CN117655763A - Guide rail dual-mode driving mechanism - Google Patents

Abstract

The invention provides a guide rail dual-mode driving mechanism. The quick-forward mechanism solves the problems that the drive mechanism is damaged easily due to quick-forward in the existing machining process and the precision of the follow-up working process is affected. The invention controls the fast forward and the working forward of the sliding block through the first driving mechanism and the second driving mechanism respectively, effectively reduces the abrasion caused by the fast forward and the reduction of the processing precision, and enables the first driving mechanism and the second driving mechanism to drive the sliding block through the clutch mechanism respectively, when one driving mechanism drives the sliding block to move, the other driving mechanism does not influence the movement of the sliding block.

Description

Guide rail dual-mode driving mechanism

Technical Field

The invention relates to the technical field of processing equipment, in particular to a guide rail dual-mode driving mechanism.

Background

In the machining process of a machine tool, a workpiece or a cutter is moved through a guide rail, two processes of fast forward and work in are usually needed, the workpiece or the cutter is moved fast through the fast forward, after the workpiece and the cutter are close to each other, a sliding block is converted into work in and is machined, the fast forward and the work in are usually carried out through a set of driving mechanism in the actual use process, the damage of the driving mechanism is easily caused in the fast forward process, the precision of the follow-up work in the follow-up work is influenced, the machining effect of the workpiece is further influenced, and the improvement exists in the prior art.

Disclosure of Invention

Aiming at the existing situation, the invention provides a guide rail dual-mode driving mechanism for respectively carrying out fast forward and working forward.

The invention aims at realizing the following technical scheme: the guide rail dual-mode driving mechanism comprises a slide block and a base, and is characterized in that a guide rail for moving in the length direction of the base is fixedly arranged on the base, the slide block is movably arranged on the base through the guide rail, a first driving mechanism for driving the slide block to fast forward along the length direction of the guide rail and a second driving mechanism for driving the slide block to fast forward along the length direction of the guide rail are respectively arranged on the base, and a clutch mechanism for enabling the first driving mechanism and the second driving mechanism to respectively drive the slide block to move is arranged on the slide block.

Preferably, a pressing plate extending along the length direction of the sliding block is fixedly arranged at the bottom of the sliding block, and the first driving mechanism and the second driving mechanism are respectively positioned at two sides of the pressing plate.

Preferably, the first driving mechanism comprises a screw rod rotatably arranged on the base, the screw rod is positioned below the sliding block and at one side of the pressing plate, and a pressing block which is attached to the pressing plate is movably arranged on the screw rod through threaded connection.

Preferably, the guide rail is a hydrostatic guide rail, the first driving mechanism comprises a pressing block which is positioned on one side of the pressing plate and is attached to the pressing plate, a first pull rope and a second pull rope are respectively fixedly arranged at two ends of the pressing block, a motor for driving the pressing block to move is fixedly arranged at one end, far away from the pressing block, of the first pull rope, a balancing weight is fixedly arranged at one end, far away from the pressing block, of the second pull rope, a roller is rotatably arranged on the base, the second pull rope is sleeved on the roller, and the roller and the pressing block are located on the same plane.

Preferably, the first driving mechanism comprises a synchronous belt movably arranged on the base, two ends of the base are respectively provided with a roller in a rotating mode, the synchronous belt is sleeved on the rollers, and the pressing block is fixedly arranged on the synchronous belt.

Preferably, the second driving mechanism comprises a screw rod rotatably arranged on the base, the screw rod is positioned below the sliding block and at one side of the pressing plate, and a pressing block which is attached to the pressing plate is movably arranged on the screw rod through threaded connection.

Preferably, the second driving mechanism comprises a pressing block which is positioned on one side of the pressing plate and is attached to the pressing plate, a first pull rope and a second pull rope are respectively fixedly arranged at two ends of the pressing block, a motor for driving the pressing block to move is fixedly arranged at one end, far away from the pressing block, of the first pull rope, one end, far away from the pressing block, of the first pull rope is fixedly arranged on a rotating shaft of the motor, a balancing weight is fixedly arranged at one end, far away from the pressing block, of the second pull rope, a roller is rotatably arranged on the base, and the second pull rope is sleeved on the roller, and the roller and the pressing block are located on the same plane.

Preferably, the second driving mechanism comprises a guide rod fixedly arranged on the base, a pull rod which is attached to the side wall of the pressing plate is sleeved on the guide rod, a cam which drives the pull rod to move is rotatably arranged on the base, one end of the pull rod, which faces the cam, is attached to the cam, a first pull rope is fixedly arranged at one end, which faces the cam, of the pull rod, a balancing weight is fixedly arranged at one end, which is far away from the pull rod, of the first pull rope, a roller is rotatably arranged on the base, the first pull rope is sleeved on the roller, and the roller and the pull rod are located on the same plane.

Preferably, the clutch mechanism comprises a first clutch component and a second clutch component which correspond to the first driving mechanism and the second driving mechanism respectively, the first clutch component and the second clutch component comprise supporting plates fixedly arranged at the bottom of the sliding block, the supporting plates are located at one side of the sliding block, a push rod extending towards the direction of the sliding block is fixedly arranged on the end face, facing the side of the sliding block, of the supporting plates, and one end, facing the sliding block, of the push rod is fixedly arranged on the sliding block.

Preferably, the clutch mechanism comprises a first clutch component and a second clutch component which correspond to the first driving mechanism and the second driving mechanism respectively, the second clutch component comprises a supporting plate fixedly arranged at the bottom of the sliding block, the supporting plate is located at one side of the sliding block, a push rod extending towards the direction of the sliding block is fixedly arranged on the end face of the supporting plate, facing the side of the sliding block, of the supporting plate, one end of the push rod, facing the sliding block, is fixedly arranged on the sliding block, the first driving mechanism is a joint robot, and the first clutch component corresponding to the first driving mechanism comprises a bolt fixedly arranged on the joint robot and a pin hole formed in the sliding block.

Compared with the prior art, the invention has the following beneficial effects: in the moving process of the workpiece or the cutter, the fast forward and the working forward of the sliding block are controlled through the first driving mechanism and the second driving mechanism respectively, so that abrasion caused by the fast forward and the reduction of machining precision are effectively reduced, the first driving mechanism and the second driving mechanism drive the sliding block respectively through the clutch mechanism, and when one driving mechanism drives the sliding block to move, the other driving mechanism does not influence the movement of the sliding block.

Drawings

FIG. 1 is an overall structural view of the present invention;

FIG. 2 is a schematic view of the structure under the slider;

FIG. 3 is an enlarged view of FIG. 2 at A;

FIG. 4 is a schematic diagram of a pull rope structure;

FIG. 5 is a schematic diagram of a timing belt structure;

fig. 6 is a schematic view of a cam structure.

The marks in the figure: 1. a slide block; 2. a base; 3. a guide rail; 4. a first driving mechanism; 5. a second driving mechanism; 6. a clutch mechanism; 7. a pressing plate; 8. a screw rod; 9. briquetting; 10. a first pull rope; 11. a second pull rope; 12. a motor; 13. balancing weight; 14. a roller; 15. a synchronous belt; 16. a roller; 17. a support plate; 18. a push rod; 19. a first clutch assembly; 20. a second clutch assembly; 21. a guide rod; 22. a pull rod; 23. a cam.

Detailed Description

The invention is further described below with reference to embodiments shown in the drawings in which:

example 1

The guide rail dual-mode driving mechanism comprises a sliding block 1 and a base 2, wherein a guide rail 3 for moving in the length direction of the base 2 is fixedly arranged on the base 2, the sliding block 1 is movably arranged on the base 2 through the guide rail 3, a first driving mechanism 4 for driving the sliding block 1 to fast advance in the length direction of the guide rail 3 and a second driving mechanism 5 for driving the sliding block 1 to fast advance in the length direction of the guide rail 3 are respectively arranged on the base 2, and a clutch mechanism 6 for enabling the first driving mechanism 4 and the second driving mechanism 5 to respectively drive the sliding block 1 to move is arranged on the sliding block 1. The bottom of the sliding block 1 is fixedly provided with a pressing plate 7 extending along the length direction of the sliding block 1, and the first driving mechanism 4 and the second driving mechanism 5 are respectively positioned at two sides of the pressing plate 7. In the moving process of the workpiece or the cutter, the fast forward and the working forward of the slide block 1 are controlled through the first driving mechanism 4 and the second driving mechanism 5 respectively, so that abrasion caused by the fast forward and the reduction of machining precision are effectively reduced, the first driving mechanism 4 and the second driving mechanism 5 respectively drive the slide block 1 through the clutch mechanism 6, and when one driving mechanism drives the slide block 1 to move, the other driving mechanism cannot influence the movement of the slide block 1.

The first driving mechanism 4 comprises a screw rod 8 rotatably arranged on the base 2, the screw rod 8 is positioned below the sliding block 1 and at one side of the pressing plate 7, and a pressing block 9 which is abutted against the pressing plate 7 is movably arranged on the screw rod 8 through threaded connection. The second driving mechanism 5 comprises a screw rod 8 rotatably arranged on the base 2, the screw rod 8 is positioned below the sliding block 1 and at one side of the pressing plate 7, and a pressing block 9 which is abutted against the pressing plate 7 is movably arranged on the screw rod 8 through threaded connection. The clutch mechanism 6 comprises a first clutch component 19 and a second clutch component 20 which correspond to the first driving mechanism 4 and the second driving mechanism 5 respectively, the first clutch component 19 and the second clutch component 20 respectively comprise a supporting plate 17 fixedly arranged at the bottom of the sliding block 1, the supporting plate 17 is positioned at one side of the sliding block 1, a push rod 18 extending towards the sliding block 1 is fixedly arranged on the end face of the supporting plate 17, facing the sliding block 1, of one side of the sliding block 1, and one end of the push rod 18 facing the sliding block 1 is fixedly arranged on the sliding block 1. Two pressing blocks 9 are driven to move through two screw rods 8 respectively, the pressing blocks 9 are driven to press against the pressing plate 7 through two push rods 18 respectively, the pressing blocks 9 drive the pressing plate 7 and the sliding block 1 to move, the second driving mechanism 5 for working is not affected when the first driving mechanism 4 for fast forward is worn, and stability of machining precision can be effectively guaranteed.

Example 2

The difference with embodiment 1 is that the second driving mechanism 5 includes a pressing block 9 located at one side of the pressing plate 7 and attached to the pressing plate 7, two ends of the pressing block 9 are respectively and fixedly provided with a first pull rope 10 and a second pull rope 11, one end of the first pull rope 10 far away from the pressing block 9 is fixedly provided with a motor 12 for driving the pressing block 9 to move, one end of the first pull rope 10 far away from the pressing block 9 is fixedly arranged on a rotating shaft of the motor 12, one end of the second pull rope 11 far away from the pressing block 9 is fixedly provided with a balancing weight 13, the base 2 is rotatably provided with a roller 14, the second pull rope 11 is sleeved on the roller 14, the roller 14 and the pressing block 9 are located on the same plane, and the first pull rope 10 and the second pull rope 11 are flexible pull ropes and are not deformed after being stretched.

Example 3

The difference with the embodiment 2 is that the guide rail 3 is a hydrostatic guide rail 3, the first driving mechanism 4 includes a pressing block 9 located at one side of the pressing plate 7 and attached to the pressing plate 7, two ends of the pressing block 9 are respectively and fixedly provided with a first pull rope 10 and a second pull rope 11, one end of the first pull rope 10 away from the pressing block 9 is fixedly provided with a motor 12 for driving the pressing block 9 to move, one end of the first pull rope 10 away from the pressing block 9 is fixedly arranged on a rotating shaft of the motor 12, one end of the second pull rope 11 away from the pressing block 9 is fixedly provided with a balancing weight 13, a roller 14 is rotatably arranged on the base 2, the second pull rope 11 is sleeved on the roller 14, and the roller 14 and the pressing block 9 are located on the same plane.

Example 4

The difference from embodiment 3 is that the second driving mechanism 5 includes a screw rod 8 rotatably disposed on the base 2, the screw rod 8 is disposed below the slide block 1 and on one side of the pressing plate 7, and a pressing block 9 abutting against the pressing plate 7 is movably disposed on the screw rod 8 through a screw connection.

Example 5

The difference from embodiment 3 is that the first driving mechanism 4 includes a synchronous belt 15 movably disposed on the base 2, two ends of the base 2 are respectively rotatably provided with a roller 16, the synchronous belt 15 is sleeved on the roller 16, and the pressing block 9 is fixedly disposed on the synchronous belt 15.

Example 6

The difference from the embodiment 5 is that the second driving mechanism 5 includes a screw rod 8 rotatably disposed on the base 2, the screw rod 8 is disposed below the slide block 1 and on one side of the pressing plate 7, and a pressing block 9 abutting against the pressing plate 7 is movably disposed on the screw rod 8 through a screw connection.

Example 7

The difference from embodiment 1 is that the clutch mechanism 6 includes a first clutch assembly 19 and a second clutch assembly 20 corresponding to the first driving mechanism 4 and the second driving mechanism 5, the second clutch assembly 20 includes a support plate 17 fixedly disposed at the bottom of the slider 1, the support plate 17 is located at one side of the slider 1, a push rod 18 extending toward the slider 1 is fixedly disposed on an end surface of the support plate 17 facing the side of the slider 1, one end of the push rod 18 facing the slider 1 is fixedly disposed on the slider 1, the first driving mechanism 4 is a joint robot, and the first clutch assembly 19 corresponding to the first driving mechanism 4 includes a pin fixedly disposed on the joint robot and a pin hole formed on the slider 1. When the sliding block 1 is driven to fast forward, a bolt on the joint robot is inserted into a pin hole on the sliding block 1, locking between the joint robot and the sliding block 1 is completed, and the fast forward of the sliding block 1 is realized through the movement of the closing robot.

Example 8

The difference with the embodiment 1 is that the second driving mechanism 5 includes a guiding rod 21 fixedly arranged on the base 2, a pull rod 22 abutting against the side wall of the pressing plate 7 is sleeved on the guiding rod 21, a cam 23 driving the pull rod 22 to move is rotatably arranged on the base 2, one end of the pull rod 22 facing the cam 23 abuts against the cam 23, one end of the pull rod 22 facing the cam 23 is fixedly provided with a first pull rope 10, one end of the first pull rope 10 far away from the pull rod 22 is fixedly provided with a balancing weight 13, a roller 14 is rotatably arranged on the base 2, the first pull rope 10 is sleeved on the roller 14, and the roller 14 and the pull rod 22 are located on the same plane.

The specific embodiments described herein are offered by way of example only to illustrate the spirit of the invention. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions thereof without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (10)

1. Guide rail bimodulus actuating mechanism, including slider (1) and base (2), its characterized in that, fixedly on base (2) be provided with guide rail (3) that base (2) length direction moved, slider (1) set up on base (2) through this guide rail (3) activity, be provided with first actuating mechanism (4) and actuating slider (1) that actuating slider (1) fast-forward along guide rail (3) length direction on base (2) respectively along guide rail (3) length direction second actuating mechanism (5), be provided with on slider (1) and make above-mentioned first actuating mechanism (4) and second actuating mechanism (5) drive respectively slider (1) carry out clutch mechanism (6) that move.

2. The guide rail dual-mode driving mechanism according to claim 1, wherein a pressing plate (7) extending along the length direction of the sliding block (1) is fixedly arranged at the bottom of the sliding block (1), and the first driving mechanism (4) and the second driving mechanism (5) are respectively positioned at two sides of the pressing plate (7).

3. A dual rail drive mechanism according to claim 2, characterized in that the first drive mechanism (4) comprises a screw (8) rotatably arranged on the base (2), which screw (8) is arranged below the slide (1) and on one side of the pressure plate (7), and that the screw (8) is movably provided with a pressure block (9) which is arranged by means of a threaded connection against the pressure plate (7).

4. The guide rail dual-mode driving mechanism according to claim 2, wherein the guide rail (3) is a hydrostatic guide rail (3), the first driving mechanism (4) comprises a pressing block (9) located at one side of the pressing plate (7) and attached to the pressing plate (7), two ends of the pressing block (9) are respectively fixedly provided with a first pull rope (10) and a second pull rope (11), one end of the first pull rope (10) away from the pressing block (9) is fixedly provided with a motor (12) for driving the pressing block (9) to move, one end of the first pull rope (10) away from the pressing block (9) is fixedly arranged on a rotating shaft of the motor (12), one end of the second pull rope (11) away from the pressing block (9) is fixedly provided with a balancing weight (13), the base (2) is rotatably provided with a roller (14), the second pull rope (11) is sleeved on the roller (14), and the roller (14) and the pressing block (9) are located on the same plane.

5. The guide rail dual-mode driving mechanism according to claim 2, wherein the first driving mechanism (4) comprises a synchronous belt (15) movably arranged on the base (2), two ends of the base (2) are respectively provided with a roller (16) in a rotating manner, the synchronous belt (15) is sleeved on the roller (16), and the pressing block (9) is fixedly arranged on the synchronous belt (15).

6. A dual-mode guide rail driving mechanism according to claim 2, wherein the second driving mechanism (5) comprises a screw (8) rotatably arranged on the base (2), the screw (8) is arranged below the slide block (1) and at one side of the pressing plate (7), and a pressing block (9) which is abutted against the pressing plate (7) is movably arranged on the screw (8) through a threaded connection.

7. The guide rail dual-mode driving mechanism according to claim 2, wherein the second driving mechanism (5) comprises a pressing block (9) located at one side of the pressing plate (7) and attached to the pressing plate (7), a first pull rope (10) and a second pull rope (11) are fixedly arranged at two ends of the pressing block (9) respectively, a motor (12) for driving the pressing block (9) to move is fixedly arranged at one end, far away from the pressing block (9), of the first pull rope (10), one end, far away from the pressing block (9), of the first pull rope (10) is fixedly arranged on a rotating shaft of the motor (12), a balancing weight (13) is fixedly arranged at one end, far away from the pressing block (9), of the second pull rope (11) is rotatably arranged on the base (2), the second pull rope (11) is sleeved on the rolling wheel (14), and the rolling wheel (14) and the pressing block (9) are located on the same plane.

8. The guide rail dual-mode driving mechanism according to claim 2, wherein the second driving mechanism (5) comprises a guide rod (21) fixedly arranged on the base (2), a pull rod (22) abutted against the side wall of the pressing plate (7) is sleeved on the guide rod (21), a cam (23) for driving the pull rod (22) to move is rotatably arranged on the base (2), one end of the pull rod (22) facing the cam (23) abuts against the cam (23), a first pull rope (10) is fixedly arranged at one end of the pull rod (22) facing the cam (23), a balancing weight (13) is fixedly arranged at one end of the first pull rope (10) far away from the pull rod (22), a roller (14) is rotatably arranged on the base (2), the first pull rope (10) is sleeved on the roller (14), and the roller (14) and the pull rod (22) are located on the same plane.

9. The guide rail dual-mode driving mechanism according to claim 3 or 4 or 5 or 6 or 7 or 8, wherein the clutch mechanism (6) comprises two supporting plates (17) fixedly arranged at the bottom of the sliding block (1), the two supporting plates (17) are positioned at two sides of the sliding block (1), a push rod (18) extending towards the sliding block (1) is fixedly arranged on the end face of the supporting plate (17) facing the sliding block (1), and one end of the push rod (18) facing the sliding block (1) is fixedly arranged on the sliding block (1).

10. The guide rail dual-mode driving mechanism according to claim 1, wherein the clutch mechanism (6) comprises a first clutch component (19) and a second clutch component (20) which correspond to the first driving mechanism (4) and the second driving mechanism (5) respectively, the second clutch component (20) comprises a supporting plate (17) fixedly arranged at the bottom of the sliding block (1), the supporting plate (17) is positioned at one side of the sliding block (1), a push rod (18) extending towards the direction of the sliding block (1) is fixedly arranged on the end face of the supporting plate (17) facing the sliding block (1), one end of the push rod (18) facing the sliding block (1) is fixedly arranged on the sliding block (1), the first driving mechanism (4) is an articulated robot, and the first clutch component (19) corresponding to the first driving mechanism (4) comprises a bolt fixedly arranged on the articulated robot and a pin hole formed on the sliding block (1).