CN107877015B - Chuck for full-automatic numerical control laser pipe cutting machine - Google Patents

Abstract

The invention relates to the field of laser pipe cutting machinery, and particularly discloses a chuck for a full-automatic numerical control laser pipe cutting machine. The chuck comprises two clamping plates, wherein a notch is formed in the rear end of one clamping plate, a first air cylinder and a rotary air cylinder are arranged between the two clamping plates, the output end of the first air cylinder is connected with a driving rack, a rear clamping plate is hinged to the driving rack, the rear clamping plate is fixedly connected with a guide column, the guide column penetrates through the rotary air cylinder, the driving rack and a driven rack are meshed through a common gear, and the driven rack is fixedly connected with the front clamping plate. By adopting the scheme, the full-automatic numerical control laser cutting machine has reasonable structural design, can help the full-automatic numerical control laser cutting machine to realize automatic feeding processing of pipes with various shapes such as rectangular pipes, round pipes, elliptical pipes, D-shaped pipes and the like, and is time-saving and labor-saving. And the pipe material feeding and the processing are synchronously carried out, so that the processing efficiency is high.

Description

Chuck for full-automatic numerical control laser pipe cutting machine

Technical Field

The invention relates to the field of laser pipe cutting machinery, in particular to a chuck for a full-automatic numerical control laser pipe cutting machine.

Background

At present, along with the continuous improvement of the optical fiber laser cutting technology, especially the rapid development of the pipe cutting industry, the laser processing brings convenience and benefit to the production and manufacturing industry, and the market demand for the laser pipe cutting machine is also increasing. Most of the laser pipe cutting equipment used in the actual production is manually fed by a single pipe or semi-automatically fed. Therefore, the applicant has invented a full-automatic numerical control laser pipe cutting machine, which can realize automatic feeding processing of rectangular pipes, round pipes, elliptical pipes, D-shaped pipes and other pipes with various shapes, and is time-saving and labor-saving. The pipe material feeding and processing are synchronously carried out, the processing efficiency is high, special chucks are required to be matched with the pipe material to realize the functions, but no such chucks exist at present.

Disclosure of Invention

The invention provides the chuck for the full-automatic numerical control laser pipe cutting machine, which can be applied to the full-automatic numerical control laser pipe cutting machine, saves time and labor, has high feeding speed and high efficiency, and overcomes the defects of the prior art.

The invention is realized by the following technical scheme:

The chuck for the full-automatic numerical control laser pipe cutting machine is characterized by comprising two clamping plates, wherein a notch is formed in the rear end of one clamping plate, a first cylinder and a rotary cylinder are arranged between the two clamping plates, the output end of the first cylinder is connected with a driving rack, the driving rack is hinged to a rear clamping plate, the rear clamping plate is fixedly connected with a guide post, the guide post penetrates through the rotary cylinder, the driving rack is meshed with a driven rack through a common gear, and the driven rack is fixedly connected with a front clamping plate.

The front clamping plate and the rear clamping plate are hollow structures.

The driving rack is hinged with the rear clamping plate through a driving connecting plate, the driving connecting plate is in sliding connection with the driving sliding rail, the driven rack is connected with the front clamping plate through a driven connecting plate, and the driven connecting plate is in sliding connection with the driven sliding rail.

The beneficial effects of the invention are as follows:

by adopting the scheme, the full-automatic numerical control laser cutting machine has reasonable structural design, can help the full-automatic numerical control laser cutting machine to realize automatic feeding processing of pipes with various shapes such as rectangular pipes, round pipes, elliptical pipes, D-shaped pipes and the like, and is time-saving and labor-saving. And the pipe material feeding and the processing are synchronously carried out, so that the processing efficiency is high.

Drawings

The invention is further described below with reference to the accompanying drawings:

FIG. 1 is a schematic view of the structure of the present invention in use;

FIG. 2 is a schematic diagram of a front view of a chuck;

FIG. 3 is a schematic top view of the chuck;

FIG. 4 is a schematic cross-sectional view of the structure of FIG. 3 in the direction C-C;

FIG. 5 is a schematic cross-sectional view of the structure of the D-D direction in FIG. 2;

Fig. 6 is a schematic cross-sectional structure in the direction E-E in fig. 2.

In the figure, a cylinder 216 is transmitted, a clamping plate 217, a notch 218, a cylinder 219 is first, a cylinder 220 is rotated, a guide post 221, a driving rack 222, a common gear 223, a driven rack 224, a front clamping plate 225, a rear clamping plate 226, a driving connecting plate 227, a driven connecting plate 228, a driving sliding rail 229 and a driven sliding rail 230.

Detailed Description

The drawings illustrate specific embodiments of the invention. As shown in fig. 1 to 6, the chuck for the full-automatic numerical control laser pipe cutting machine comprises two clamping plates 217, wherein the two clamping plates 217 are arranged in parallel left and right and are vertical, a notch 218 is formed in the rear end of one clamping plate 217, a first air cylinder 219 and a rotary air cylinder 220 are fixed on the clamping plate 217, the output end of the first air cylinder 219 is connected with a driving rack 222, the driving rack 222 is fixed on a driving connecting plate 227, a rear clamping plate 226 is hinged on the driving connecting plate 227, the driving connecting plate 227 is in sliding connection with a driving sliding rail 229, the driving sliding rail is fixed on the inner side of the clamping plate 217, the rear clamping plate 226 is perpendicular to the driving rack 222, the rear clamping plate 226 is fixedly connected with a guide column 221, the guide column 221 penetrates through the center of the rotary air cylinder 220, the cross section of the guide column 221 is elliptical or polygonal, the rotary air cylinder 220 can drive the guide column 221 to rotate, the rear clamping plate 226 can rotate into the notch 218, the driving rack 222 is meshed with a driven gear 224 through a common gear 223, the driven gear 224 is fixedly connected with the driven connecting plate 228, the upper end of the driven connecting plate 228 is fixedly connected with the front clamping plate 225, the front clamping plate 225 is perpendicular to the driven sliding rail 230, and the driven sliding rail 230 is fixedly connected with the driven sliding rail 230; when the transfer cylinder of the loading system is retracted, the front and rear clamping plates 225 and 226 are in an upright state, and when the transfer cylinder 216216 is extended, the front and rear clamping plates 225 and 226 are in a horizontal state. To reduce weight, the front 225 and rear 226 splints are hollow structures.

The working process is as follows: at first, the conveying cylinder 216 on the feeding system is in a retracted state, the front clamping plate 225 is in an upright state, the rear clamping plate 226 is turned into the notch 218 under the action of the rotary cylinder 220, after the pipe is conveyed forward to the front clamping plate 225, the rotary cylinder 220 is started to turn the rear clamping plate 226 into an upright state, the first cylinder 219 is started, the front clamping plate 225 and the rear clamping plate 226 move together to clamp the pipe, the synchronous conveying belt 209 is started to drive the sliding conveying table 214 to slide forward, the conveying cylinder is started to drive the clamping plate 217 to rotate, the front clamping plate 225 and the rear clamping plate 226 are in a horizontal state, that is to say, the rear clamping plate 226 is in an upper state, the front clamping plate 225 is arranged below, when the pipe reaches the upper side of the main machine body, the photoelectric sensor on the main body senses the pipe, the material supporting cylinder below the material supporting roller is driven to lift the material supporting roller, the first cylinder 219 is started again, the front clamping plate 225 and the rear clamping plate 226 are separated, the pipe is loosened, the synchronous conveying belt 209 drives the sliding conveying table 214 to withdraw, and the next pipe conveying action is ready.

The technical features are known to those skilled in the art except the technical features described in the specification.

Claims (1)

1. The chuck for the full-automatic numerical control laser pipe cutting machine is characterized by comprising two clamping plates (217), wherein a notch (218) is formed in the rear end of one clamping plate (217), a first air cylinder (219) and a rotary air cylinder (220) are arranged between the two clamping plates (217), the output end of the first air cylinder (219) is connected with a driving rack (222), a rear clamping plate (226) is hinged on the driving rack (222), the rear clamping plate is fixedly connected with a guide column (221), the guide column (221) penetrates through the rotary air cylinder (220), the driving rack (222) is meshed with a driven rack (224) through a common gear (223), and the driven rack (224) is fixedly connected with a front clamping plate (225); the front clamping plate (225) and the rear clamping plate (226) are hollow structures; the driving rack (222) is hinged with the rear clamping plate (226) through a driving connecting plate (227), the driving connecting plate (227) is in sliding connection with the driving sliding rail (229), the driven rack (224) is connected with the front clamping plate (225) through a driven connecting plate (228), and the driven connecting plate (228) is in sliding connection with the driven sliding rail (230).