CN116045870A - Full-automatic gauge block comparator - Google Patents

Abstract

The invention relates to the technical field of high-precision instruments and equipment, in particular to a full-automatic gauge block comparator, which has the technical scheme that: the measuring mechanism comprises a detection assembly and a displacement assembly, wherein the detection assembly comprises a detection bracket and a detection piece, the displacement assembly comprises a horizontal moving piece and a vertical lifting piece, the detection piece comprises a detection table arranged on the detection bracket, and the measuring mechanism further comprises a measuring sensor arranged at the bottom of the detection table and used for measuring the gauge block; the horizontal moving part comprises an X-axis moving part and a Y-axis moving part, the Y-axis moving part is arranged at the bottom of the X-axis moving part, the top of the vertical lifting part is provided with a detection plate for placing the gauge block, and the vertical lifting part comprises a lifter for driving the detection plate to lift. The gauge block measuring device has the technical effects of automatically measuring the gauge block, improving the detection precision and improving the detection speed.

Description

Full-automatic gauge block comparator

Technical Field

The invention relates to the technical field of high-precision instruments and equipment, in particular to a full-automatic gauge block comparator.

Background

The gauge block comparator is a metering instrument for comparing the length of the measuring gauge block. In precision displacement measurement, the measurement of the gauge block with the concentration of more than one percent is comparison measurement, and the measurement result is obtained by measuring the length differential of two measured pieces by adopting an Ubbelohde interferometer or other types of comparison measurement instruments, so that the method is widely applied to the field of measurement.

At present, a manual mode is adopted for detecting the gauge block, so that the gauge block is time-consuming and labor-consuming, an engineer is often required to detect a box of gauge block in a whole day, each data is required to be recorded manually, and a great amount of labor is required to be consumed and the detection time is prolonged for the conventional gauge block detector; meanwhile, the manual detection brings measurement instability; therefore, in order to improve the overall detection time and the measurement accuracy, the application discloses a full-automatic gauge block comparator.

Disclosure of Invention

In order to solve the technical problems, the invention provides a full-automatic gauge block comparator.

The technical scheme adopted for solving the technical problems is as follows:

the full-automatic gauge block comparator comprises a base and a measuring mechanism arranged on the base, wherein the measuring mechanism comprises a detecting component and a displacement component, the detecting component comprises a detecting bracket arranged on the base and a detecting piece arranged on the detecting bracket, the detecting piece is used for automatically measuring a gauge block, the displacement component comprises a horizontal moving piece and a vertical lifting piece, and the displacement component is used for driving the bottom of the detecting piece to which the gauge block automatically moves to complete automatic measurement;

the detection piece comprises a detection table arranged on the detection support and a measurement sensor arranged at the bottom of the detection table for measuring the gauge block;

the horizontal moving part comprises an X-axis moving part and a Y-axis moving part, the Y-axis moving part is arranged at the bottom of the X-axis moving part, and the moving direction of the X-axis moving part and the moving direction of the Y-axis moving part are mutually perpendicular;

the top of the vertical lifting piece is provided with a detection plate for placing the gauge block, and the vertical lifting piece comprises a lifter for driving the detection plate to lift.

Preferably, the Y-axis moving part comprises a Y-axis sliding rail arranged on the base, a translation plate is arranged on the Y-axis sliding rail, and the Y-axis moving part further comprises a Y-axis driver for driving the translation plate to move on the Y-axis sliding rail;

the X-axis moving part comprises an X-axis sliding rail arranged on the translation plate, a displacement frame plate is arranged on the X-axis sliding rail, and the X-axis moving part further comprises an X-axis driver for driving the displacement frame plate to move in a translation mode.

Preferably, the bottom of the translation plate is provided with a Y-axis sliding block which is arranged on the Y-axis sliding rail in a sliding way, and the bottom of the Y-axis sliding block is provided with a sliding groove which is clamped on the Y-axis sliding rail;

the Y-axis driver comprises a Y-axis motor arranged on the base and further comprises a driving shaft arranged on the Y-axis motor, a driving block is connected to the driving shaft in a threaded mode, a Y-axis connecting block connected with a Y-axis sliding block is arranged at the top of the driving block, and the Y-axis connecting block is connected with the driving block and the Y-axis sliding block through bolts.

Preferably, the X-axis moving part further comprises an X-axis sliding block arranged on the X-axis sliding rail, the X-axis driver comprises an X-axis motor arranged on the translation plate, a rotating shaft is arranged on the X-axis motor, the X-axis driver further comprises a displacement block, and the top of the displacement block and the top of the X-axis sliding block are in threaded connection with an X-axis connecting block.

Preferably, the displacement block is provided with a displacement hole for the rotating shaft to pass through, a displacement sleeve for being in threaded connection with the rotating shaft is arranged in the displacement hole, and the translation plate is also provided with a fixed block arranged at the end part of the rotating shaft.

Preferably, the lifter comprises a lifting bottom block arranged at the bottom of the displacement frame plate and a lifting top block arranged at the top of the displacement frame plate, wherein a lifting motor is arranged at the bottom of the lifting bottom block, lifting shafts penetrating through the lifting bottom block and the lifting top block are arranged on the lifting motor, and lifting holes for the lifting shafts to penetrate through are formed in the lifting bottom block and the lifting top block.

Preferably, the lifting bottom block is fixedly arranged on the X-axis moving piece, a fixed shaft lever is arranged on the lifting bottom block, and the top of the fixed shaft lever is connected with the lifting top block.

Preferably, the displacement frame plate is further provided with a positioning component for positioning the detection plate, the positioning component comprises a positioning block fixedly arranged on the displacement frame plate and a positioning rod arranged at the top of the positioning block, the detection plate is provided with a positioning hole for the positioning rod to penetrate through, the positioning hole is provided with a plurality of positioning holes, and the positioning rod comprises a reinforcing part arranged in the positioning block and a cylindrical part penetrating through the positioning hole.

Preferably, the vertical lifting piece further comprises a lifting piece arranged on the base, the lifting piece comprises a ceramic platform fixedly arranged on the base and a lifting block arranged on the ceramic platform, the top of the lifting block is provided with a bump used for abutting against the bottom of the block, and the bump is provided with a plurality of bumps.

Preferably, the detection table is set to be L-shaped, the measurement sensor is arranged at the bottom of the detection table and is downwards arranged, a lifting sliding rail used for driving the measurement sensor to vertically move is arranged in the detection table, an L-shaped sliding table is arranged on the lifting sliding rail in a sliding mode, and the measurement sensor is arranged on the L-shaped sliding table.

The invention has the beneficial effects that:

1. by arranging the horizontal moving part and the vertical lifting part, the gauge block on the detection plate is automatically moved to the bottom of the detection part, the detection sensor is utilized to automatically measure the gauge block, the X-axis moving part and the Y-axis moving part move horizontally, meanwhile, the vertical lifting piece enables the detection plate to move in the vertical direction, so that the gauge block automatically moves to a detection position, the lifting slide rail is driven to drive the measuring sensor to lift, automatic measurement is completed on the gauge block by utilizing the movement of the measuring sensor, and therefore accuracy of the measuring gauge block is improved, and detection efficiency is improved;

2. through setting up of locating component, carry out positioning process to the pick-up plate, improve the stability of pick-up plate at removal and testing process, and then make the detection accuracy obtain improving.

Drawings

FIG. 1 is a schematic overall structure of an embodiment of the present application;

FIG. 2 is a schematic cross-sectional view of an embodiment of the present application;

FIG. 3 is a schematic cross-sectional view illustrating a Y-axis moving member according to an embodiment of the present disclosure;

FIG. 4 is a schematic cross-sectional view of an embodiment of the present application for illustrating an X-axis moving member;

FIG. 5 is an enlarged view of a cross-sectional structure of a vertical lift member according to an embodiment of the present application;

FIG. 6 is a schematic view of a partial structure of a lifter according to an embodiment of the present disclosure;

fig. 7 is a schematic diagram of an internal structure of a test bench according to an embodiment of the application.

1, a base; 11. a translation plate; 12. a displacement frame plate; 3. a detection assembly; 31. detecting a bracket; 32. a detecting member; 321. a detection table; 322. a measuring sensor; 4. a displacement assembly; 41. a horizontal moving member; 42. a vertical lifting member; 51. an X-axis moving member; 52. an X-axis sliding rail; 53. an X-axis driver; 54. an X-axis sliding block; 55. an X-axis motor; 56. a rotating shaft; 57. a displacement block; 59. a displacement sleeve; 61. a Y-axis moving member; 62. a Y-axis sliding rail; 63. a Y-axis driver; 64. a Y-axis slider; 65. a chute; 66. a Y-axis motor; 67. a drive shaft; 68. a driving block; 69. a Y-axis connecting block; 7. a detection plate; 81. a lifter; 811. a lifting shaft; 812. lifting holes; 813. lifting the bottom block; 814. lifting the top block; 815. a lifting motor; 83. lifting the sliding rail; 84. an L-shaped sliding table; 9. a positioning assembly; 91. a positioning block; 92. a positioning rod; 93. positioning holes; 96. a jacking member; 97. a ceramic platform; 98. a jacking block; 99. and a bump.

Detailed Description

The present invention will be described in further detail with reference to the following examples, which are only for the purpose of illustrating the invention and are not to be construed as limiting the scope of the invention.

Examples:

referring to fig. 1, for the full-automatic gauge block comparator disclosed in the application, including base 1 and the measuring mechanism of setting on base 1, measuring mechanism includes detection subassembly 3 and displacement subassembly 4, and detection subassembly 3 is including setting up the detection support 31 on base 1, still including setting up the detecting element 32 on detection support 31, is equipped with the pick-up plate 7 that is used for placing the gauge block on the displacement subassembly 4, utilizes displacement subassembly 4 to drive pick-up plate 7 automatic movement to detection subassembly 3 below, utilizes detection subassembly 3 automatic completion to the automatic measurement of gauge block on the pick-up plate 7.

Referring to fig. 1 and 2, the displacement assembly 4 includes a horizontal moving member 41 and a vertical lifting member 42, the horizontal moving member 41 includes an X-axis moving member 51 and a Y-axis moving member 61, the Y-axis moving member 61 is disposed at the bottom of the X-axis moving member 51, and a driving direction of the X-axis moving member 51 and a driving direction of the Y-axis moving member 61 are disposed perpendicular to each other.

Referring to fig. 1 and 2, the Y-axis moving member 61 includes a Y-axis slide rail 62 and a Y-axis driver 63, a translation plate 11 is provided on the Y-axis slide rail 62, the Y-axis slide rail 62 is fixedly provided on the base 1, a Y-axis slide block 64 is slidably provided on the Y-axis slide rail 62, the Y-axis driver 63 includes a Y-axis motor 66 for driving the Y-axis slide block 64, and further includes a driving shaft 67 provided on the Y-axis motor 66, a driving block 68 is screwed on the driving shaft 67, a Y-axis connection block 69 connected with the Y-axis slide block 64 is provided on top of the driving block 68, and the Y-axis connection block 69 is connected with the Y-axis slide block 64 through a bolt. The driving block 68 is driven to move on the driving shaft 67 by the Y-axis motor 66, so that the Y-axis sliding block 64 driven by the driving block 68 moves on the Y-axis sliding rail 62, and further drives the translation plate 11 at the top to move. The bottom of the translation plate 11 is provided with a Y-axis sliding block 64 which is arranged on the Y-axis sliding rail 62 in a sliding way, and the bottom of the Y-axis sliding block 64 is provided with a sliding groove 65 which is clamped on the Y-axis sliding rail 62.

Referring to fig. 1 to 7, the X-axis moving member 51 includes an X-axis sliding rail 52 disposed on the translation plate 11, an X-axis sliding block 54 is disposed on the X-axis sliding rail 52, a displacement frame plate 12 is disposed on the X-axis sliding rail 52, and the X-axis moving member 51 further includes an X-axis driver 53, and the X-axis driver 53 drives the X-axis sliding block 54 to move, and since the top of the X-axis sliding block 54 is connected with the displacement frame plate 12, the X-axis sliding block 54 drives the displacement frame plate 12 to move in a synchronous translation. The X-axis driver 53 comprises an X-axis motor 55 arranged on the translation plate 11, a rotating shaft 56 is arranged on the X-axis motor 55, the X-axis driver 53 further comprises a displacement block 57, the top of the displacement block 57 and the top of the X-axis sliding block 54 are in threaded connection with an X-axis connecting block 58, the X-axis motor 55 drives the rotating shaft 56 to rotate, the rotating shaft 56 drives the displacement block 57 to move in a translational mode, the X-axis sliding block 54 is connected with the displacement block 57 through the X-axis connecting block 58, and therefore after the displacement block 57 moves in a translational mode, the top of the X-axis connecting block 58 drives the displacement frame plate 12 to move in a translational mode synchronously, and the detection plate 7 placed on the displacement frame plate 12 moves in a follow mode.

The top of the vertical lifting piece 42 is provided with a detection plate 7 for placing the gauge block, the vertical lifting piece 42 comprises a lifter 81 for driving the detection plate 7 to lift, the lifter 81 comprises a lifting bottom block 813 arranged at the bottom of the displacement frame plate 12 and a lifting top block 814 arranged at the top of the displacement frame plate 12, the lifting bottom block 813 is fixedly arranged on the X-axis moving piece 51, a fixed shaft rod is arranged on the lifting bottom block 813, the top of the fixed shaft rod is connected with the lifting top block 814, the bottom of the lifting bottom block 813 is provided with a lifting motor 815, the lifting motor 815 is provided with a lifting shaft 811 penetrating through the lifting bottom block 813 and the lifting top block 814, and lifting holes 812 for the lifting shaft 811 to penetrate are formed in the lifting bottom block 813 and the lifting top block 814. The lifting shaft 811 is driven by the lifting motor 815 to move up and down the displacement frame plate 12 held in the lifting bottom block 813 and the lifting top block 814, and further, the detection plate 7 on the top of the lifting displacement frame plate 12 is moved up and down. The displacement block 57 is provided with a displacement hole for the rotating shaft 56 to pass through, a displacement sleeve 59 for being connected with the rotating shaft 56 in a threaded manner is arranged in the displacement hole, and the translation plate 11 is also provided with a fixed block arranged at the end part of the rotating shaft 56. The lifter 81 is provided on the displacement frame plate 12, and the detection plate 7 is moved up and down by the lifting shaft 811.

Referring to fig. 1 to 7, a positioning component 9 for positioning the detection plate 7 is further arranged on the displacement frame plate 12, and stability and accuracy of detection are improved by using the positioning component 9; the positioning assembly 9 comprises a positioning block 91 fixedly arranged on the displacement frame plate 12, a positioning rod 92 is arranged at the top of the positioning block 91, and a plurality of positioning holes 93 for the positioning rod 92 to penetrate are formed in the detection plate 7; the positioning comprises a reinforcing part and a cylindrical part, the reinforcing part is arranged in the positioning block 91, the diameter of the reinforcing part is larger than that of the cylindrical part, and the cylindrical part is arranged in the positioning hole 93 in a penetrating mode.

The vertical lifting member 42 further comprises a lifting member 96 arranged on the base 1, and after the gauge block to be detected on the detection plate 7 is moved to the detection position by the horizontal moving member 41 and the vertical lifting member 42, the detection plate 7 is driven to move downwards by the vertical lifting member 42; the jacking piece 96 comprises a ceramic platform 97 fixedly arranged on the base 1, and further comprises a jacking block 98 arranged on the ceramic platform 97, wherein a plurality of protruding blocks 99 are arranged at the top of the jacking block 98, the top of each protruding block 99 is gradually abutted against the bottom of the corresponding block in the downward movement process of the corresponding detection plate 7, the corresponding block is separated from the corresponding detection plate 7 in the gradual descending process, and the detection piece 32 at the top is convenient for detecting the corresponding block.

Referring to fig. 1 to 5, the detecting member 32 includes a detecting stage 321 provided on the detecting bracket 31, and further includes a measuring sensor 322 provided at the bottom of the detecting stage 321 to measure the gauge block; the detection platform 321 is set to the L type, and measuring sensor 322 sets up in detection platform 321 bottom and downward setting, is equipped with the lift slide rail 83 that is used for driving measuring sensor 322 vertical movement in the detection platform 321, and the last slip of lift slide rail 83 is provided with L type slip table 84, and measuring sensor 322 sets up on L type slip table 84, utilizes measuring sensor 322 to carry out automatic measurement to the gauge block to with detection data transmission gives measuring terminal.

The above embodiments should not limit the present invention in any way, and all technical solutions obtained by equivalent substitution or equivalent conversion fall within the protection scope of the present invention.

Claims (10)

1. A full-automatic gauge block comparator is characterized in that: the measuring device comprises a base (1) and a measuring mechanism arranged on the base (1), wherein the measuring mechanism comprises a detecting component (3) and a displacement component (4), the detecting component (3) comprises a detecting support (31) arranged on the base (1), and further comprises a detecting piece (32) arranged on the detecting support (31), the detecting piece (32) is used for automatically measuring a gauge block, the displacement component (4) comprises a horizontal moving piece (41) and a vertical lifting piece (42), and the displacement component (4) is used for driving the bottom of the detecting piece (32) to which the gauge block automatically moves to complete automatic measurement;

the detecting piece (32) comprises a detecting table (321) arranged on the detecting bracket (31), and a measuring sensor (322) arranged at the bottom of the detecting table (321) for measuring the gauge block;

the horizontal moving part (41) comprises an X-axis moving part (51) and a Y-axis moving part (61), wherein the Y-axis moving part (61) is arranged at the bottom of the X-axis moving part (51), and the moving direction of the X-axis moving part (51) is perpendicular to the moving direction of the Y-axis moving part (61);

the top of the vertical lifting piece (42) is provided with a detection plate (7) for placing the gauge block, and the vertical lifting piece (42) comprises a lifter (81) for driving the detection plate (7) to lift.

2. The fully automatic proof mass comparator of claim 1, wherein: the Y-axis moving part (61) comprises a Y-axis sliding rail (62) arranged on the base (1), a translation plate (11) is arranged on the Y-axis sliding rail (62), and the Y-axis moving part (61) further comprises a Y-axis driver (63) for driving the translation plate (11) to move on the Y-axis sliding rail (62);

the X-axis moving part (51) comprises an X-axis sliding rail (52) arranged on the translation plate (11), a displacement frame plate (12) is arranged on the X-axis sliding rail (52), and the X-axis moving part (51) further comprises an X-axis driver (53) for driving the displacement frame plate (12) to move in a translation mode.

3. A fully automatic gauge block comparator according to claim 2, wherein: the bottom of the translation plate (11) is provided with a Y-axis sliding block (64) which is arranged on the Y-axis sliding rail (62) in a sliding way, and the bottom of the Y-axis sliding block (64) is provided with a sliding groove (65) which is clamped on the Y-axis sliding rail (62);

the Y-axis driver (63) comprises a Y-axis motor (66) arranged on the base (1), and further comprises a driving shaft (67) arranged on the Y-axis motor (66), wherein a driving block (68) is connected to the driving shaft (67) in a threaded mode, a Y-axis connecting block (69) connected with the Y-axis sliding block (64) is arranged at the top of the driving block (68), and the Y-axis connecting block (69) is connected with the driving block (68) and the Y-axis sliding block (64) through bolts.

4. A fully automatic mass comparator as claimed in claim 3, wherein: the X-axis moving part (51) further comprises an X-axis sliding block (54) arranged on the X-axis sliding rail (52), the X-axis driver (53) comprises an X-axis motor (55) arranged on the translation plate (11), a rotating shaft (56) is arranged on the X-axis motor (55), the X-axis driver (53) further comprises a displacement block (57), and the displacement block (57) and the top of the X-axis sliding block (54) are in threaded connection with an X-axis connecting block (58).

5. The fully automatic proof mass comparator of claim 4, wherein: the displacement block (57) is provided with a displacement hole for the rotating shaft (56) to pass through, a displacement sleeve (59) for being connected with the rotating shaft (56) in a threaded mode is arranged in the displacement hole, and the translation plate (11) is further provided with a fixed block arranged at the end portion of the rotating shaft (56).

6. A fully automatic gauge block comparator according to claim 2, wherein: the lifter (81) comprises a lifting bottom block (813) arranged at the bottom of the displacement frame plate (12), and further comprises a lifting top block (814) arranged at the top of the displacement frame plate (12), a lifting motor (815) is arranged at the bottom of the lifting bottom block (813), a lifting shaft (811) penetrating through the lifting bottom block (813) and the lifting top block (814) is arranged on the lifting motor (815), and lifting holes (812) for the lifting shaft (811) to penetrate are formed in the lifting bottom block (813) and the lifting top block (814).

7. The fully automatic proof mass comparator of claim 6, wherein: the lifting bottom block (813) is fixedly arranged on the X-axis moving piece (51), a fixed shaft lever is arranged on the lifting bottom block (813), and the top of the fixed shaft lever is connected with the lifting top block (814).

8. The fully automatic proof mass comparator of claim 6, wherein: the displacement frame plate (12) is also provided with a positioning assembly (9) for positioning the detection plate (7), the positioning assembly (9) comprises a positioning block (91) fixedly arranged on the displacement frame plate (12), and also comprises a positioning rod (92) arranged at the top of the positioning block (91), the detection plate (7) is provided with positioning holes (93) for the positioning rod (92) to penetrate through, and the positioning holes (93) are provided with a plurality of positioning holes;

the positioning rod (92) comprises a reinforcing part arranged in the positioning block (91) and a cylindrical part penetrating through the positioning hole (93).

9. The fully automatic proof mass comparator of claim 8, wherein: the vertical lifting piece (42) further comprises a lifting piece (96) arranged on the base (1), the lifting piece (96) comprises a ceramic platform (97) fixedly arranged on the base (1), the vertical lifting piece further comprises a lifting block (98) arranged on the ceramic platform (97), the top of the lifting block (98) is provided with a lug (99) used for abutting against the bottom of the block, and the lugs (99) are arranged in a plurality.

10. The fully automatic proof mass comparator of claim 1, wherein: the detection table (321) is set to be L-shaped, the measurement sensor (322) is arranged at the bottom of the detection table (321) and is downwards arranged, a lifting sliding rail (83) for driving the measurement sensor (322) to vertically move is arranged in the detection table (321), an L-shaped sliding table (84) is arranged on the lifting sliding rail (83) in a sliding mode, and the measurement sensor (322) is arranged on the L-shaped sliding table (84).

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