inner rail 3 disposed at the same height as the horizontal driving mechanism, and an annular outer rail 4 disposed concentrically.

Horizontal drive mechanism and vertical drive mechanism set up on support 1, and carrier 2 sets up at vertical drive mechanism downside, can reciprocate through vertical drive mechanism, and support 1 sets up including on track 3 and outer track 4, drives the support through horizontal drive mechanism and does clockwise or anticlockwise rotation along inner track and outer track.

One side of the bracket 1 at the inner side of rotation is provided with a roller 5, one side at the outer side of rotation is provided with two rollers 5, and the rollers 5 are rotatably arranged on the bracket 1. The roller arrangement structure with the inner roller and the outer roller is adopted, so that the linear speed characteristics of the annular inner track 3 are well adapted to the characteristics of low linear speed and high linear speed of the outer track 4.

As shown in fig. 2, specifically, the horizontal driving mechanism includes a first motor 6, a first speed reducer 7 and a first transmission shaft 8, the first motor 6 is connected to an input end of the first speed reducer 7 in a transmission manner, an output end of the first speed reducer 7 is connected to the first transmission shaft 8 in a transmission manner, the first transmission shaft 8 is connected to the roller 5 in a transmission manner, the roller 5 drives the support to move along the track, and the first motor 6 and the first speed reducer 7 are disposed in the support 1.

As shown in fig. 3, specifically, the vertical driving mechanism includes a second motor, a second speed reducer 9, a gear 10 and a rack 11, the second motor is connected to the input end of the second speed reducer 9 in a transmission manner, the output end of the second speed reducer 9 is connected to the gear 10 in a transmission manner, the gear 10 is engaged with the rack 11, the rack 11 is vertically slidably disposed on the support 1, and the carrier 2 is fixed to the lower end of the rack 11. Thereby drive gear 10 rotation through the second motor and drive rack 11 and slide from top to bottom, drive carrier 2 and slide from top to bottom then.

As shown in fig. 4, the object carrier is used for placing a workpiece, and preferably, the object carrier comprises an object carrying frame 12 and a plurality of object carrying hooks 13, wherein the upper end of the object carrying frame is open, a plurality of water through holes are arranged on the side wall, and the object carrying hooks are fixedly connected to the lower side of the object carrying frame. The small-sized workpiece can be prevented from being in the carrying frame 12, and the large-sized workpiece can be hung on the carrying hook 13.

When the device is used, the device is matched with a production tank for anodic oxidation production, such as an oil removal tank, an alkaline washing tank, a pickling tank, a chemical polishing tank, an oxidation tank, a dyeing tank and a washing tank, the production tank is arranged at the lower sides of an inner rail and an outer rail, the production tank is arranged along the rails, a workpiece to be electroplated is placed on a storage rack, the workpiece is driven to pass through a preset production tank according to an anodic oxidation process flow through a vertical driving mechanism and a horizontal driving mechanism to complete an anodic oxidation processing flow, the rail is annular, the workpiece to be electroplated can be driven to the same position for loading the workpiece to be electroplated, and the workpiece can be simultaneously loaded and unloaded at the position.

Preferably, the support 1 may be provided in plural, and arranged on the inner rail 3 and the outer rail 4 in a uniform rotation direction. Through setting up at a plurality of supports 1, make every production processes can produce simultaneously in anodic oxidation, and can wait that the next process vacates in the washing pond after producing faster process is accomplished, realize streamlined production, greatly increased production efficiency.

It should be noted that the above-mentioned embodiments are not intended to limit the scope of the present invention, and all equivalent modifications and substitutions based on the above-mentioned technical solutions are within the scope of the present invention as defined in the claims.

Claims (5)

1. A traveling crane for anodic oxidation production is characterized in that: comprises a bracket, a horizontal driving mechanism, a vertical driving mechanism, a carrier, an annular inner track and an annular outer track, wherein the annular inner track is arranged horizontally at the same height, and the annular outer track is arranged concentrically; horizontal drive mechanism and vertical actuating mechanism set up on the support, and the carrier setting can reciprocate through vertical actuating mechanism at vertical actuating mechanism downside, and on track and outer track including the support setting, drive the support through horizontal drive mechanism and do clockwise or anticlockwise rotation along inner track and outer track, the support is equipped with a gyro wheel in the one side of rotating the inboard, is equipped with two gyro wheels in the one side of rotating the outside, and the rotatable setting of gyro wheel is on the support.

2. The traveling crane for anodic oxidation production according to claim 1, characterized in that: the support is equipped with a plurality ofly, sets up on interior track and outer track according to unified rotation direction.

3. The traveling crane for anodic oxidation production according to claim 1, characterized in that: the horizontal driving mechanism comprises a first motor, a first speed reducer and a first transmission shaft, the first motor is in transmission connection with the input end of the first speed reducer, the output end of the first speed reducer is in transmission connection with the first transmission shaft, the first transmission shaft is in transmission connection with the roller, and the first motor and the first speed reducer are arranged in the support.

4. The traveling crane for anodic oxidation production according to claim 1, characterized in that: the vertical driving mechanism comprises a second motor, a second speed reducer, a gear and a rack, the second motor is in transmission connection with the input end of the second speed reducer, the output end of the second speed reducer is in transmission connection with the gear, the gear is meshed with the rack, the rack is vertically and slidably arranged on the support, and the carrier is fixed at the lower end of the rack.

5. The traveling crane for anodic oxidation production according to claim 1, characterized in that: the object carrying frame comprises an object carrying frame and a plurality of object carrying hooks, the upper end of the object carrying frame is open, a plurality of water through holes are formed in the side wall, and the object carrying hooks are fixedly connected to the lower side of the object carrying frame.

Images