CN210109037U - Steel construction nondestructive test equipment with raising and lowering functions - Google Patents

Abstract

The utility model relates to the technical field of detection equipment, aim at providing a steel construction nondestructive test equipment with raising and lowering functions, its technical scheme main points are including ultrasonic probe and main control system, and ultrasonic probe passes through connecting wire and main control system electric connection, still include bottom plate, first motor and elevating system, and first motor and main control system all set up on the bottom plate, and elevating system includes drive sprocket, driven sprocket, chain and elevator, are equipped with the crane on the bottom plate, drive sprocket and driven sprocket rotate through first pivot and second pivot respectively and connect in the crane, and the chain cover is established on drive sprocket and driven sprocket and is tensioned by drive sprocket and driven sprocket, and first motor sets up on the bottom plate and with the linkage of first pivot, the elevator sets up on the chain, and ultrasonic probe links to each other with the elevator; the steel structure nondestructive testing equipment with the lifting function does not need workers to climb to a high place to carry out detection, and high-altitude operation is avoided, so that potential safety hazards are reduced.

Description

Steel construction nondestructive test equipment with raising and lowering functions

Technical Field

The utility model relates to a check out test set's technical field, in particular to steel construction nondestructive test equipment with raising and lowering functions.

Background

The ultrasonic waves can be reflected on interfaces of different substances in the transmission process, have the characteristics of good directivity, large transmission energy, strong penetrating power, high sensitivity and the like, and can determine the position and the size of a defect by the reflection characteristic of the ultrasonic waves in a workpiece, so that the ultrasonic waves are widely applied to detection and flaw detection, and a steel structure is a structure consisting of steel materials and is one of main building structure types; the structure mainly comprises steel beams, steel columns, steel trusses and other members made of section steel, steel plates and the like, and all the members or parts are usually connected by adopting welding seams, bolts or rivets; because of its light dead weight, and construction is simple and convenient, widely apply to large-scale factory building, venue, super high-rise building field etc..

Because each part of the steel structure is often connected by adopting a welding means, nondestructive detection operation needs to be carried out on the connection position of each part of the steel structure so as to detect whether the connection structure is firm or not.

Because areas such as factory buildings and venues that the steel construction was made are high-rise buildings mostly, and traditional steel construction nondestructive test equipment does not have raising and lowering functions, and the staff need climb the eminence and detect, carries out high altitude construction, has great potential safety hazard.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a steel construction nondestructive test equipment with raising and lowering functions, the staff need not to climb to the eminence and detect when carrying out steel construction detection, avoids high altitude construction to reduce the potential safety hazard.

The above technical purpose of the present invention can be achieved by the following technical solutions:

the utility model provides a steel construction nondestructive test equipment with raising and lowering functions, includes ultrasonic transducer and control host computer, and ultrasonic transducer passes through connecting wire and control host computer electric connection, still includes bottom plate, first motor and elevating system, first motor and control host computer all set up on the bottom plate, elevating system includes drive sprocket, driven sprocket, chain and elevator, be equipped with the crane on the bottom plate, drive sprocket and driven sprocket rotate through first pivot and second pivot respectively and connect in the crane, the chain cover is established on drive sprocket and driven sprocket and by drive sprocket and driven sprocket tensioning, first motor setting on the bottom plate and with first pivot linkage, the elevator sets up on the chain, ultrasonic transducer links to each other with the elevator.

Through adopting above-mentioned technical scheme, the staff is carrying out steel construction and is detecting time measuring, start first motor, first motor is beaten first pivot and is rotated, first pivot drives drive sprocket and rotates at the rotation in-process, drive sprocket drives driven sprocket through the chain and rotates at the rotation in-process, drive sprocket and driven sprocket rotate jointly and drive and last the chain and rotate, the elevator removes along with the rotation of chain, the elevator drives ultrasonic transducer and removes together at the removal in-process, thereby it detects to need not the staff to climb the eminence, avoid high altitude construction, and the potential safety hazard is reduced.

Further setting: the ultrasonic probe is arranged on the connecting plate, and the two ends of the connecting plate are respectively connected with the lifting blocks.

Through adopting above-mentioned technical scheme, set up elevating system into two sets ofly, set up elevating system into a set of comparison with, can improve ultrasonic probe at the stability of removal in-process, reduced the possibility that ultrasonic probe rocked, bring the convenience for steel construction nondestructive test.

Further setting: two sets of a first motor of elevating system sharing is equipped with drive mechanism on the bottom plate, and drive mechanism includes transfer line, worm and worm wheel, first pivot is connected at the both ends of transfer line, the worm wheel sets up on the transfer line, the worm is connected in first motor, the worm wheel meshes with the worm.

By adopting the technical scheme, the two groups of lifting mechanisms share one motor, and compared with a group of lifting mechanisms which use one motor, the energy can be saved.

Further setting: the bottom plate is provided with a support frame, the support frame is provided with a support block, the support block is provided with an arc-shaped groove, and the transmission rod is located in the arc-shaped groove.

Through adopting above-mentioned technical scheme, the supporting shoe can support the dwang to improve the stability of dwang in the rotation process.

Further setting: the arc-shaped groove is internally provided with a ball, and the transmission rod is abutted against the ball.

Through adopting above-mentioned technical scheme, at the transfer line rotation in-process, the roll takes place to roll to make and change into rolling friction by sliding friction between transfer line and the arc wall, make the transfer line more smooth and easy at the rotation in-process.

Further setting: the bottom plate is further provided with a guide rod, and the guide rod penetrates through the lifting block.

Through adopting above-mentioned technical scheme, the setting of guide bar can lead to the moving direction of elevator to improve the stability of elevator at the removal in-process.

Further setting: and the bottom plate is also provided with rollers.

Through adopting above-mentioned technical scheme, the setting of gyro wheel is convenient for this check out test set's removal, and it is convenient to remove this check out test set for the staff, only needs to promote check out test set, can remove.

Further setting: the ultrasonic probe is provided with two ultrasonic probes, a driving device is arranged on the connecting plate and comprises a driving motor, a gear, a first rack and a second rack, the driving motor is arranged on the connecting plate, the gear is arranged on an output shaft of the driving motor, the first rack and the second rack are both in sliding connection with the connecting plate, the first rack is meshed with the gear, the second rack is meshed with the gear, and the first rack and the second rack are respectively connected with the ultrasonic probes.

Through adopting above-mentioned technical scheme, start driving motor, driving motor drives the gear and rotates, and the gear drives first rack and second rack removal at the rotation in-process, and first rack and second rack drive ultrasonic transducer respectively and remove to the purpose of realization automatically regulated ultrasonic transducer position in the horizontal direction brings the convenience for the detection, and ultrasonic transducer on first rack and the second rack can detect the steel construction of difference simultaneously, improves detection efficiency.

To sum up, the utility model discloses following beneficial effect has:

1. when a worker detects a steel structure, the first motor is started, the first motor drives the first rotating shaft to rotate, the first rotating shaft drives the driving chain wheel to rotate in the rotating process, the driving chain wheel drives the driven chain wheel to rotate through the chain in the rotating process, the driving chain wheel and the driven chain wheel rotate together to drive the continuous chain to rotate, the lifting block moves along with the rotation of the chain, and the lifting block drives the ultrasonic probe to move together in the moving process, so that the worker does not need to climb to a high place to detect, high-altitude operation is avoided, and potential safety hazards are reduced;

2. the lifting mechanisms are arranged into two groups, so that compared with the lifting mechanisms arranged into one group, the stability of the ultrasonic probe in the moving process can be improved, the possibility of shaking of the ultrasonic probe is reduced, and convenience is brought to nondestructive testing of a steel structure;

3. the setting to the pole can lead the moving direction of elevator to improve the stability of elevator at the removal in-process.

Drawings

Fig. 1 is a schematic structural diagram for embodying the present invention in the present embodiment;

FIG. 2 is a schematic structural diagram of a driving device in the present embodiment;

fig. 3 is an enlarged view of the structure of the part a in fig. 2 for showing the connection relationship between the limit rack and the second rack.

In the figure, 1, an ultrasonic probe; 2. a control host; 3. a base plate; 4. a connecting plate; 5. a first motor; 6. a lifting mechanism; 7. a roller; 8. a drive sprocket; 9. a driven sprocket; 10. a chain; 11. a lifting block; 12. a lifting frame; 13. a first rotating shaft; 14. a second rotating shaft; 15. a guide bar; 16. a frame; 17. a transmission mechanism; 18. a transmission rod; 19. a worm; 20. a worm gear; 21. a stabilizer frame; 22. a support frame; 23. a support block; 24. an arc-shaped slot; 25. a ball bearing; 26. a connecting wire; 27. a drive device; 28. a drive motor; 29. a gear; 30. a first rack; 31. a second rack; 32. a limiting strip; 33. a dovetail groove; 34. a dovetail strip; 35. a first link; 36. a second link; 37. a limiting block; 38. a connecting seat.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Example (b): a steel structure nondestructive testing device with a lifting function is shown in figure 1 and comprises an ultrasonic probe 1, a control host 2, a bottom plate 3, a connecting plate 4, a first motor 5 and a lifting mechanism 6.

As shown in fig. 1, the bottom plate 3 is further provided with rollers 7.

As shown in fig. 1, elevating system 6 sets up to two sets ofly, elevating system 6 includes drive sprocket 8, driven sprocket 9, chain 10 and elevator 11, be equipped with crane 12 on bottom plate 3, drive sprocket 8 rotates through first pivot 13 and connects in crane 12, driven sprocket 9 rotates through second pivot 14 and connects in crane 12, chain 10 cover is established on drive sprocket 8 and driven sprocket 9 and is tensioned by drive sprocket 8 and driven sprocket 9, elevator 11 sets up on chain 10, still be equipped with guide bar 15 on bottom plate 3, guide bar 15 runs through elevator 11, so as to lead the moving direction of elevator 11, improve the stability of elevator 11 in the removal process.

As shown in fig. 1 and 2, the two sets of lifting mechanisms 6 share a first motor 5, the first motor 5 is disposed on the bottom plate 3 through a frame 16 and is linked with the first rotating shaft 13, a transmission mechanism 17 is disposed on the bottom plate 3, the transmission mechanism 17 includes a transmission rod 18, a worm 19 and a worm wheel 20, two ends of the transmission rod 18 are connected with the first rotating shaft 13, the worm wheel 20 is disposed on the transmission rod 18, the worm 19 is connected with the first motor 5, the frame 16 is provided with a stabilizing frame 21, the worm 19 is rotatably connected with the stabilizing frame 21, and the worm wheel 20 is meshed with the worm 19.

The first motor 5 is started, the first motor 5 drives the worm 19 to rotate, the worm 19 drives the worm wheel 20 to rotate in the rotating process, the worm wheel 20 drives the transmission rod 18 to rotate in the rotating process, the transmission rod 18 drives the first rotating shafts 13 at two ends to rotate in the rotating process, the first rotating shafts 13 drive the second rotating shafts 14 to rotate through the chains 10, the first chain wheels and the second chain wheels drive the chains 10 to rotate continuously in the rotating process, and the lifting block 11 moves along with the rotation of the chains 10.

As shown in fig. 1 and 2, a supporting frame 22 is arranged on the bottom plate 3, a supporting block 23 is arranged on the supporting frame 22, an arc-shaped groove 24 is arranged on the supporting block 23, a ball 25 is arranged in the arc-shaped groove 24, and the transmission rod 18 is located in the arc-shaped groove 24 and is abutted against the ball 25, so that the transmission rod 18 is supported, and the stability of the transmission rod 18 in the rotating process is improved.

As shown in fig. 1 and 2, the ultrasonic probe 1 and the control host 2 are both provided in two, the control host 2 is provided on the bottom plate 3, and the ultrasonic probe 1 is electrically connected to the control host 2 through a connection line 26.

As shown in fig. 2 and 3, two ends of the connecting plate 4 are respectively connected with the lifting block 11, the ultrasonic probe 1 is arranged on the connecting plate 4 through the driving device 27, the driving device 27 is arranged on the connecting plate 4, the driving device 27 comprises a driving motor 28, a gear 29, a first rack 30 and a second rack 31, the driving motor 28 is arranged on one side of the connecting plate 4 close to the ground through a connecting seat 38, an output shaft of the driving motor 28 penetrates through the connecting plate 4, the gear 29 is arranged on an output shaft of the driving motor 28, the first rack 30 and the second rack 31 are both slidably connected with the connecting plate 4, the connecting plate 4 is provided with a limit strip 32, the limit strip 32 is provided with a dovetail groove 33, the first rack 30 and the second rack 31 are both provided with a dovetail strip 34, the dovetail strip 34 is slidably matched with the dovetail groove 33, the first rack 30 is engaged with the gear 29, the second rack 31 is engaged with the gear 29, the first rack 30 is connected with the ultrasonic probe, the second rack 31 is connected with the ultrasonic probe 1 through a second connecting rod 36, and one end of the first rack 30 departing from the ultrasonic probe 1 and one end of the second rack 31 departing from the ultrasonic probe 1 are both provided with a limiting block 37 so as to limit the first rack 30 and the second rack 31.

In the moving process of the lifting block 11, the connecting plate 4 moves along with the lifting block 11, so that the ultrasonic probe 1 is driven to move, and nondestructive testing is carried out on a steel structure at a high position.

The driving motor 28 is started, the driving motor 28 drives the gear 29 to rotate, the gear 29 drives the first rack 30 and the second rack 31 to move in the rotating process, the first rack 30 and the second rack 31 drive the ultrasonic probe 1 to move through the first connecting rod 35 and the second connecting rod 36 respectively, accordingly, the position of the ultrasonic probe 1 in the horizontal direction is changed, and a worker can adjust the position of the ultrasonic probe 1 in the horizontal direction according to work requirements.

The implementation process comprises the following steps: start first motor 5, first motor 5 drive chain 10 removes, and chain 10 drives connecting plate 4 through elevator 11 and removes to drive ultrasonic transducer 1 and remove, the staff is carrying out steel construction when detecting, need not the staff and climbs the eminence and detect, avoids high altitude construction, reduces the potential safety hazard.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications to the present embodiment without inventive contribution as required after reading the present specification, but all of them are protected by patent laws within the scope of the claims of the present invention.

Claims (8)

1. The utility model provides a steel construction nondestructive test equipment with raising and lowering functions, includes ultrasonic probe (1) and main control system (2), and ultrasonic probe (1) passes through connecting wire (26) and main control system (2) electric connection, its characterized in that: also comprises a bottom plate (3), a first motor (5) and a lifting mechanism (6), the first motor (5) and the control host (2) are both arranged on the bottom plate (3), the lifting mechanism (6) comprises a driving chain wheel (8), a driven chain wheel (9), a chain (10) and a lifting block (11), a lifting frame (12) is arranged on the bottom plate (3), the driving chain wheel (8) and the driven chain wheel (9) are respectively connected to the lifting frame (12) through a first rotating shaft (13) and a second rotating shaft (14) in a rotating way, the chain (10) is sleeved on the driving chain wheel (8) and the driven chain wheel (9) and is tensioned by the driving chain wheel (8) and the driven chain wheel (9), the first motor (5) is arranged on the bottom plate (3) and is linked with the first rotating shaft (13), the lifting block (11) is arranged on the chain (10), and the ultrasonic probe (1) is connected with the lifting block (11).

2. The steel structure nondestructive testing device with the lifting function as recited in claim 1, wherein: still include connecting plate (4), elevating system (6) set up to two sets of, ultrasonic probe (1) sets up on connecting plate (4), elevator (11) are connected respectively at the both ends of connecting plate (4).

3. The steel structure nondestructive testing device with the lifting function as recited in claim 2, wherein: two sets of first motor (5) of elevating system (6) sharing is equipped with drive mechanism (17) on bottom plate (3), and drive mechanism (17) are including transfer line (18), worm (19) and worm wheel (20), first pivot (13) are connected at the both ends of transfer line (18), worm wheel (20) set up on transfer line (18), worm (19) are connected in first motor (5), worm wheel (20) and worm (19) meshing.

4. The steel structure nondestructive testing device with the lifting function as recited in claim 3, wherein: the bottom plate (3) is provided with a support frame (22), the support frame (22) is provided with a support block (23), the support block (23) is provided with an arc-shaped groove (24), and the transmission rod (18) is positioned in the arc-shaped groove (24).

5. The steel structure nondestructive testing device with the lifting function as recited in claim 4, wherein: the arc-shaped groove (24) is internally provided with a ball (25), and the transmission rod (18) is abutted against the ball (25).

6. The steel structure nondestructive testing device with the lifting function as recited in claim 1, wherein: the bottom plate (3) is further provided with a guide rod (15), and the guide rod (15) penetrates through the lifting block (11).

7. The steel structure nondestructive testing device with the lifting function as recited in claim 1, wherein: and the bottom plate (3) is also provided with a roller (7).

8. The steel structure nondestructive testing device with the lifting function as recited in claim 2, wherein: ultrasonic probe (1) sets up to two, be equipped with drive arrangement (27) on connecting plate (4), drive arrangement (27) include driving motor (28), gear (29), first rack (30) and second rack (31), driving motor (28) set up on connecting plate (4), gear (29) set up on the output shaft of driving motor (28), first rack (30) and second rack (31) all with connecting plate (4) sliding connection, first rack (30) and gear (29) meshing, second rack (31) and gear (29) meshing, ultrasonic probe (1) is connected respectively in first rack (30) and second rack (31).

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