CN220839264U - Numerical control machine tool motion debugging device - Google Patents

Abstract

The utility model relates to the technical field of motion debugging of a numerical control machine tool, in particular to a motion debugging device of a numerical control machine tool, which enables detection of materials to be more comprehensive and improves detection accuracy of the materials by arranging a corner mechanism; comprises a longitudinal displacement mechanism; the device also comprises a rotating mechanism, a transverse displacement mechanism, a corner mechanism, a driving mechanism and a locking mechanism, wherein the rotating mechanism is arranged at the upper end of the longitudinal displacement mechanism, the transverse displacement mechanism is arranged at the upper end of the longitudinal displacement mechanism, the corner mechanism is arranged at the upper end of the transverse displacement mechanism, the driving mechanism is arranged on the longitudinal displacement mechanism, and the locking mechanism is arranged on the corner mechanism; the longitudinal displacement mechanism moves longitudinally, the rotating mechanism detects materials, the transverse displacement mechanism moves transversely, the corner mechanism changes angles, the driving mechanism drives the transverse displacement mechanism, and the locking mechanism locks the corner mechanism.

Description

Numerical control machine tool motion debugging device

Technical Field

The utility model relates to the technical field of motion debugging of a numerical control machine tool, in particular to a motion debugging device of the numerical control machine tool.

Background

The debugging of the numerical control machine tool is that after one numerical control machine tool is transported to a factory, the normal production can be put into after the installation is qualified, so the installation, the debugging and the acceptance of the numerical control machine tool are important links in the earlier stage of the use of the machine tool, and are relatively important for the installation, the debugging and the acceptance of various machine tools.

In the existing numerical control machine tool movement debugging device, for example, the numerical control machine tool movement debugging device disclosed in the patent of the utility model with the application number 201921413347.3 is convenient to take down the dial indicator from the clamping seat, can prevent loosening when the dial indicator contacts with the revolving body, can move the movable seat along the groove, supports the movable seat through two supporting platforms, facilitates the adjustment of the position of the device, and enhances the detection precision of the debugged position.

But in the numerical control machine tool motion debugging process, the mechanism can only measure the precision of the circular motion of the chuck, and cannot perform fixed measurement on the end face of the chuck, so that measurement data are omitted, and measurement is inaccurate.

Disclosure of utility model

In order to solve the technical problems, the utility model provides the numerical control machine tool motion debugging device which enables the detection of materials to be more comprehensive and improves the detection accuracy of the materials by arranging the corner mechanism.

The utility model relates to a motion debugging device of a numerical control machine tool, which comprises a longitudinal displacement mechanism; the device also comprises a rotating mechanism, a transverse displacement mechanism, a corner mechanism, a driving mechanism and a locking mechanism, wherein the rotating mechanism is arranged at the upper end of the longitudinal displacement mechanism, the transverse displacement mechanism is arranged at the upper end of the longitudinal displacement mechanism, the corner mechanism is arranged at the upper end of the transverse displacement mechanism, the driving mechanism is arranged on the longitudinal displacement mechanism, and the locking mechanism is arranged on the corner mechanism;

The longitudinal displacement mechanism longitudinally moves, the rotating mechanism is used for detecting materials, the transverse displacement mechanism transversely moves, the corner mechanism changes angles, the driving mechanism drives the transverse displacement mechanism, and the locking mechanism locks the corner mechanism; the rotary mechanism is opened to enable the detection material to rotate, the driving mechanism is opened to enable the transverse displacement mechanism to conduct stable transverse movement, the longitudinal displacement mechanism is opened to enable equipment to be close to the rotary mechanism to conduct detection, the angle is changed after the rotary angle mechanism is rotated, then the rotary angle mechanism is locked by matching with the locking mechanism, and then the longitudinal displacement mechanism and the transverse displacement mechanism are moved to conduct detection on the end face of the rotary mechanism, so that detection of the material is more comprehensive, and detection accuracy of the material is improved.

Preferably, the longitudinal displacement mechanism comprises a base, a first rail, a rack, a sliding seat, a driven gear, a driving gear and a knob, wherein the first rail is arranged at the upper end of the base, the rack is arranged at the upper end of the base, the sliding seat is arranged at the upper end of the base in a sliding way through the first rail, the driven gear is rotatably arranged at the right end of the sliding seat and is meshed with the rack, the driving gear is rotatably arranged at the right end of the sliding seat and is meshed with the driven gear, and the knob is arranged at the right end of the driving gear; the driving gear is rotated by rotating the knob, the driven gear is meshed and driven while the driving gear is rotated, the driven gear is rotated, and the rack is meshed and driven while the driven gear is rotated, so that the sliding seat longitudinally moves on the first track.

Preferably, the rotating mechanism comprises a lathe and a chuck, the lathe is arranged at the upper end of the base, and the chuck is rotatably arranged at the right end of the lathe; the chuck is rotated by opening the lathe.

Preferably, the transverse displacement mechanism comprises a second rail, a stabilizing frame, a sliding frame and a hexagonal nut, wherein the second rail is arranged at the upper end of the sliding seat, the stabilizing frame is arranged at the upper end of the sliding seat, the sliding frame is matched with the second rail to be slidably arranged at the upper end of the sliding seat, and the sliding frame penetrates through the stabilizing frame to stabilize the sliding frame, and the hexagonal nut is arranged at the right end of the sliding frame; the carriage is more stable to move through the stabilizing frame.

Preferably, the corner mechanism comprises a rotating shaft, a rotating block and a dial indicator, wherein the rotating shaft is arranged at the upper end of the sliding frame, the rotating block is rotatably arranged on the rotating shaft, and the dial indicator is arranged on the rotating block; the dial indicator is subjected to angle change by rotating the rotating block, and measurement is performed by the dial indicator.

Preferably, the driving mechanism comprises a screw and a motor, the screw is rotatably arranged on the stabilizing frame and the sliding seat, the input end of the screw extends to the right side of the sliding seat, the screw is in threaded fit with the hexagonal nut, the motor is arranged at the right end of the sliding seat, and the output end of the motor is connected with the input end of the screw; the motor is turned on to drive the screw rod.

Preferably, the locking mechanism comprises two groups of first fixing columns, two groups of second fixing columns and two groups of locking rings, wherein the two groups of first fixing columns are arranged on the sliding frame, the two groups of second fixing columns are arranged on the rotating block, and each group of second fixing columns are rotatably provided with one group of locking rings; the first fixed column and the second fixed column are tightly sleeved through the locking ring, so that the rotating block is locked.

Compared with the prior art, the utility model has the beneficial effects that: the rotary mechanism is opened to enable the detection material to rotate, the driving mechanism is opened to enable the transverse displacement mechanism to conduct stable transverse movement, the longitudinal displacement mechanism is opened to enable equipment to be close to the rotary mechanism to conduct detection, the angle is changed after the rotary angle mechanism is rotated, then the rotary angle mechanism is locked by matching with the locking mechanism, and then the longitudinal displacement mechanism and the transverse displacement mechanism are moved to conduct detection on the end face of the rotary mechanism, so that detection of the material is more comprehensive, and detection accuracy of the material is improved.

Drawings

FIG. 1 is a schematic view of a first axial structure of the present utility model;

FIG. 2 is a schematic top view of the present utility model;

FIG. 3 is a right side view of the present utility model;

FIG. 4 is an enlarged schematic view of the corner mechanism of the present utility model in the axial direction of the portion A in FIG. 1;

FIG. 5 is a schematic view of the longitudinal displacement mechanism of the present utility model in a right-hand view of section B of FIG. 3;

FIG. 6 is a schematic view of a second axial structure of the present utility model;

The reference numerals in the drawings: 1. a longitudinal displacement mechanism; 11. a base; 12. track one; 13. a rack; 14. a slide; 15. a driven gear; 16. a drive gear; 17. a knob; 2. a rotation mechanism; 21. a lathe; 22. a chuck; 3. a lateral displacement mechanism; 31. a second track; 32. a stabilizing rack; 33. a carriage; 34. a hexagonal nut; 4. a corner mechanism; 41. a rotating shaft; 42. a rotating block; 43. a dial gauge; 5. a driving mechanism; 51. a screw rod; 52. a motor; 6. a locking mechanism; 61. fixing the first column; 62. fixing the second column; 63. a locking ring.

Detailed Description

In order that the utility model may be readily understood, a more complete description of the utility model will be rendered by reference to the appended drawings. This utility model may be embodied in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

The utility model relates to a motion debugging device of a numerical control machine tool, which comprises a longitudinal displacement mechanism 1; the device also comprises a rotating mechanism 2, a transverse displacement mechanism 3, a corner mechanism 4, a driving mechanism 5 and a locking mechanism 6, wherein the rotating mechanism 2 is arranged at the upper end of the longitudinal displacement mechanism 1, the transverse displacement mechanism 3 is arranged at the upper end of the longitudinal displacement mechanism 1, the corner mechanism 4 is arranged at the upper end of the transverse displacement mechanism 3, the driving mechanism 5 is arranged on the longitudinal displacement mechanism 1, and the locking mechanism 6 is arranged on the corner mechanism 4;

The longitudinal displacement mechanism 1 longitudinally moves, the rotating mechanism 2 is used for detecting materials, the transverse displacement mechanism 3 transversely moves, the corner mechanism 4 changes angles, the driving mechanism 5 drives the transverse displacement mechanism 3, and the locking mechanism 6 locks the corner mechanism 4; the longitudinal displacement mechanism 1 comprises a base 11, a first rail 12, a rack 13, a sliding seat 14, a driven gear 15, a driving gear 16 and a knob 17, wherein the first rail 12 is arranged at the upper end of the base 11, the rack 13 is arranged at the upper end of the base 11, the sliding seat 14 is slidably arranged at the upper end of the base 11 through the first rail 12, the driven gear 15 is rotatably arranged at the right end of the sliding seat 14, the driven gear 15 is meshed with the rack 13, the driving gear 16 is rotatably arranged at the right end of the sliding seat 14, the driving gear 16 is meshed with the driven gear 15, and the knob 17 is arranged at the right end of the driving gear 16; the rotating mechanism 2 comprises a lathe 21 and a chuck 22, wherein the lathe 21 is arranged at the upper end of the base 11, and the chuck 22 is rotatably arranged at the right end of the lathe 21; the transverse displacement mechanism 3 comprises a second rail 31, a stabilizing frame 32, a sliding frame 33 and a hexagonal nut 34, wherein the second rail 31 is arranged at the upper end of the sliding seat 14, the stabilizing frame 32 is arranged at the upper end of the sliding seat 14, the sliding frame 33 is matched with the second rail 31 to be slidably arranged at the upper end of the sliding seat 14, the sliding frame 33 penetrates through the stabilizing frame 32 to stabilize the sliding frame 33, and the hexagonal nut 34 is arranged at the right end of the sliding frame 33; the corner mechanism 4 comprises a rotating shaft 41, a rotating block 42 and a dial indicator 43, wherein the rotating shaft 41 is arranged at the upper end of the carriage 33, the rotating block 42 is rotatably arranged on the rotating shaft 41, and the dial indicator 43 is arranged on the rotating block 42; the driving mechanism 5 comprises a lead screw 51 and a motor 52, the lead screw 51 is rotatably arranged on the stabilizing frame 32 and the sliding seat 14, the input end of the lead screw 51 extends to the right side of the sliding seat 14, the lead screw 51 is in threaded fit with the hexagonal nut 34, the motor 52 is arranged at the right end of the sliding seat 14, and the output end of the motor 52 is connected with the input end of the lead screw 51; the locking mechanism 6 includes two sets of first fixing posts 61, two sets of second fixing posts 62, and two sets of locking rings 63, the two sets of first fixing posts 61 are mounted on the carriage 33, the two sets of second fixing posts 62 are mounted on the rotating block 42, and one set of locking rings 63 is rotatably mounted on each set of second fixing posts 62.

As shown in fig. 1 to 5, in the motion debugging device for a numerical control machine tool according to the present utility model, when the device is operated, the chuck 22 is rotated by opening the lathe 21, the screw 51 is driven by opening the motor 52, the screw 51 is screwed with the hexagonal nut 34, the carriage 33 is moved laterally, the carriage 33 is moved more stably by the stabilizer 32, the driving gear 16 is rotated by rotating the knob 17, the driven gear 15 is rotated while the driving gear 16 is rotated, the driven gear 15 is rotated while the driven gear 15 is rotated, the rack 13 is rotated while the driven gear 15 is engaged, thereby the slide 14 is longitudinally moved on the first rail 12, the dial gauge 43 is detected near the chuck 22, the dial gauge 43 is angularly changed by rotating the rotating block 42, then the fixed column one 61 and the fixed column two 62 are tightly sleeved by the locking ring 63, and then the slide 14 and the carriage 33 are moved to detect the end face of the chuck 22.

The motor 52 of the present utility model is commercially available and will be installed and operated by those skilled in the art in accordance with the instructions accompanying the same without the need for creative effort by those skilled in the art.

The main functions realized by the utility model are as follows: in the motion debugging process of the numerical control machine tool, the rotation angle mechanism is arranged, so that the detection of materials is more comprehensive, and the detection accuracy of the materials is improved.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that it will be apparent to those skilled in the art that modifications and variations can be made without departing from the technical principles of the present utility model, and these modifications and variations should also be regarded as the scope of the utility model.

Claims (7)

1. A numerical control machine tool motion debugging device comprises a longitudinal displacement mechanism (1); the device is characterized by further comprising a rotating mechanism (2), a transverse displacement mechanism (3), a corner mechanism (4), a driving mechanism (5) and a locking mechanism (6), wherein the rotating mechanism (2) is arranged at the upper end of the longitudinal displacement mechanism (1), the transverse displacement mechanism (3) is arranged at the upper end of the longitudinal displacement mechanism (1), the corner mechanism (4) is arranged at the upper end of the transverse displacement mechanism (3), the driving mechanism (5) is arranged on the longitudinal displacement mechanism (1), and the locking mechanism (6) is arranged on the corner mechanism (4);

The vertical displacement mechanism (1) moves longitudinally, the rotating mechanism (2) detects materials, the transverse displacement mechanism (3) moves transversely, the corner mechanism (4) changes angles, the driving mechanism (5) drives the transverse displacement mechanism (3), and the locking mechanism (6) locks the corner mechanism (4).

2. The numerical control machine tool motion debugging device according to claim 1, wherein the longitudinal displacement mechanism (1) comprises a base (11), a first rail (12), a rack (13), a slide seat (14), a driven gear (15), a driving gear (16) and a knob (17), the first rail (12) is installed at the upper end of the base (11), the rack (13) is installed at the upper end of the base (11), the slide seat (14) is slidably installed at the upper end of the base (11) through the first rail (12), the driven gear (15) is rotatably installed at the right end of the slide seat (14), the driven gear (15) is meshed with the rack (13), the driving gear (16) is rotatably installed at the right end of the slide seat (14), the driving gear (16) is meshed with the driven gear (15), and the knob (17) is installed at the right end of the driving gear (16).

3. A numerical control machine tool motion debugging device as claimed in claim 2, characterized in that the rotating mechanism (2) comprises a lathe (21) and a chuck (22), the lathe (21) is mounted at the upper end of the base (11), and the chuck (22) is rotatably mounted at the right end of the lathe (21).

4. The numerical control machine tool motion debugging device according to claim 2, wherein the transverse displacement mechanism (3) comprises a second rail (31), a stabilizing frame (32), a sliding frame (33) and a hexagonal nut (34), the second rail (31) is arranged at the upper end of the sliding seat (14), the stabilizing frame (32) is arranged at the upper end of the sliding seat (14), the sliding frame (33) is matched with the second rail (31) to be slidably arranged at the upper end of the sliding seat (14), the sliding frame (33) penetrates through the stabilizing frame (32) to enable the sliding frame to be stable, and the hexagonal nut (34) is arranged at the right end of the sliding frame (33).

5. The numerical control machine tool motion debugging device according to claim 4, wherein the rotation angle mechanism (4) comprises a rotation shaft (41), a rotation block (42) and a dial indicator (43), the rotation shaft (41) is arranged at the upper end of the sliding frame (33), the rotation block (42) is rotatably arranged on the rotation shaft (41), and the dial indicator (43) is arranged on the rotation block (42).

6. A machine tool motion debugging device according to claim 4, wherein the driving mechanism (5) comprises a screw (51) and a motor (52), the screw (51) is rotatably mounted on the stabilizing frame (32) and the slide (14), the input end of the screw (51) extends to the right side of the slide (14), the screw (51) is in threaded fit with the hexagonal nut (34), the motor (52) is mounted at the right end of the slide (14), and the output end of the motor (52) is connected with the input end of the screw (51).

7. The numerical control machine tool motion debugging device according to claim 5, wherein the locking mechanism (6) comprises two groups of first fixing columns (61), two groups of second fixing columns (62) and two groups of locking rings (63), the two groups of first fixing columns (61) are mounted on the sliding frame (33), the two groups of second fixing columns (62) are mounted on the rotating block (42), and one group of locking rings (63) are rotatably mounted on each group of second fixing columns (62).