CN114505749A

CN114505749A - Robot for removing burrs of aluminum deep processing

Info

Publication number: CN114505749A
Application number: CN202210164721.0A
Authority: CN
Inventors: 罗海东; 卢健鸿; 彭明冲
Original assignee: Foshan Shunde Sanchi Intelligent Equipment Co ltd
Current assignee: Foshan Shunde Sanchi Intelligent Equipment Co ltd
Priority date: 2022-02-22
Filing date: 2022-02-22
Publication date: 2022-05-17

Abstract

The invention discloses an aluminum deep processing burr removing robot which comprises a machine table, at least two conveying lines, a clamp assembly and a polishing machine head, wherein the two conveying lines are slidably arranged on the machine table; the clamp assembly is arranged on the outer side of the conveying line in a lifting mode and used for clamping and fixing the aluminum material; two polishing heads are adopted, the two polishing heads are oppositely and slidably arranged on the machine table, and two conveying lines are arranged between the two polishing heads; during operation, the aluminium product is carried to the transfer chain, makes the both ends of aluminum product move towards two aircraft noses of polishing respectively, and the anchor clamps subassembly presss from both sides tight fixed and lift the aluminum product to the aluminum product, and the both ends of aluminum product are polished to the polisher head, accomplish the back of polishing, and the anchor clamps subassembly is placed the aluminum product on the transfer chain and is removed the fixed to the aluminum product, and the transfer chain sees off the aluminum product of accomplishing with processing, makes the efficiency of polishing obtain improving.

Description

Robot for removing burrs of aluminum deep processing

Technical Field

The invention relates to the technical field of aluminum product processing, in particular to a robot for removing burrs in aluminum product deep processing.

Background

After the aluminum product cutting is good, the incision department of aluminum product can remain there is the burr, in order not to influence the use, need polish aluminum product incision burr, generally polish aluminum product incision burr through the manual work now, need spend longer time.

Disclosure of Invention

The present invention is directed to solving at least one of the problems of the prior art. Therefore, the robot for removing the deep processing burrs of the aluminum material comprises a machine table, at least two conveying lines, a clamp assembly and a polishing machine head, wherein the two conveying lines are slidably arranged on the machine table; the clamp assembly is arranged on the outer side of the conveying line in a lifting mode and used for clamping and fixing the aluminum material; the two polishing machine heads are arranged on the machine table in a sliding mode, and the two conveying lines are arranged between the two polishing machine heads.

According to some embodiments of the invention, the clamp assembly comprises a back plate, a lifting connecting plate, a lifting cylinder and a clamping cylinder, the back plate is connected with the conveying line, a sliding rail is longitudinally arranged on the back plate, a sliding block is slidably arranged on the sliding rail, the sliding block is connected with the lifting plate, the lifting plate is rotatably connected with one end of the lifting connecting plate, and the other end of the lifting connecting plate is rotatably connected with the lifting cylinder; the clamping cylinder is horizontally fixed on the lifting plate, the clamping cylinder is connected with a clamping plate, the clamping plate is oppositely provided with a backup plate, and the backup plate is fixed on the lifting plate.

According to some embodiments of the invention, the lifting plate is provided with a rotary cylinder, the rotary cylinder is positioned at the side edge of the conveying line, and the rotary cylinder is connected with a lower pressing rod.

According to some embodiments of the invention, a fixed cylinder is mounted on the lifting plate, a fixed cone is mounted on the fixed cylinder, and a fixed sleeve is fitted on the fixed cone and fixed on the conveying line.

According to some embodiments of the invention, a discharging rack is mounted at the discharging end of the conveying line, a material pushing cylinder is mounted on the discharging rack, the material pushing cylinder is connected with a material pushing plate, and the material pushing plate moves back to the conveying line.

According to some embodiments of the invention, the polishing machine head comprises a sliding plate, a vertical seat and a polishing main shaft, wherein an X-axis moving assembly is mounted at the bottom of the sliding plate, the X-axis moving assembly is fixed on the machine table, a Y-axis moving assembly is mounted on the top surface of the sliding plate, the vertical seat is slidably mounted on the Y-axis moving assembly, a Z-axis moving mechanism is mounted on the vertical seat, a lifting seat is mounted on the Z-axis moving mechanism, and the polishing main shaft is fixedly mounted on the lifting seat.

According to some embodiments of the invention, the X-axis moving assembly comprises an X-axis sliding rail, an X-axis sliding block, an X-axis rack and an X-axis motor, the X-axis sliding rail is fixed on the top surface of the machine table, the X-axis sliding block is slidably mounted on the X-axis sliding rail, and the X-axis sliding block is fixed at the bottom of the sliding plate; the X-axis rack is fixed on the side face of the machine table, the X-axis rack is meshed with a driving gear, the driving gear is mounted on a driving shaft of the X-axis motor, and the X-axis motor is fixed on the sliding plate through a motor plate.

According to some embodiments of the invention, the Y-axis moving assembly comprises a Y-axis slide rail, a Y-axis slide block, a Y-axis screw and a Y-axis motor, the Y-axis slide rail is fixed on the top surface of the slide plate, the Y-axis slide block is slidably mounted on the Y-axis slide rail, and the Y-axis slide block is fixed at the bottom of the vertical seat; and a Y-axis nut seat is arranged on the Y-axis screw rod and connected with the vertical seat, and the Y-axis screw rod is connected with a driving shaft of the Y-axis motor.

According to some embodiments of the invention, the Z-axis moving mechanism comprises a Z-axis slide rail, a Z-axis slide block, a Z-axis screw rod and a Z-axis motor, the Z-axis slide rail is fixed on the front side surface of the vertical base, the Z-axis slide block is slidably mounted on the Z-axis slide rail, and the Z-axis slide block is fixed on the back side surface of the lifting base; and a Z-axis nut seat is arranged on the Z-axis screw rod and fixed on the back side surface of the lifting seat, and the Z-axis screw rod is connected with a driving shaft of the Z-axis motor.

According to some embodiments of the invention, the conveying line comprises a conveying frame and a conveying belt, wherein driven pulleys are respectively mounted at two ends of the conveying frame, the conveying belt is wound between the two driven pulleys, and a driving pulley is wound on the conveying belt and connected with a driving motor.

The invention has at least the following beneficial effects:

the aluminum product is carried to the transfer chain, makes the both ends of aluminum product towards two aircraft noses of polishing respectively, and the anchor clamps subassembly presss from both sides tight fixed and lift the aluminum product to the aluminum product, and the both ends of aluminum product are polished to the polisher head, accomplish the back of polishing, and the anchor clamps subassembly is placed the aluminum product on the transfer chain and is removed the fixed to the aluminum product, and the transfer chain sees off the aluminum product of accomplishing with processing, makes polishing efficiency obtain improving.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is an overall schematic diagram of an embodiment of the present invention;

FIG. 2 is a schematic view of a conveyor line and a clamp assembly according to an embodiment of the invention;

FIG. 3 is a perspective view of the conveyor line and clamp assembly in accordance with the exemplary embodiment of the present invention;

FIG. 4 is a side view of the conveyor line and clamp assembly of an embodiment of the present invention;

FIG. 5 is a schematic view of a clamp assembly according to an embodiment of the present invention;

FIG. 6 is a perspective view of a sander head according to an embodiment of the present invention;

FIG. 7 is a schematic front view of a sander head according to an embodiment of the present invention;

FIG. 8 is a schematic cross-sectional view of a grinder head in accordance with an embodiment of the present invention.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention and are not to be construed as limiting the present invention.

Referring to fig. 1 and 2, the robot for removing the deep-processing burrs of the aluminum material comprises a machine table 100, at least two conveying lines 200, a clamp assembly 300 and a polishing machine head 400, wherein the two conveying lines 200 are slidably arranged on the machine table 100; the clamp assembly 300 is arranged on the outer side of the conveying line 200 in a lifting mode, and the clamp assembly 300 is used for clamping and fixing the aluminum material; two grinding heads 400 are adopted, the two grinding heads 400 are oppositely and slidably arranged on the machine table 100, and two conveying lines 200 are arranged between the two grinding heads 400; during operation, the aluminum product is carried to transfer chain 200, makes the both ends of aluminum product respectively towards two aircraft nose 400 of polishing, and anchor clamps subassembly 300 presss from both sides tight fixed and the aluminum product of lifting to the aluminum product, and aircraft nose 400 of polishing polishes the both ends of aluminum product, accomplishes the back of polishing, and anchor clamps subassembly 300 places the aluminum product on transfer chain 200 and removes the fixed to the aluminum product, and transfer chain 200 sends out the aluminum product that the processing was accomplished, makes polishing efficiency obtain improving.

Referring to fig. 3 to 5, the clamp assembly 300 includes a back plate 310, a lifting plate 320, a lifting connecting plate 330, a lifting cylinder 340, and a clamping cylinder 350, the back plate 310 is connected to the conveyor line 200, a slide rail 360 is longitudinally mounted on the back plate 310, a slider 370 is slidably mounted on the slide rail 360, the slider 370 is connected to the lifting plate 320, the lifting plate 320 is rotatably connected to one end of the lifting connecting plate 330, the other end of the lifting connecting plate 330 is rotatably connected to the lifting cylinder 340, and when the lifting cylinder 340 pushes the lifting connecting plate 330, the lifting connecting plate 330 pulls the lifting plate 320 to move the lifting plate 320 downward along the slide rail 360; when the lifting plate moves upwards along the slide rail 360, the lifting cylinder 340 resets, so that the lifting connecting plate 330 is pulled by the lifting cylinder 340, and the lifting connecting plate 330 pushes the lifting plate 320 upwards.

The lifting plate 320 is horizontally fixed with a clamping cylinder 350, the clamping cylinder 350 is connected with a clamping plate 380, the clamping plate 380 is oppositely provided with a backup plate 390, the backup plate 390 is fixed on the lifting plate 320, the clamping cylinder 350 pulls the clamping plate 380, so that the clamping plate 380 moves towards the clamping plate direction, and the aluminum material is clamped and fixed.

A rotary cylinder 3100 is mounted on the lifting plate 320, the rotary cylinder 3100 is located on the side of the conveying line 200, a push-down rod 3110 is connected to the rotary cylinder 3100, and when the aluminum material is conveyed to the clamp assembly 300, the rotary cylinder 3100 rotates the push-down rod 3110 to the position above the aluminum material so that the aluminum material is pressed by the push-down rod 3110, and the stability of aluminum material fixing is further improved.

All be equipped with the nylon piece at splint 380, backup plate 390, holding down lever 3110, lifter plate 320 and the face of aluminum product contact, the protection aluminum product avoids the aluminum product to be by the fish tail.

The lifting plate 320 is provided with a fixed cylinder 3200, the fixed cylinder 3200 is provided with a fixed cone 3210, and the fixed cone 3210 is matched with a fixed sleeve 3300. The fixing sleeve 3300 is fixed on the conveying frame 210 of the conveying line 200, when the lifting plate 320 is lifted in place, the fixing cylinder 3200 pushes the fixing cone 3210, the fixing cone 3210 is inserted into the fixing sleeve 3300, and the position of the lifting plate 320 is fixed, so that the accuracy of the lifted position of the lifting plate 320 and the stability of the lifted position during processing are guaranteed; after the machining is completed, the fixing cylinder 3200 is divided so that the fixing cone 3210 is disengaged from the fixing sleeve 3300 and the lifting plate 320 is lowered.

Referring to fig. 3, a discharging rack 500 is installed at the discharging end of the conveying line 200, and the processed aluminum material enters the discharging rack 500; in order to facilitate discharging, the discharging frame 500 is provided with a material pushing cylinder 510, the material pushing cylinder 510 is connected with a material pushing plate 520, the material pushing plate 520 moves in the direction opposite to the conveying line 200, after the processed aluminum material falls to the discharging frame 500, the material pushing plate 520 pushes the aluminum material away from the conveying line 200, and the next processed aluminum material falls to the discharging frame 500 conveniently.

Referring to fig. 2 and 3, the conveyor line 200 includes a conveyor frame 210 and a conveyor belt 220, wherein two ends of the conveyor frame 210 are respectively provided with a driven pulley 230, the conveyor belt 220 is wound between the two driven pulleys 230, the conveyor belt 220 is further wound with a driving pulley 240, and the driving pulley 240 is connected with a driving motor 250.

In this embodiment, two conveying lines 200 are connected in series, a linkage rod is installed between the driving pulleys 240 of the two conveying lines 200, and the linkage rod is linked with the driving shaft of the driving motor 250.

Referring to fig. 6 to 8, the polisher head 400 includes a sliding plate 410, a vertical base 420, and a polishing spindle 430, wherein an X-axis moving assembly 440 is installed at the bottom of the sliding plate 410, the X-axis moving assembly 440 is fixed on the machine 100, a Y-axis moving assembly 450 is installed on the top surface of the sliding plate 410, the vertical base 420 is installed on the Y-axis moving assembly 450 in a sliding manner, a Z-axis moving mechanism 460 is installed on the vertical base 420, a lifting base 470 is installed on the Z-axis moving mechanism 460, and the polishing spindle 430 is fixedly installed on the lifting base 470, so that the polishing spindle 430 can adjust the position thereof through the X-axis moving assembly 440, the Y-axis moving assembly 450, and the Z-axis moving mechanism 460.

The X-axis moving assembly 440 includes an X-axis sliding rail 441, an X-axis sliding block 442, an X-axis rack 443, and an X-axis motor 444, wherein the X-axis sliding rail 441 is fixed on the top surface of the machine 100, the X-axis sliding block 442 is slidably mounted on the X-axis sliding rail 441, and the X-axis sliding block 442 is fixed at the bottom of the sliding plate 410; the X-axis gear 443 is fixed to a side surface of the machine table 100, the X-axis gear 443 is engaged with a driving gear 445, the driving gear 445 is mounted on a driving shaft of the X-axis motor 444, and the X-axis motor 444 is fixed to the sliding plate 410 through a motor plate 446.

In this embodiment, the conveyor line 200 is slidably mounted on an X-axis slide rail 441.

The Y-axis moving assembly 450 comprises a Y-axis slide rail 451, a Y-axis slide block 452, a Y-axis screw 453 and a Y-axis motor 454, wherein the Y-axis slide rail 451 is fixed on the top surface of the slide plate 410, the Y-axis slide block 452 is slidably mounted on the Y-axis slide rail 451, and the Y-axis slide block 452 is fixed at the bottom of the vertical base 420; the Y-axis screw 453 is provided with a Y-axis nut holder 455, the Y-axis nut holder 455 is connected to the vertical holder 420, and the Y-axis screw 453 is connected to a driving shaft of a Y-axis motor 454.

The Z-axis moving mechanism 460 comprises a Z-axis sliding rail 461, a Z-axis slider 462, a Z-axis screw 463 and a Z-axis motor 464, wherein the Z-axis sliding rail 461 is fixed on the front side surface of the vertical base 420, the Z-axis slider 462 is slidably mounted on the Z-axis sliding rail 461, and the Z-axis slider 462 is fixed on the back side surface of the lifting base 470; a Z-axis nut seat 465 is arranged on the Z-axis screw 463, the Z-axis nut seat 465 is fixed on the back side surface of the lifting seat 470, and the Z-axis screw 463 is connected with a driving shaft of the Z-axis motor 464.

The embodiments of the present invention have been described in detail with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, and various changes can be made within the knowledge of those skilled in the art without departing from the gist of the present invention.

Claims

1. The utility model provides an aluminum product deep-processing burr removes robot which characterized in that includes:

a machine table (100);

the conveying lines (200) are at least two, and the two conveying lines (200) are slidably arranged on the machine table (100);

the clamp assembly (300) is installed on the outer side of the conveying line (200) in a lifting mode, the clamp assembly (300) is used for clamping and fixing the aluminum material, and the clamp assembly (300) is installed on the outer side of the conveying line (200);

the two grinding machine heads (400) are arranged, the two grinding machine heads (400) are installed on the machine table (100) in a sliding mode in the opposite direction, and the two conveying lines (200) are arranged between the two grinding machine heads (400).

2. The aluminum material deep-processing deburring robot of claim 1, wherein the clamp assembly (300) comprises a back plate (310), a lifting plate (320), a lifting connecting plate (330), a lifting cylinder (340) and a clamping cylinder (350), the back plate (310) is connected with the conveying line (200), a sliding rail (360) is longitudinally arranged on the back plate (310), a sliding block (370) is slidably arranged on the sliding rail (360), the sliding block (370) is connected with the lifting plate (320), the lifting plate (320) is rotatably connected with one end of the lifting connecting plate (330), and the other end of the lifting connecting plate (330) is rotatably connected with the lifting cylinder (340); the clamping cylinder (350) is horizontally fixed on the lifting plate (320), the clamping cylinder (350) is connected with a clamping plate (380), a backup plate (390) is oppositely arranged on the clamping plate (380), and the backup plate (390) is fixed on the lifting plate (320).

3. The aluminum deep-processing burr removing robot is characterized in that a rotary cylinder (3100) is mounted on the lifting plate (320), the rotary cylinder (3100) is located on the side of the conveying line (200), and a lower pressing rod (3110) is connected to the rotary cylinder (3100).

4. The robot for removing the deep processing burrs of the aluminum product as claimed in claim 2, wherein a fixed cylinder (3200) is installed on the lifting plate (320), a fixed cone (3210) is installed on the fixed cylinder (3200), a fixed sleeve (3300) is fitted on the fixed cone (3210), and the fixed sleeve (3300) is fixed on the conveying line (200).

5. The robot for removing the deep-processing burrs of the aluminum material as claimed in claim 1, wherein a discharging frame (500) is mounted at a discharging end of the conveying line (200), a material pushing cylinder (510) is mounted on the discharging frame (500), a material pushing plate (520) is connected to the material pushing cylinder (510), and the material pushing plate (520) moves in a direction opposite to the conveying line (200).

6. The robot for removing the deep-processing burrs of the aluminum material as claimed in claim 1, wherein the conveying line (200) comprises a conveying frame (210) and a conveying belt (220), driven pulleys (230) are respectively mounted at two ends of the conveying frame (210), the conveying belt (220) is wound between the two driven pulleys (230), a driving pulley (240) is further wound on the conveying belt (220), and the driving pulley (240) is connected with a driving motor (250).

7. The robot for removing the deep-processing burrs of the aluminum material as set forth in claim 1, wherein the grinding head (400) comprises a sliding plate (410), a vertical seat (420) and a grinding spindle (430), an X-axis moving assembly (440) is mounted at the bottom of the sliding plate (410), the X-axis moving assembly (440) is fixed on the machine table (100), a Y-axis moving assembly (450) is mounted on the top surface of the sliding plate (410), the vertical seat (420) is slidably mounted on the Y-axis moving assembly (450), a Z-axis moving mechanism (460) is mounted on the vertical seat (420), a lifting seat (470) is mounted on the Z-axis moving mechanism (460), and the grinding spindle (430) is fixedly mounted on the lifting seat (470).

8. The robot for removing the deep-processing burrs of the aluminum material as claimed in claim 7, wherein the X-axis moving assembly (440) comprises an X-axis sliding rail (441), an X-axis sliding block (442), an X-axis rack (443), and an X-axis motor (444), the X-axis sliding rail (441) is fixed on the top surface of the machine platform (100), the X-axis sliding block (442) is slidably mounted on the X-axis sliding rail (441), and the X-axis sliding block (442) is fixed on the bottom of the sliding plate (410); the X-axis rack (443) is fixed on the side surface of the machine table (100), the X-axis rack (443) is meshed with a driving gear (445), the driving gear (445) is installed on a driving shaft of the X-axis motor (444), and the X-axis motor (444) is fixed on the sliding plate (410) through a motor plate (446).

9. The aluminum deep-processing deburring robot of claim 7, wherein the Y-axis moving assembly (450) comprises a Y-axis slide rail (451), a Y-axis slide block (452), a Y-axis screw (453) and a Y-axis motor (454), the Y-axis slide rail (451) is fixed on the top surface of the sliding plate (410), the Y-axis slide block (452) is slidably mounted on the Y-axis slide rail (451), and the Y-axis slide block (452) is fixed on the bottom of the vertical base (420); and a Y-axis nut seat (455) is arranged on the Y-axis screw (453), the Y-axis nut seat (455) is connected with the vertical seat (420), and the Y-axis screw (453) is connected with a driving shaft of the Y-axis motor (454).

10. The robot for removing the deep-processing burrs of the aluminum material as claimed in claim 7, wherein the Z-axis moving mechanism (460) comprises a Z-axis sliding rail (461), a Z-axis sliding block (462), a Z-axis screw (463) and a Z-axis motor (464), the Z-axis sliding rail (461) is fixed on the front side surface of the vertical base (420), the Z-axis sliding block (462) is slidably mounted on the Z-axis sliding rail (461), and the Z-axis sliding block (462) is fixed on the back side surface of the lifting base (470); and a Z-axis nut seat (465) is arranged on the Z-axis screw rod (463), the Z-axis nut seat (465) is fixed on the back side surface of the lifting seat (470), and the Z-axis screw rod (463) is connected with a driving shaft of the Z-axis motor (464).