CN111854605A

CN111854605A - Test instrument based on cloud calculates

Info

Publication number: CN111854605A
Application number: CN202010739920.0A
Authority: CN
Inventors: 陈圆圆
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-07-28
Filing date: 2020-07-28
Publication date: 2020-10-30

Abstract

The invention relates to the technical field of workpiece dimension testing of an image type measuring instrument, in particular to a cloud computing-based testing instrument which comprises a base, wherein a scanning dimension table is fixed at the top end of the base, a driving overturning displacement adjusting structure is fixed on one side of the base, a supporting column is welded at the top end of one end of the base, and a cloud computer display screen is fixed at one end of the supporting column. According to the invention, through the design of the fine-tuning adaptive size measurement recording structure, the device is convenient to finish good measurement performance on the size of a workpiece through fine-tuning of the shooting distance and the light adaptability brought by the shooting filter adjusting structure, the test shooting definition and the focusing effect are more comprehensively ensured, so that the size qualification test can be conveniently finished by comparing cloud data, and through the design of the driving overturning displacement adjusting structure, the device is convenient to finish automatic adjustment on overturning and displacement of the test workpiece, so that the workpiece size can be conveniently obtained at multiple angles, and the use convenience is improved.

Description

Test instrument based on cloud calculates

Technical Field

The invention relates to the technical field of workpiece dimension testing of an image type measuring instrument, in particular to a testing instrument based on cloud computing.

Background

The image measuring instrument is a high-precision and high-tech measuring instrument widely applied to the industries of machinery, electronics, instruments, hardware, plastic and the like with the aim of two-coordinate measurement, integrates light, mechanical, electrical and computer image technologies, is usually convenient to input the size of a workpiece into a computer in advance after being matched with cloud data for use at present, and completes data comparison after scanning and measuring the workpiece to form the test of the size of the workpiece;

however, the fine setting that stretches out and draws back and the shooting filter that lacks and be applicable to different light in the position of shooing of current device leads to producing the camera lens polarisation easily and losing the focus in the whole use of device owing to shoot the position, leads to contrast size effect to have the deviation, and often be not convenient for drive the work piece in the use and overturn the regulation with multidirectional drive, leads to using convenient degree relatively poor.

SUMMARY OF THE PATENT FOR INVENTION

The invention aims to provide a test instrument based on cloud computing.

In order to achieve the purpose, the invention adopts the following technical scheme:

a test instrument based on cloud computing comprises a base, wherein a scanning size table is fixed at the top end of the base, a driving overturning displacement adjusting structure is fixed on one side of the base, a supporting column is welded at the top end of one end of the base, a cloud computer display screen is fixed at one end of the supporting column, a cloud computer main body is fixed inside the supporting column, the cloud computer main body is electrically connected with the cloud computer display screen, a fine-tuning adaptive size measurement recording structure is fixed at the bottom of one end of the supporting column, and the fine-tuning adaptive size measurement recording structure is also electrically connected with the cloud computer display screen;

the fine-adjustment adaptive size measurement recording structure comprises a capping connecting block, an extension inserting clamping block, an internal thread pushing column, a fine-adjustment telescopic column, an industrial camera, an assembly extension plate, an auxiliary illumination block and a shooting filter adjusting structure, the bottom end of the capping connecting block is connected with an extending plugging fixture block in a hot melting way, the outer side of the extending plugging fixture block is sleeved with an internal thread pushing column, the inner part of the internal thread pushing column is connected with a fine adjustment telescopic column through a thread, the top end of the interior of the fine adjustment telescopic column is connected with the bottom end of the extension splicing fixture block in a sliding way, the bottom end of the fine adjustment telescopic column is fixedly connected with the industrial camera, the peripheral side surface of the fine adjustment telescopic column is welded with an assembly extension plate, two sides of the assembly extension plate are both connected with the auxiliary illumination block through screws, and the bottom end of the assembly extension plate is fixedly connected with a shooting filter adjusting structure through screws;

shoot filter adjustment structure including the assembly positioning board, insert card post, printing opacity piece, motor and carry on piece, miniature output motor, drive gear, cooperation rack, first light filter and second light filter, four end angles of the upper surface of assembly positioning board all with insert card post welded connection, the top and the printing opacity piece fixed connection of assembly positioning board, the one end of assembly positioning board lower surface is fixed with the motor and carries on the piece, the inside and the miniature output motor that the piece was carried to the motor pass through the screw connection, miniature output motor's output and drive gear revolve and be connected, the outside and the cooperation rack toothing that drive the gear are connected, the one end and first light filter and the second light filter fixed connection of cooperation rack.

Preferably, the driving overturning displacement adjusting structure comprises an extending displacement stroke plate, a first motor, an output threaded rod, an axial adjusting carrying column, a mounting ribbed plate, a hydraulic piston cylinder, a lifting matching block, an overturning carrying block, a second motor and an automatic clamping driving structure, wherein one end of the extending displacement stroke plate is fixedly connected with the first motor through a screw, the output end of the first motor is rotatably connected with the output threaded rod, the outer side of the output threaded rod is connected with the axial adjusting carrying column through a thread, the axial adjusting carrying column is in sliding connection with the extending displacement stroke plate, one side of the top end of the axial adjusting carrying column is fixedly connected with the mounting ribbed plate through a screw, the top end of the mounting ribbed plate is fixedly connected with the hydraulic piston cylinder through a screw, the output end of the hydraulic piston cylinder is welded with the lifting matching block, and the bottom end of the lifting matching block is welded with the overturning carrying block, one end of the overturning carrying block is fixedly connected with a second motor through a screw, and the output end of the second motor is rotatably connected with the automatic clamping driving structure.

Preferably, the automatic clamping driving structure comprises an assembly built-in support, a micro cylinder, a pushing driving rod, a first linkage push rod, a second linkage push rod, a clamping fastening claw and an overtravel-preventing spring, one side of the inside of the micro cylinder is fixedly connected with the micro cylinder through a screw, the output end of the micro cylinder is connected with the pushing driving rod in a welding mode, the pushing driving rod is connected with the assembly built-in support through the first linkage push rod, the top end and the bottom end of the other side of the inside of the micro cylinder are connected with the clamping fastening claw in a sliding mode, the clamping fastening claw is connected with the clamping fastening claw through the overtravel-preventing spring, and the pushing driving rod is connected with the clamping fastening claw through the second linkage push rod.

Preferably, cooperation following chutes are formed in two sides of the pushing driving rod, displacement guide sliding rails are welded on two sides of the interior of the extension displacement stroke plate, and the cooperation following chutes and the displacement guide sliding rails are in clearance fit.

Preferably, the inner part of the internal thread pushing column is provided with a rotating matching ring groove, the peripheral side surface of the extending plugging fixture block is sleeved with an assembling rotating plate, and the assembling rotating plate and the matching ring groove are in clearance fit.

Preferably, the second optical filter is an infrared cut-off optical filter, the first optical filter is a full-spectrum optical filter, the second optical filter is connected with the matching rack through gluing, and the first optical filter is also connected with the matching rack through gluing.

Preferably, the output end of the second motor is rotatably connected with an output shaft, one end of the output shaft is sleeved with a roller bearing, and the automatic clamping driving structure is connected with the second motor through the roller bearing.

Preferably, the lifting guide sliding blocks are welded on two sides of one end of the assembling ribbed plate, one end of the hydraulic piston cylinder is provided with an assembling displacement stabilizing groove, and the assembling displacement stabilizing groove is in clearance fit with the lifting guide sliding blocks.

Preferably, the top end and the bottom end inside one end of the assembly built-in support are both provided with limiting and guiding square sliding holes, the outer side of one end of the clamping fastening claw is welded with a stroke sliding column, and the stroke sliding column is in clearance fit with the square sliding holes.

The invention has at least the following beneficial effects:

1. according to the device, through the design of the fine-tuning adaptive size measurement recording structure, the device is convenient for finishing good measurement performance on the size of a workpiece through fine-tuning of the shooting distance and the light adaptability brought by the shooting filter adjusting structure, the shooting definition and the focusing effect of the test are more comprehensively ensured, and the size qualification test is finished by comparing cloud data;

2. according to the invention, through the design of the driving overturning displacement adjusting structure, the device is convenient to finish automatic adjustment of overturning and displacement of the test workpiece, so that the workpiece size can be conveniently obtained from multiple angles, and the use convenience is improved.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the patent of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the patent of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention as a whole;

FIG. 2 is a front view of the present invention in its entirety;

FIG. 3 is an overall elevation view of a fine tune adaptive dimensional measurement listing structure according to the present invention;

FIG. 4 is a partial cross-sectional view of a fine tune adaptive dimensional measurement listing configuration of the present invention;

FIG. 5 is an exploded view of the structure of the fine tuning adaptive dimensional measurement listing structure of the present invention;

FIG. 6 is a schematic view of a partial structure of an adjusting structure of a photographing filter according to the present invention;

FIG. 7 is a schematic view of a partial structure of a mechanism for driving a turning displacement adjustment according to the present invention;

fig. 8 is a partial structural schematic view of the automatic clamping driving structure of the present invention.

In the figure: 1. a base; 2. a scanning size table; 3. a support pillar; 4. a cloud computer display screen; 5. capping the connecting block; 6. extending and inserting the clamping block; 7. an internal thread pushing column; 8. finely adjusting the telescopic column; 9. an industrial camera; 10. assembling an extension plate; 11. an auxiliary illumination block; 12. a shooting filter adjusting structure; 13. fine-tuning the adaptive size measurement recording structure; 14. assembling a positioning plate; 15. inserting a clamping column; 16. a light transmitting sheet; 17. a motor mounting block; 18. a micro output motor; 19. driving the gear; 20. matching the rack; 21. a first optical filter; 22. a second optical filter; 23. an extended displacement stroke plate; 24. a first motor; 25. an output threaded rod; 26. axially adjusting the carrying column; 27. assembling a rib plate; 28. a hydraulic piston cylinder; 29. lifting the matching block; 30. turning over the carrying block; 31. a second motor; 32. automatically clamping the driving structure; 33. driving the turning displacement adjusting structure; 34. assembling an interior mounting bracket; 35. a micro cylinder; 36. pushing the driving rod; 37. a first linkage push rod; 38. a second linkage push rod; 39. clamping the fastening claw; 40. prevent overtravel spring.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present invention and are not intended to limit the present invention.

Referring to fig. 1-8, a test instrument based on cloud computing comprises a base 1, a scanning size table 2 is fixed at the top end of the base 1, a driving overturning displacement adjusting structure 33 is fixed at one side of the base 1, a supporting column 3 is welded at the top end of one end of the base 1, a cloud computer display screen 4 is fixed at one end of the supporting column 3, a cloud computer main body is fixed inside the supporting column 3, the cloud computer main body is electrically connected with the cloud computer display screen 4, a fine-tuning adaptive size measurement recording structure 13 is fixed at the bottom of one end of the supporting column 3, and the fine-tuning adaptive size measurement recording structure 13 is also electrically connected with the cloud computer display screen 4;

the fine adjustment adaptive size measurement recording structure 13 comprises a capping connecting block 5, an extension inserting clamping block 6, an internal thread pushing column 7, a fine adjustment telescopic column 8, an industrial camera 9, an assembly extension plate 10, an auxiliary illumination block 11 and a shooting filter adjusting structure 12, wherein the bottom end of the capping connecting block 5 is in hot-melting connection with the extension inserting clamping block 6, the outer side of the extension inserting clamping block 6 is sleeved with the internal thread pushing column 7, the inner part of the internal thread pushing column 7 is connected with the fine adjustment telescopic column 8 through a thread, the top end of the inner part of the fine adjustment telescopic column 8 is in sliding connection with the bottom end of the extension inserting clamping block 6, the bottom end of the fine adjustment telescopic column 8 is fixedly connected with the industrial camera 9, the peripheral side surface of the fine adjustment telescopic column 8 is in welding connection with the assembly extension plate 10, the two sides of the assembly extension plate 10 are both connected with the auxiliary illumination block 11 through screws, and the bottom end of the, the adjusting structure 12 of the shooting filter comprises an assembling positioning plate 14, an access clamping column 15, a light-transmitting sheet 16, a motor carrying block 17, a micro output motor 18, a driving gear 19, a matching rack 20, a first light filter 21 and a second light filter 22, four end angles of the upper surface of the assembly positioning plate 14 are all connected with the access clamping columns 15 in a welded manner, the top end of the assembly positioning plate 14 is fixedly connected with the light-transmitting sheet 16, one end of the lower surface of the assembly positioning plate 14 is fixed with a motor carrying block 17, the inside of the motor carrying block 17 is connected with the micro output motor 18 through screws, the output end of the micro output motor 18 is rotatably connected with a driving gear 19, the outer side of the driving gear 19 is meshed with a matching rack 20 and is connected with the first light filter 21 and a second light filter 22, the lifting fine adjustment and the automatic switching suitable filter lens for shooting are conveniently completed, and therefore light deviation and focus losing are avoided.

The scheme has the following working processes:

the workpiece is placed at the top end of a scanning size table 2, a driving rod 36 is pushed forward by pushing of a micro cylinder 35, the conduction limit of a first linkage push rod 37 and a second linkage push rod 38 is utilized, a clamping fastening claw 39 is pushed to slide in an assembling inner bracket 34 by force, the clamping movement is completed towards the inside, the stress overtravel in the clamping process is avoided by an overtravel prevention spring 40, the workpiece is clamped and positioned, an output threaded rod 25 is driven to rotate by a first motor 24, the torque is transmitted to an axial adjustment carrying column 26 by the threaded connection between the output threaded rod 25 and the axial adjustment carrying column 26, the torque is limited to form a displacement driving force by the sliding connection between the axial adjustment carrying column 26 and an extension displacement stroke plate 23, the overturning displacement adjusting structure 33 is driven to drive the workpiece to perform the adjustment of the transverse displacement, and the lifting adjustment driven by a hydraulic piston cylinder 28 is matched, the workpiece is positioned at a proper position at the bottom end of the industrial camera 9, the post 7 is pushed through the active internal thread, the fine-tuning telescopic post 8 is lifted in the internal thread pushing post 7 according to the matching of the threads, the fine tuning of the shooting height of the industrial camera 9 is completed, the distance defocusing is avoided, when the external light is sufficient, the first optical filter 21 positioned at the initial displacement is used as a common optical filter to absorb and reflect infrared rays in natural light, so that the light receiving effect is kept in the shooting process of the industrial camera 9, the shooting is clearer, when the external light is darker, the micro output motor 18 is controlled to drive the gear 19 to complete clockwise rotation, the matching rack 20 is pushed to displace, the second optical filter 22 is driven to complete displacement to be positioned at the bottom end of the industrial camera 9, the light absorbing effect of the second optical filter 22 is utilized, all light is utilized, and the low-illumination performance is, the image picture is not out of focus, and when the bottom of the workpiece needs to be turned over and shot, the second motor 31 drives the automatic clamping driving structure 32 to complete rotation, so that the workpiece is turned over at an angle.

According to the working process, the following steps are known:

Further, the driving overturn displacement adjusting structure 33 comprises an extension displacement stroke plate 23, a first motor 24, an output threaded rod 25, an axial adjustment carrying column 26, a matching ribbed plate 27, a hydraulic piston cylinder 28, a lifting matching block 29, an overturn carrying block 30, a second motor 31 and an automatic clamping driving structure 32, wherein one end of the extension displacement stroke plate 23 is fixedly connected with the first motor 24 through a screw, the output end of the first motor 24 is rotatably connected with the output threaded rod 25, the outer side of the output threaded rod 25 is connected with the axial adjustment carrying column 26 through a screw, the axial adjustment carrying column 26 is in sliding connection with the extension displacement stroke plate 23, one side of the top end of the axial adjustment carrying column 26 is fixedly connected with the matching ribbed plate 27 through a screw, the top end of the matching ribbed plate 27 is fixedly connected with the hydraulic piston cylinder 28 through a screw, and the output end of the hydraulic piston cylinder 28 is welded with the lifting matching block 29, the bottom end of the lifting matching block 29 is welded with the overturning carrying block 30, one end of the overturning carrying block 30 is fixedly connected with a second motor 31 through a screw, and the output end of the second motor 31 is rotatably connected with an automatic clamping driving structure 32, so that the workpiece is driven to overturn and the displacement is adjusted conveniently;

further, the automatic clamping driving structure 32 comprises an assembly built-in support 34, a micro cylinder 35, a pushing driving rod 36, a first linkage push rod 37, a second linkage push rod 38, a clamping fastening claw 39 and an anti-overtravel spring 40, wherein one side inside the micro cylinder 35 is fixedly connected with the micro cylinder 35 through a screw, the output end of the micro cylinder 35 is connected with the pushing driving rod 36 in a welding manner, the pushing driving rod 36 is connected with the assembly built-in support 34 through the first linkage push rod 37, the top end and the bottom end of the other side inside the micro cylinder 35 are both connected with the clamping fastening claw 39 in a sliding manner, the clamping fastening claw 39 is connected with the clamping fastening claw 39 through the anti-overtravel spring 40, the pushing driving rod 36 is connected with the clamping fastening claw 39 through the second linkage push rod 38, and automatic clamping of a workpiece is facilitated;

furthermore, matching following sliding grooves are formed in two sides of the pushing driving rod 36, displacement guide sliding rails are welded on two sides inside the extending displacement travel plate 23, and the matching following sliding grooves and the displacement guide sliding rails are in clearance fit, so that axial adjustment of stress derivation of the carrying columns 26 is facilitated to form longitudinal displacement of the driven workpiece;

furthermore, a rotating matching ring groove is formed in the internal thread pushing column 7, an assembling rotating plate is sleeved on the peripheral side surface of the extending inserting clamping block 6, the assembling rotating plate and the matching ring groove are in clearance fit, so that rotation limiting is conveniently formed, and the internal thread pushing column 7 pushes the fine-tuning telescopic column 8 to complete lifting adjustment in the rotating process;

furthermore, the type of the second optical filter 22 is an infrared cut-off optical filter, the type of the first optical filter 21 is a full-spectrum optical filter, the second optical filter 22 is connected with the matching rack 20 through gluing, and the first optical filter 21 is connected with the matching rack 20 through gluing, so that the adaptation to different light rays can be conveniently completed through adjustment;

further, an output shaft is rotatably connected to an output end of the second motor 31, one end of the output shaft is sleeved with a roller bearing, and the automatic clamping driving structure 32 is connected with the second motor 31 through the roller bearing, so that the output of rotating and overturning is convenient to complete;

furthermore, the two sides of one end of the assembling ribbed plate 27 are both welded with a lifting guide slide block, one end of the hydraulic piston cylinder 28 is provided with an assembling displacement stabilizing groove, and the assembling displacement stabilizing groove and the lifting guide slide block are in clearance fit, so that the lifting effect is convenient to stabilize;

furthermore, the inside top and the bottom of assembly built-in support 34 one end have all been seted up spacing direction square slide opening, and the stroke slip post has all been welded in the outside of clamping fastening claw 39 one end, and stroke slip post and square slide opening are clearance fit, are convenient for form the spacing of displacement, avoid the clamping in-process displacement to lose the stroke.

The foregoing shows and describes the general principles of the present patent, its essential features, and its advantages. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are only for the purpose of illustrating the principles of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims. The scope of the invention patent claims is defined by the appended claims and their equivalents.

Claims

1. The test instrument based on cloud computing comprises a base (1) and is characterized in that a scanning size table (2) is fixed at the top end of the base (1), a driving overturning displacement adjusting structure (33) is fixed on one side of the base (1), a supporting column (3) is welded at the top end of one end of the base (1), a cloud computer display screen (4) is fixed at one end of the supporting column (3), a cloud computer main body is fixed inside the supporting column (3), the cloud computer main body is electrically connected with the cloud computer display screen (4), a fine-tuning adaptive size measuring recording structure (13) is fixed at the bottom of one end of the supporting column (3), and the fine-tuning adaptive size measuring recording structure (13) is also electrically connected with the cloud computer display screen (4);

the fine adjustment adaptive size measurement recording structure (13) comprises a capping connecting block (5), an extension inserting clamping block (6), an internal thread pushing column (7), a fine adjustment telescopic column (8), an industrial camera (9), an assembling extending plate (10), an auxiliary illumination block (11) and a shooting filter adjusting structure (12), wherein the bottom end of the capping connecting block (5) is in hot-melt connection with the extension inserting clamping block (6), the outer side of the extension inserting clamping block (6) is sleeved with the internal thread pushing column (7), the inner part of the internal thread pushing column (7) is connected with the fine adjustment telescopic column (8) through threads, the top end of the inner part of the fine adjustment telescopic column (8) is in sliding connection with the bottom end of the extension inserting clamping block (6), the bottom end of the fine adjustment telescopic column (8) is fixedly connected with the industrial camera (9), and the peripheral side surface of the fine adjustment telescopic column (8) is in welding connection with the assembling extending plate (10), both sides of the assembly extension plate (10) are connected with the auxiliary illumination block (11) through screws, and the bottom end of the assembly extension plate (10) is fixedly connected with the shooting filter adjusting structure (12) through screws;

the shooting filter adjusting structure (12) comprises an assembly positioning plate (14), an access clamping column (15), a light-transmitting sheet (16), a motor carrying block (17), a micro output motor (18), a driving gear (19), a matching rack (20), a first light filter (21) and a second light filter (22), wherein four end angles of the upper surface of the assembly positioning plate (14) are welded with the access clamping column (15), the top end of the assembly positioning plate (14) is fixedly connected with the light-transmitting sheet (16), the motor carrying block (17) is fixed at one end of the lower surface of the assembly positioning plate (14), the interior of the motor carrying block (17) is connected with the micro output motor (18) through screws, the output end of the micro output motor (18) is rotationally connected with the driving gear (19), the outer side of the driving gear (19) is meshed with the matching rack (20), one end of the matching rack (20) is fixedly connected with the first optical filter (21) and the second optical filter (22).

2. The cloud computing-based test instrument as claimed in claim 1, wherein the driving and overturning displacement adjusting structure (33) comprises an extension displacement stroke plate (23), a first motor (24), an output threaded rod (25), an axial adjustment carrying column (26), a mounting rib plate (27), a hydraulic piston cylinder (28), a lifting matching block (29), an overturning carrying block (30), a second motor (31) and an automatic clamping driving structure (32), one end of the extension displacement stroke plate (23) is fixedly connected with the first motor (24) through a screw, the output end of the first motor (24) is rotatably connected with the output threaded rod (25), the outer side of the output threaded rod (25) is connected with the axial adjustment carrying column (26) through a screw thread, and the axial adjustment carrying column (26) is in sliding connection with the extension displacement stroke plate (23), one side of the top end of the axial adjusting carrying column (26) is fixedly connected with a mounting ribbed plate (27) through a screw, the top end of the mounting ribbed plate (27) is fixedly connected with a hydraulic piston cylinder (28) through a screw, the output end of the hydraulic piston cylinder (28) is welded with a lifting matching block (29), the bottom end of the lifting matching block (29) is welded with an overturning carrying block (30), one end of the overturning carrying block (30) is fixedly connected with a second motor (31) through a screw, and the output end of the second motor (31) is rotatably connected with an automatic clamping driving structure (32).

3. The cloud computing-based test instrument according to claim 2, wherein the automatic clamping driving structure (32) comprises an assembly built-in support (34), a micro cylinder (35), a pushing driving rod (36), a first linkage push rod (37), a second linkage push rod (38), a clamping fastening claw (39) and an overtravel-preventing spring (40), one side of the interior of the micro cylinder (35) is fixedly connected with the micro cylinder (35) through a screw, the output end of the micro cylinder (35) is welded with the pushing driving rod (36), the pushing driving rod (36) is connected with the assembly built-in support (34) through the first linkage push rod (37), the top end and the bottom end of the other side of the interior of the micro cylinder (35) are both connected with the clamping fastening claw (39) in a sliding manner, and the clamping fastening claw (39) is connected with the clamping fastening claw (39) through the overtravel-preventing spring (40), the pushing driving rod (36) is connected with the clamping fastening claw (39) through a second linkage push rod (38).

4. The cloud computing-based test instrument according to claim 2, wherein matching following sliding grooves are formed in both sides of the pushing driving rod (36), displacement guide sliding rails are welded on both sides of the inside of the extending displacement stroke plate (23), and the matching following sliding grooves are in clearance fit with the displacement guide sliding rails.

5. The cloud computing-based test instrument as claimed in claim 1, wherein a rotary matching ring groove is formed in the internal thread pushing column (7), an assembling rotating plate is sleeved on the peripheral side surface of the extending plugging fixture block (6), and the assembling rotating plate and the matching ring groove are in clearance fit.

6. A cloud computing based test instrument according to claim 1, wherein said second filter (22) is of the type of an infrared cut filter, said first filter (21) is of the type of a full spectrum filter, said second filter (22) is adhesively connected to a mating rack (20), and said first filter (21) is adhesively connected to a mating rack (20).

7. The cloud computing-based test instrument according to claim 2, wherein an output shaft is rotatably connected to an output end of the second motor (31), a roller bearing is sleeved at one end of the output shaft, and the automatic clamping driving structure (32) is connected with the second motor (31) through the roller bearing.

8. The cloud computing-based test instrument as claimed in claim 2, wherein the lifting guide sliders are welded to both sides of one end of the assembly rib plate (27), one end of the hydraulic piston cylinder (28) is provided with an assembly displacement stabilizing groove, and the assembly displacement stabilizing groove and the lifting guide sliders are in clearance fit.

9. The cloud computing-based test instrument as claimed in claim 3, wherein the top end and the bottom end of the inside of one end of the assembling inner support (34) are provided with limiting and guiding square sliding holes, the outer side of one end of the clamping fastening claw (39) is welded with a stroke sliding column, and the stroke sliding column is in clearance fit with the square sliding holes.