CN211588137U - Copper mesh PTFE soft belt bearing flanging machine machining station - Google Patents
Copper mesh PTFE soft belt bearing flanging machine machining station Download PDFInfo
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- CN211588137U CN211588137U CN201921654502.0U CN201921654502U CN211588137U CN 211588137 U CN211588137 U CN 211588137U CN 201921654502 U CN201921654502 U CN 201921654502U CN 211588137 U CN211588137 U CN 211588137U
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Abstract
The utility model discloses a soft bearing flanging machine station of taking of copper mesh tetrafluoro, this flanging machine station include, the drive case, the top surface mosaic of drive case has the chassis, and the top surface movable mounting on chassis has the rotary disk, equidistant welding has four to press the material mould on the top surface of rotary disk. A copper mesh tetrafluoro soft area bearing flanger processing station, set up the transport pipe through one side at the guiding tube, and the both sides surface at the transport pipe sets up the extrusion frame, can upwards transport the storage at the inside raw materials of transport pipe, transport the raw materials to placing a section of thick bamboo, can automatic feeding, improve machining efficiency, the resource of using manpower sparingly simultaneously, the below through the top cap is close to the rear end position and sets up the transportation frame, and set up the power supply board in the inside of transportation frame, can transport the work piece automatically, realize the automation, convenient subsequent depositing, whole work efficiency is improved.
Description
Technical Field
The utility model relates to a flanger technical field, in particular to copper mesh tetrafluoro soft belt bearing flanger processing station.
Background
The copper mesh PTFE soft belt bearing flanging machine is a device for flanging a rolled copper mesh PTFE soft belt bearing, sequentially processes the copper mesh PTFE soft belt bearing through each station of the flanging machine, and folds the edge of the copper mesh PTFE soft belt bearing;
the current flanging machine station has certain drawback when using, (1), the material loading is loaded down with trivial details: when the existing flanging machine processing station is used, raw materials to be processed need to be manually placed in a die, the shapes of the raw materials need to be manually adjusted in the placing process, and then the raw materials can be placed on the die, and the process is mainly finished manually, so that certain human resources need to be consumed, and the overall processing progress is influenced; (2) and the material taking is inconvenient: because the existing flanging machine processing station needs workers to manually take materials and place the materials after processing raw materials, the process also needs manual work, and therefore the copper mesh PTFE soft belt bearing flanging machine processing station is provided.
SUMMERY OF THE UTILITY MODEL
The utility model discloses a main aim at provides a copper mesh tetrafluoro soft belt bearing flanger processing station can effectively solve the problem in the background art.
In order to achieve the above purpose, the utility model adopts the following technical scheme:
the utility model provides a soft area bearing flanger processing station of copper mesh tetrafluoro, this flanger processing station includes:
the outer surface of the top end of the driving box is embedded with a chassis, a rotating disc is movably mounted on the outer surface of the top end of the chassis, and four pressing molds are welded on the outer surface of the top end of the rotating disc at equal intervals;
the conveying frame is movably mounted on the outer surface of the bottom end of the top cover and close to the rear end, the conveying belt is sleeved on the outer surface of the conveying frame, the power supply board is arranged on the inner surface of the conveying belt, and copper side hooks are welded on two sides of the outer surface of the bottom end of the power supply board;
the guide pipe is welded on the outer surface of the rear end of the driving box and close to the top end, an arc pipe is welded on the outer surface of the bottom end of the guide pipe, a conveying pipe is welded at one end, away from the guide pipe, of the arc pipe, through grooves are formed in the outer surfaces of the two sides of the conveying pipe, and an extrusion frame is fixedly installed at the position, close to the through grooves, in the driving box through bolts;
the storage box is welded on the outer surface of the top end of the guide pipe, and the outer surface of the bottom end of the storage box is welded with the discharging hopper.
Preferably, the top surface of drive case is close to left side position welding and has four support columns, the top surface welding top cap of four support columns, and the top surface of top cap is close to left side position and has first cylinder through bolt fixed mounting, the top surface of top cap is close to front end position and has the second cylinder through bolt fixed mounting.
Preferably, the outer surfaces of the two sides of the conveyor belt are respectively provided with a sliding groove, the inner surface of each sliding groove is bonded with a copper sheet, the outer surface of the bottom end of the conveyor belt is bonded with a plurality of flexible electromagnetic coils at equal intervals, and the flexible electromagnetic coils are respectively connected with the copper sheets on the two sides through leads.
Preferably, the outer surface of the extrusion frame is sleeved with an extrusion belt, and the outer surface of the extrusion belt is bonded with anti-skid threads.
Preferably, a servo motor is fixedly mounted in the driving box close to the top end of the driving box through bolts, an output shaft is arranged in the center of the outer surface of the top end of the servo motor, and the output shaft penetrates through the chassis and is welded with the center of the rotating disc.
Preferably, a placing cylinder is arranged in the center of the outer surface of the top end of the material pressing mold, a butt joint hole is formed in the position, close to the right side, of the outer surface of the top end of the chassis, and the inner surface of the butt joint hole is welded to the top end of the outer surface of the conveying pipe.
Preferably, a second extrusion rod is welded at the center of the outer surface of the bottom end of the first cylinder, and a first extrusion rod is welded at the center of the outer surface of the bottom end of the second cylinder.
Preferably, a chamfer is formed in the position, close to the bottom end, of the outer surface of the first extrusion rod, and a step is formed in the position, close to the bottom end, of the outer surface of the second extrusion rod.
Preferably, the inside of transportation frame is equipped with self-locking motor, two the inside of extrusion frame all through bolt fixed mounting with the self-locking motor.
Compared with the prior art, the utility model discloses following beneficial effect has:
1. the rotary disc is arranged at the top end of the driving box, so that workpieces can be driven to enter different stations, when the workpieces move to the first extrusion rod below the second air cylinder, the copper mesh PTFE soft belt bearing is extruded into a horn device, and then the copper mesh PTFE soft belt bearing is extruded and formed by the second extrusion rod below the first air cylinder;
2. the storage box is arranged on one side of the driving box, the inverted-triangular blanking funnel is arranged at the bottom end of the storage box, raw materials can be gathered, the width of the inner part of the blanking funnel is equal to the outer diameter of a workpiece, the raw materials can transversely enter the blanking funnel, and then the transverse raw materials are gathered into the guide pipe by the blanking funnel;
3. the conveying pipe is arranged on one side of the guide pipe, the extrusion frames are arranged on the outer surfaces of the two sides of the conveying pipe, raw materials stored in the conveying pipe can be conveyed upwards, the raw materials are conveyed into the placing barrel, automatic feeding can be achieved, machining efficiency is improved, and meanwhile, manpower resources are saved;
4. the conveying frame is arranged close to the rear end position below the top cover, the power supply plate is arranged inside the conveying frame, the flexible electromagnetic coil is electrified through the power supply plate during use, the flexible electromagnetic coil generates magnetism, a processed workpiece is attracted, then the power supply plate is moved to the rear end position of the conveying belt to be powered off along with the movement of the conveying belt, the workpiece is put down, the workpiece can be automatically conveyed, automation is realized, subsequent storage is facilitated, and the whole working efficiency is improved.
Drawings
FIG. 1 is an overall structure diagram of a flanging machine processing station of a PTFE soft belt bearing of the copper mesh of the utility model;
FIG. 2 is a structural diagram of a guiding tube, an arc tube and a conveying tube in a flanging machine processing station of a PTFE soft belt bearing of the copper mesh of the utility model;
FIG. 3 is a cross-sectional view of a guiding tube, an arc tube and a conveying tube in a flanging machine processing station of a PTFE soft belt bearing of the copper mesh of the present invention;
FIG. 4 is a structural diagram of a storage box and a discharging hopper in a flanging machine processing station of a PTFE soft belt bearing of the utility model;
FIG. 5 is a structural diagram of a rotating disc and a chassis in a processing station of a copper mesh PTFE soft belt bearing flanging machine of the utility model;
FIG. 6 is a cross-sectional view of a first extrusion rod in a flanging machine processing station of a PTFE soft belt bearing of the present invention;
FIG. 7 is a cross-sectional view of a second extrusion rod in a flanging machine processing station of a PTFE soft belt bearing of the present invention;
FIG. 8 is a cross-sectional view of a transportation frame in a flanging machine processing station of a PTFE soft belt bearing of the utility model;
FIG. 9 is a structural diagram of a power supply board in a flanging machine processing station of a PTFE soft belt bearing of the utility model;
FIG. 10 is a cross-sectional view of the conveyor belt in the flanging machine processing station of the PTFE soft belt bearing of the copper mesh of the present invention;
FIG. 11 is a structural diagram of the raw material in the flanging machine processing station of the PTFE soft belt bearing of the utility model;
fig. 12 is a structural diagram of the copper mesh tetrafluoro soft belt bearing flanging machine processing station after being processed by a second air cylinder;
figure 13 is the utility model relates to a structure diagram after first cylinder processing in the soft area bearing flanger processing station of copper mesh tetrafluoro.
In the figure: 1. a drive box; 2. rotating the disc; 3. pressing a mould; 4. a top cover; 5. a first cylinder; 6. A second cylinder; 7. a transport rack; 8. a storage box; 9. a guide tube; 10. an arc tube; 11. a delivery pipe; 12. an extrusion frame; 13. a discharging hopper; 14. placing the cylinder; 15. a chassis; 16. a butt joint hole; 17. a first extrusion stem; 18. a second extrusion stem; 19. a power supply board; 20. a copper side hook; 21. a conveyor belt; 22. a copper sheet; 23. a flexible electromagnetic coil.
Detailed Description
The present invention will be described in further detail with reference to the accompanying drawings.
In which like parts are designated by like reference numerals. It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "bottom" and "top," "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.
Referring to fig. 1-10, a copper mesh tetrafluoro soft belt bearing flanging machine processing station comprises:
a chassis 15 is embedded in the outer surface of the top end of the driving box 1, a rotating disc 2 is movably mounted on the outer surface of the top end of the chassis 15, and four pressing molds 3 are welded on the outer surface of the top end of the rotating disc 2 at equal intervals;
the conveying frame 7 is movably mounted at the position, close to the rear end, of the outer surface of the bottom end of the top cover 4, the conveying belt 21 is sleeved on the outer surface of the conveying frame 7, the power supply board 19 is arranged on the inner surface of the conveying belt 21, and copper side hooks 20 are welded at two sides of the outer surface of the bottom end of the power supply board 19;
the guide pipe 9 is welded on the outer surface of the rear end of the drive box 1 and close to the top end, the outer surface of the bottom end of the guide pipe 9 is welded with an arc pipe 10, one end, far away from the guide pipe 9, of the arc pipe 10 is welded with a conveying pipe 11, through grooves are formed in the outer surfaces of two sides of the conveying pipe 11, and an extrusion frame 12 is fixedly installed at the position, close to the through grooves, in the drive box 1 through bolts;
and the storage box 8 is welded on the outer surface of the top end of the guide pipe 9, and the outer surface of the bottom end of the storage box 8 is welded with a blanking funnel 13.
Referring to fig. 1, four support columns are welded on the outer surface of the top end of the driving box 1 near the left side, a top cover 4 is welded on the outer surface of the top end of the four support columns, a first cylinder 5 is fixedly mounted on the outer surface of the top end of the top cover 4 near the left side through bolts, and a second cylinder 6 is fixedly mounted on the outer surface of the top end of the top cover 4 near the front end.
Referring to fig. 10, sliding grooves are formed in the outer surfaces of the two sides of the conveyor belt 21, copper sheets 22 are bonded to the inner surfaces of the sliding grooves, a plurality of flexible electromagnetic coils 23 are bonded to the outer surface of the bottom end of the conveyor belt 21 at equal intervals, and the flexible electromagnetic coils 23 are connected with the copper sheets 22 on the two sides through conducting wires respectively.
Referring to fig. 3, the outer surface of the extrusion frame 12 is covered with an extrusion band, and the outer surface of the extrusion band is adhered with an anti-slip thread.
Referring to fig. 1, a servo motor is fixedly mounted in the driving box 1 near the top end through bolts, an output shaft is arranged in the center of the outer surface of the top end of the servo motor, and the output shaft penetrates through a chassis 15 and is welded with the center of a rotating disc 2.
Referring to fig. 5, a placing tube 14 is disposed at the center of the outer surface of the top end of the pressing mold 3, a butt joint hole 16 is disposed at a position on the outer surface of the top end of the base plate 15 near the right side, and the inner surface of the butt joint hole 16 is welded to the top end of the outer surface of the conveying tube 11.
Referring to fig. 6-7, a second extrusion rod 18 is welded to the center of the outer surface of the bottom end of the first cylinder 5, and a first extrusion rod 17 is welded to the center of the outer surface of the bottom end of the second cylinder 6.
Referring to fig. 6-7, the outer surface of the first extrusion rod 17 is chamfered near the bottom end, and the outer surface of the second extrusion rod 18 is stepped near the bottom end.
Referring to fig. 1, the inside of the transportation frame 7 is provided with a self-locking motor, the insides of the two extrusion frames 12 are respectively provided with a self-locking motor through bolts, the inside of the power supply board 19 is provided with a lithium battery, the positive pole of the lithium battery is connected with the left copper side hook 20, and the negative pole of the lithium battery is connected with the right copper side hook 20.
When in use, the raw material as shown in figure 11 is firstly put into the storage box 8 and then enters the blanking funnel 13 at the bottom end of the storage box 8, because the width of the inner part of the blanking funnel 13 is equal to the outer diameter of a workpiece, the raw material can transversely enter the blanking funnel 13, then the blanking funnel 13 is inverted into a triangular shape, the transverse raw material is converged into the guide tube 9, the far raw material falls into the guide tube 9 and enters the arc tube 10 through the self gravity and moves to the other end of the arc tube 10, because the two sides of the conveying pipe 11 are both provided with through grooves, the position of the inner part of the driving box 1, which is close to the through grooves, is provided with the extrusion frame 12, the self-locking motor drives the extrusion frame 12 to rotate, the raw material in the conveying pipe 11 is extruded, meanwhile, the raw material is upwards conveyed to the top end of the conveying pipe 11, and because the top end of the conveying pipe 11 is connected with the butt joint, when the barrel 14 is placed at the top end of the material pressing mold 3 and the material pressing mold moves right above the butt joint hole 16, the extrusion frame 12 rotates to push the raw material upwards, so that the raw material enters the barrel 14, and then the rotating disk 2 is driven to rotate through the servo motor.
When the material is rotated to the lower part of the second cylinder 6, the second cylinder 6 is controlled to drive the first extrusion rod 17 to extend and be inserted into the material, the shape of the material is extruded to be the shape shown in fig. 12, then the servo motor drives the rotating disk 2 to rotate, and when the material is rotated to the lower part of the first cylinder 5, the first cylinder 5 is controlled to drive the second extrusion rod 18 at the bottom end to extend and be inserted into the material, the material is extruded, and the material shown in fig. 12 is extruded to be the shape shown in fig. 13.
When the fashioned copper mesh tetrafluoro soft belt bearing arrives the below of conveyer belt 21, the inside copper side hook 20 of power supply board 19 both sides, respectively in the inside lithium cell connection of power supply board 19, because copper side hook 20 inserts in the spout of conveyer belt 21 both sides, consequently when conveyer belt 21 moves the position that has copper side hook 20, make the flexible solenoid 23 that is located this position circular telegram, produce magnetism, the copper mesh tetrafluoro soft belt bearing that can the shaping attracts, adsorb the surface of conveyer belt 21, when moving to the position that does not have copper side hook 20, can't supply power to flexible solenoid 23, fashioned copper mesh tetrafluoro soft belt bearing drops under the effect of gravity, can transport the work piece automatically, realize automaticly, convenient subsequent depositing, improve holistic work efficiency.
The basic principles and the main features of the invention and the advantages of the invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.
Claims (9)
1. The utility model provides a soft bearing flanging machine station of copper mesh tetrafluoro which characterized in that, this flanging machine station includes:
the device comprises a driving box (1), wherein a chassis (15) is embedded in the outer surface of the top end of the driving box (1), a rotating disc (2) is movably mounted on the outer surface of the top end of the chassis (15), and four pressing molds (3) are welded on the outer surface of the top end of the rotating disc (2) at equal intervals;
the conveying frame (7) is movably mounted at the position, close to the rear end, of the outer surface of the bottom end of the top cover (4), a conveying belt (21) is sleeved on the outer surface of the conveying frame (7), a power supply plate (19) is arranged on the inner surface of the conveying belt (21), and copper side hooks (20) are welded at two sides of the outer surface of the bottom end of the power supply plate (19);
the guide pipe (9) is welded on the position, close to the top end, of the outer surface of the rear end of the driving box (1), the outer surface of the bottom end of the guide pipe (9) is welded with an arc-shaped pipe (10), one end, far away from the guide pipe (9), of the arc-shaped pipe (10) is welded with a conveying pipe (11), through grooves are formed in the outer surfaces of two sides of the conveying pipe (11), and an extrusion frame (12) is fixedly installed on the position, close to the through grooves, of the inside of the driving box (1);
the storage box (8) is welded on the outer surface of the top end of the guide pipe (9), and the outer surface of the bottom end of the storage box (8) is welded with the blanking funnel (13).
2. The copper mesh tetrafluoro soft belt bearing flanging machine processing station of claim 1 is characterized in that: the top surface of drive case (1) is close to left side position welding has four support columns, the top surface welding top cap (4) of four support columns, and the top surface of top cap (4) is close to left side position and has first cylinder (5) through bolt fixed mounting, the top surface of top cap (4) is close to front position and has second cylinder (6) through bolt fixed mounting.
3. The copper mesh tetrafluoro soft belt bearing flanging machine processing station of claim 1 is characterized in that: the outer surfaces of the two sides of the conveyor belt (21) are respectively provided with a sliding groove, the inner surface of each sliding groove is bonded with a copper sheet (22), the outer surface of the bottom end of the conveyor belt (21) is bonded with a plurality of flexible electromagnetic coils (23) at equal intervals, and the flexible electromagnetic coils (23) are respectively connected with the copper sheets (22) on the two sides through leads.
4. The copper mesh tetrafluoro soft belt bearing flanging machine processing station of claim 1 is characterized in that: the outer surface of the extrusion frame (12) is sleeved with an extrusion belt, and the outer surface of the extrusion belt is adhered with anti-skid threads.
5. The copper mesh tetrafluoro soft belt bearing flanging machine processing station of claim 1 is characterized in that: the servo motor is fixedly installed in the position, close to the top end, of the interior of the driving box (1) through bolts, an output shaft is arranged in the center of the outer surface of the top end of the servo motor, and the output shaft penetrates through the chassis (15) and is welded with the center of the rotating disc (2).
6. The copper mesh tetrafluoro soft belt bearing flanging machine processing station of claim 1 is characterized in that: a placing barrel (14) is arranged in the center of the outer surface of the top end of the material pressing mold (3), a butt joint hole (16) is formed in the position, close to the right side, of the outer surface of the top end of the chassis (15), and the inner surface of the butt joint hole (16) is welded to the top end of the outer surface of the conveying pipe (11).
7. The copper mesh tetrafluoro soft belt bearing flanging machine processing station of claim 2 is characterized in that: a second extrusion rod (18) is welded at the center of the outer surface of the bottom end of the first cylinder (5), and a first extrusion rod (17) is welded at the center of the outer surface of the bottom end of the second cylinder (6).
8. The copper mesh tetrafluoro soft belt bearing flanging machine processing station of claim 7 is characterized in that: the outer surface of the first extrusion rod (17) is provided with a chamfer at a position close to the bottom end, and the outer surface of the second extrusion rod (18) is provided with a step at a position close to the bottom end.
9. The copper mesh tetrafluoro soft belt bearing flanging machine processing station of claim 1 is characterized in that: the conveying frame is characterized in that a self-locking motor is arranged inside the conveying frame (7), and the self-locking motors are fixedly arranged inside the two extrusion frames (12) through bolts.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN201921654502.0U CN211588137U (en) | 2019-09-30 | 2019-09-30 | Copper mesh PTFE soft belt bearing flanging machine machining station |
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CN201921654502.0U CN211588137U (en) | 2019-09-30 | 2019-09-30 | Copper mesh PTFE soft belt bearing flanging machine machining station |
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CN211588137U true CN211588137U (en) | 2020-09-29 |
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CN201921654502.0U Active CN211588137U (en) | 2019-09-30 | 2019-09-30 | Copper mesh PTFE soft belt bearing flanging machine machining station |
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2019
- 2019-09-30 CN CN201921654502.0U patent/CN211588137U/en active Active
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