CN220854080U

CN220854080U - BIM-based steel structure construction strength monitoring device

Info

Publication number: CN220854080U
Application number: CN202322798953.4U
Authority: CN
Inventors: 毕强; 刘泽鲲; 郭旺
Original assignee: China 22MCC Group Corp Ltd
Current assignee: China 22MCC Group Corp Ltd
Priority date: 2023-10-19
Filing date: 2023-10-19
Publication date: 2024-04-26
Anticipated expiration: 2033-10-19

Abstract

The utility model discloses a BIM-based steel structure construction strength monitoring device. The infrared sensor comprises a base, two stand columns are symmetrically arranged on the base, two adjusting arms are respectively inserted in the two stand columns in a hollow structure, the top ends of the two adjusting arms extend out of the stand columns and are respectively and symmetrically provided with a semi-annular detection part, connecting plates are fixedly connected in the two detection parts respectively, and an infrared emitter and an infrared receiver are respectively arranged on the two connecting plates; one side be equipped with lift adjustment subassembly between stand and the regulating arm, lift adjustment subassembly includes threaded rod, bevel gear pair and transmission shaft, vertical shaft hole has been seted up to the regulating arm, in the threaded rod rotation installation stand and with the internal thread cooperation in the shaft hole of regulating arm, the transmission shaft runs through the lateral wall of stand and passes through bevel gear pair transmission with the threaded rod. The utility model can detect the shape of the steel structure, and the signal of the infrared emitter can be shielded after the steel structure is deformed, thereby achieving the purpose of monitoring the strength of the steel structure.

Description

BIM-based steel structure construction strength monitoring device

Technical Field

The utility model relates to a steel structure, in particular to a BIM-based steel structure construction strength monitoring device.

Background

BIM technology is a datamation tool applied to engineering design, construction and management, and by integrating datamation and informatization models of buildings, sharing and transferring are carried out in the whole life cycle process of project planning, operation and maintenance, so that engineering technicians can correctly understand and efficiently respond to various building information.

After the BIM technology is used for building the steel structure, the strength of the supporting part of the steel structure is required to be monitored, the existing monitoring equipment is complicated to use, the monitoring equipment cannot be adjusted according to the height of the steel structure, and the monitoring efficiency of the strength of the steel structure is reduced. The utility model of China with the authorized bulletin number of CN215115925U discloses a steel structure monitoring device, which can only detect point positions.

Disclosure of utility model

The utility model aims to solve the technical problems, so as to provide the BIM-based steel structure construction strength monitoring device, and the monitoring efficiency is improved.

The utility model solves the technical problems and adopts the following technical scheme:

The BIM-based steel structure construction strength monitoring device comprises a base, two upright posts are symmetrically arranged on the base, two adjusting arms are respectively inserted in the hollow structures of the two upright posts, the top ends of the two adjusting arms extend out of the upright posts and are respectively symmetrically provided with a semi-annular detection part, connecting plates are fixedly connected in the two detection parts respectively, and an infrared emitter and an infrared receiver are respectively arranged on the two connecting plates; one side be equipped with lift adjustment subassembly between stand and the regulating arm, lift adjustment subassembly includes threaded rod, bevel gear pair and transmission shaft, vertical shaft hole has been seted up to the regulating arm, in the threaded rod rotation installation stand and with the internal thread cooperation in the shaft hole of regulating arm, the transmission shaft runs through the lateral wall of stand and passes through bevel gear pair transmission with the threaded rod.

Compared with the prior art, the utility model adopting the technical scheme has the beneficial effects that:

Through the setting of infrared transmitter and infrared receiver, can carry out the shape detection to the steel construction, can shelter from infrared transmitter's signal after the steel construction takes place deformation to reached the purpose of monitoring the intensity of steel construction, through the setting of lift adjustment subassembly, can adjust the height of two sets of monitoring portions, make the monitoring portion can adapt to the steel construction of different co-altitude and monitor, thereby improved the detection efficiency of steel construction intensity.

Further, the optimization scheme of the utility model is as follows:

the upper end of the adjusting arm is provided with a horizontal part, and the detecting part is positioned on the end face of the horizontal part.

The lower extreme of threaded rod passes through the bearing frame and rotates with the base to be connected, and the bevel gear pair includes driven bevel gear and initiative bevel gear, and driven bevel gear installs in the lower part of threaded rod, and initiative bevel gear installs the inner at the transmission shaft, and the knob is installed to the outer end of transmission shaft.

The lower extreme symmetry of the vertical portion of adjustment arm is seted up flutedly, and the gyro wheel is installed to the recess rotation, and gyro wheel and the inner wall roll connection of stand.

Semicircular connecting semi-rings are symmetrically arranged between the two stand columns, T-shaped slots are formed in the end faces of the connecting semi-rings, supporting plates are arranged on the outer walls of the stand columns, T-shaped clamping claws are arranged on the stand columns on the upper portions of the supporting plates, and the slots of the connecting semi-rings are arranged on the supporting plates and clamped on the clamping claws.

The end faces of the two detection parts are respectively provided with a positioning hole, and the positioning holes of the two detection parts are connected through a positioning pin.

The base is provided with mounting feet, and mounting holes are formed in the mounting feet.

The section of the upright post is square or rectangular.

The lower end of the upright post is in a horn mouth shape.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present utility model;

FIG. 2 is an enlarged schematic view at A of FIG. 1;

FIG. 3 is a schematic view of a connection structure between a column and an adjusting arm according to an embodiment of the present utility model;

fig. 4 is a schematic structural diagram of a monitoring portion according to an embodiment of the present utility model.

In the figure: a base 1; mounting feet 1-1; a first upright 2; a second upright 3; a first adjustment arm 4; a vertical part 4-1; shaft hole 4-1-1; a horizontal part 4-2; a detection unit 4-3; 4-4 parts of connecting plates; positioning holes 4-5; positioning pins 4-6; a second adjusting arm 5; an infrared emitter 6; an infrared receiver 7; a bearing seat 8; a threaded rod 9; a driven bevel gear 10; an axle 11; a knob 12; a groove 13; a roller 14; a connecting half ring 15; a support plate 16; a claw 17; and a support bar 18.

Detailed Description

The utility model is further described in detail below with reference to the drawings and examples.

Referring to fig. 1-4, the present embodiment is a building strength monitoring device for a steel structure based on BIM, and mainly comprises a base 1, a first upright 2, a second upright 3, a first adjusting arm 4, a second adjusting arm 5 and a lifting adjusting assembly. The base 1 is U-shaped, is of a split combined structure, is composed of two L-shaped branch seats, the base 1 is horizontally arranged, the four corners of the base are provided with mounting feet 1-1, the mounting feet 1-1 are provided with mounting holes, the mounting feet 1-1 and the base 1 are integrally formed, and the mounting feet 1-1 are used for fixing the device.

The base 1 is symmetrically provided with a first vertical column 2 and a second vertical column 3, the first vertical column 2 and the second vertical column 3 are hollow structures, the sections of the first vertical column 2 and the second vertical column 3 are square or rectangular, and the lower ends of the two vertical columns are bell-mouthed and are provided with a bottom plate.

The first adjusting arm 4 and the second adjusting arm 5 with the same structure are respectively inserted into the first upright 2 and the second upright 3, the first adjusting arm 4 mainly comprises a vertical part 4-1, a horizontal part 4-2 and a detecting part 4-3, the vertical part 4-1 is inserted into the first upright 2, the vertical part 4-1 is provided with a vertical shaft hole 4-1-1, the shaft hole 4-1-1 is provided with internal threads, the upper end of the vertical part 4-1 extends out of the upper end of the first upright 2, the horizontal part 4-2 is positioned at the upper end of the vertical part 4-1, the vertical part 4-1 and the horizontal part 4-2 are in an inverted L shape, the end part of the horizontal part 4-2 is provided with the detecting part 4-3, the detecting part 4-3 is in a semi-annular shape, the detecting part 4-3, the vertical part 4-1 and the horizontal part 4-2 are integrally formed, and the strength is improved.

The detection parts 4-3 of the first adjusting arm 4 and the second adjusting arm 5 are symmetrically arranged to be circular, the two adjusting parts 4-3 are respectively provided with a connecting plate 4-4, the two connecting plates 4-4 are symmetrically arranged, the connecting plate 4-4 of the first adjusting arm 4 is embedded with an infrared emitter 6, and the connecting plate 4-4 of the second adjusting arm 5 is embedded with an infrared receiver 7. Two locating holes 4-5 are respectively formed in the end faces of the two detection parts 4-3, locating pins 4-6 are inserted into the locating holes 4-5, and the locating holes 4-5 and the locating pins 4-6 can achieve centering and locating between the two detection parts 4, so that signals emitted by the infrared emitter 6 can be accurately received by the infrared receiver 7.

A lifting adjusting component is arranged between the first upright post 2 and the first adjusting arm 4 and mainly comprises a bearing seat 8, a threaded rod 9, a driven bevel gear 10, a driving bevel gear, a transmission shaft and a knob 12. The threaded rod 9 is vertically arranged in the first upright post 2 and is matched with the internal threads of the shaft hole 4-1-1 of the first adjusting arm 4, and the threaded rod 9 is rotationally connected with the bottom plate of the first upright post 2 through a bearing seat. The lower part of the threaded rod 9 is provided with a driven bevel gear 10, the driven bevel gear 10 and a driving bevel gear form a bevel gear pair and are meshed for transmission, the driving bevel gear is arranged at the inner end of a transmission shaft, the transmission shaft horizontally penetrates through the outer side wall of the first upright post 2, and the outer end of the transmission shaft is provided with a knob 12. When the height is required to be adjusted, the knob 12 is rotated, the knob 12 drives the transmission shaft and the driving bevel gear to rotate, the driving bevel gear is meshed with the driven bevel gear 10 to drive the threaded rod 9 to rotate, and the threaded rod 9 drives the first adjusting arm 4 to ascend or descend, so that the monitoring efficiency of the steel structure strength is improved.

Grooves 13 are respectively formed in the inner side and the outer side of the lower end of the first adjusting arm 4, two rollers 14 are respectively installed in each groove 13 in a rotating mode through a wheel shaft 11, the rollers 14 are in rolling fit with the inner wall of the first upright post 2, the rollers 14 can be driven to synchronously move when the first adjusting arm 4 moves, and the rollers 14 can rotate so that the first adjusting arm 4 can smoothly move.

The middle parts of the first upright post 2 and the second upright post 3 are symmetrically provided with a connecting semi-ring 15, the connecting semi-ring 15 is semicircular, the width of the connecting semi-ring 15 is equal to that of the upright post, and the end face of the connecting semi-ring 15 is provided with a T-shaped slot. The outer wall of first stand 2 and second stand 3 is equipped with horizontal backup pad 16, and the stand on backup pad 16 upper portion is equipped with T shape jack catch 17, and the slot of connecting semi-ring 15 is arranged in backup pad 16 and block on jack catch 17. Be equipped with the bracing piece 18 of slope between the bottom surface of backup pad 16 and the stand, the setting of backup pad 16 can support connecting semi-ring 15, and the joint strength of backup pad 16 can be increased in the setting of bracing piece 18, and the setting of connecting semi-ring 15 can be connected two stands to go on smoothly of monitoring work.

The use process of this embodiment is: the first upright post 2 and the second upright post 3 are placed on the outer side of the steel structure, then the two monitoring parts 4-3 are aligned, the two upright posts are connected through the connecting semi-ring 15, then the infrared emitter 6 is started, if the steel structure deforms, infrared signals sent by the infrared emitter 6 are shielded, and then the infrared receiver 7 transmits shielded information to background personnel, so that the monitoring purpose is achieved. When the height of the monitoring part 4-3 needs to be adjusted, the knob 12 is rotated, the driving bevel gear is driven to rotate through the knob 12, the driving bevel gear drives the threaded rod 9 to rotate through the driven bevel gear 11, and the adjusting arm can be lifted from the inside of the upright post when the threaded rod 9 rotates, so that the height of the monitoring part 4-3 is adjusted.

The foregoing description is only of the preferred embodiments of the utility model and is not intended to limit the scope of the claims, but rather the equivalent structural changes made by the application of the present description and drawings are intended to be included within the scope of the claims.

Claims

1. The utility model provides a steel construction builds intensity monitoring device based on BIM, includes that base, base are last to be equipped with two stands, its characterized in that:

The two upright posts are hollow structures and are respectively inserted with adjusting arms, the top ends of the two adjusting arms extend out of the upright posts and are respectively symmetrically provided with a semi-annular detection part, connecting plates are respectively fixedly connected with the two detection parts, and an infrared emitter and an infrared receiver are respectively arranged on the two connecting plates;

one side be equipped with lift adjustment subassembly between stand and the regulating arm, lift adjustment subassembly includes threaded rod, bevel gear pair and transmission shaft, vertical shaft hole has been seted up to the regulating arm, in the threaded rod rotation installation stand and with the internal thread cooperation in the shaft hole of regulating arm, the transmission shaft runs through the lateral wall of stand and passes through bevel gear pair transmission with the threaded rod.

2. The BIM-based steel structure building strength monitoring device of claim 1, wherein: the upper end of the adjusting arm is provided with a horizontal part, and the detecting part is positioned on the end face of the horizontal part.

3. The BIM-based steel structure building strength monitoring device of claim 1, wherein: the lower extreme of threaded rod passes through the bearing frame and rotates with the bottom plate of stand and be connected, and the bevel gear pair includes driven bevel gear and initiative bevel gear, and driven bevel gear installs in the lower part of threaded rod, and initiative bevel gear installs the inner at the transmission shaft, and the knob is installed to the outer end of transmission shaft.

4. The BIM-based steel structure building strength monitoring device of claim 1, wherein: the lower extreme symmetry of the vertical portion of adjustment arm is seted up flutedly, and the gyro wheel is installed to the recess rotation, and gyro wheel and the inner wall roll connection of stand.

5. The BIM-based steel structure building strength monitoring device of claim 1, wherein: semicircular connecting semi-rings are symmetrically arranged between the two stand columns, T-shaped slots are formed in the end faces of the connecting semi-rings, supporting plates are arranged on the outer walls of the stand columns, T-shaped clamping claws are arranged on the stand columns on the upper portions of the supporting plates, and the slots of the connecting semi-rings are arranged on the supporting plates and clamped on the clamping claws.

6. The BIM-based steel structure building strength monitoring device of claim 1, wherein: the end faces of the two detection parts are respectively provided with a positioning hole, and the positioning holes of the two detection parts are connected through a positioning pin.

7. The BIM-based steel structure building strength monitoring device of claim 1, wherein: the base is provided with mounting feet, and mounting holes are formed in the mounting feet.

8. The BIM-based steel structure building strength monitoring device of claim 1, wherein: the section of the upright post is square or rectangular.

9. The BIM-based steel structure building strength monitoring device of claim 1, wherein: the lower end of the upright post is in a horn mouth shape.