CN214790322U - BIM technology-based large-span bridge construction monitoring and management equipment - Google Patents
BIM technology-based large-span bridge construction monitoring and management equipment Download PDFInfo
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- CN214790322U CN214790322U CN202120042661.6U CN202120042661U CN214790322U CN 214790322 U CN214790322 U CN 214790322U CN 202120042661 U CN202120042661 U CN 202120042661U CN 214790322 U CN214790322 U CN 214790322U
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Abstract
The utility model discloses a large-span bridge construction control management equipment based on BIM technique, including compensating wire subassembly, the compensating wire body that sets up including the level with cup joint the compensating wire rubber coat of compensating wire body outer lane peels off subassembly and contact assembly. The utility model discloses a mutually supporting of peel structure and contact structure, the completion need not to use the cutter can accomplish the effect of peeling off fast, only need take off the outer lane fixed band, peel off the one end of strip and the separation of compensation wire rubber coat after taking off, the user directly places the hand and pulls in handheld port and peel off the strip, the pulling process directly cuts apart the separation with compensation wire rubber coat, can not cause the damage to the compensation wire body, facilitate the use, if when handheld port damages, hand direct contact rubber point increase frictional force pulling can.
Description
Technical Field
The utility model relates to a large-span bridge control technical field specifically is a large-span bridge construction monitoring management equipment based on BIM technique.
Background
BIM is based on three-dimensional digital technology, the engineering data model of various relevant information of the building engineering project is integrated, BIM is the digital expression to engineering project facility entity and functional characteristic, when constructing the large-span bridge, need carry out real time monitoring to whole bridge building based on IMB technique, make things convenient for the builder to handle the accuse to construction progress and construction detail, but traditional bridge construction supervisory equipment if need look over the construction detail long-rangely when using, can only be convenient for more clear of observing through the focus regulation, if the focus regulation can't see clearly, supervisory equipment can only carry out the angular rotation, can't carry out the change of length, for this reason, we provide a large-span bridge construction supervisory equipment based on BIM technique.
SUMMERY OF THE UTILITY MODEL
Therefore, the utility model aims at providing a large-span bridge construction monitoring management equipment based on BIM technique through connection structure and supplementary sliding construction mutually support, reaches the effect that carries out length change when the unable completion of focus adjustment is observed, and such structural design conveniently adjusts the camera and observes the horizontal distance between the building body, is convenient for like this at the focus adjustment when not suitable for more clear observation building body, improves the practicality.
For solving the technical problem, according to the utility model discloses an aspect, the utility model provides a following technical scheme:
a large-span bridge construction monitoring management equipment based on BIM technique includes:
the monitoring assembly comprises a monitoring camera, a protective outer cover arranged on the top surface of the monitoring camera and a connecting seat arranged on the bottom surface of the monitoring camera;
the connecting assembly comprises a concave connecting frame connected to the side wall of the connecting seat, a fixed rod fixed on the top surface of the concave connecting frame, a through hole formed in the side wall of the fixed rod and a locking bolt arranged on the side surface of the through hole;
the auxiliary sliding assembly comprises a sliding frame arranged on the inner side of the concave connecting frame, a rectangular opening formed in the side wall of the sliding frame, a metal rod fixed on the bottom surface of the concave connecting frame and a round rolling rod fixed on the bottom surface of the metal rod;
fixed drive assembly, including connecting the mounting frame, the connection that slide frame is distolateral the mounting frame lateral wall and with the telescopic link of through-hole joint is with connecting the threaded rod of another lateral wall of mounting frame.
As an optimal selection scheme of large-span bridge construction control management equipment based on BIM technique, wherein, the threaded rod is provided with two, and two the threaded rod in the installing frame central line symmetry sets up.
As an optimal scheme of large-span bridge construction control management equipment based on BIM technique, wherein, the locking bolt will telescopic link tail end and dead lever locking.
As an optimal selection scheme of large-span bridge construction control management equipment based on BIM technique, wherein, still include reserve power supply subassembly, reserve power supply subassembly is including placing stand-by power supply body in the installing frame, cup joint the concave type frame of reserve power supply body bottom surface and general concave type frame bottom surface with damping spring that the inboard bottom surface of installing frame is connected.
As an optimal scheme of large-span bridge construction control management equipment based on BIM technique, wherein, damping spring is provided with two, and two damping spring linear distribution.
As an optimal selection scheme of large-span bridge construction control management equipment based on BIM technique, wherein, the flexible length of telescopic link with rectangle open-ended opening length equals.
Compared with the prior art, the utility model discloses the beneficial effect who has is: the effect of changing the length when the observation cannot be finished by adjusting the focal length is achieved by the mutual matching of the connecting structure and the auxiliary sliding structure, the horizontal distance between the camera and the observed building body is convenient to adjust by the structural design, so that the building body can be observed more clearly when the focal length is not suitable to be adjusted, the practicability is improved, when the monitoring camera is used in detail, the concave connecting frame projection connecting seat is connected, when the object cannot be observed clearly when the focal length adjusting range is exceeded, a user controls the telescopic rod to stretch, the fixed rod is driven to move forwards in the stretching process, the circular rolling rod rolls forwards in the rectangular opening during moving, so that the monitoring camera is driven to move forwards, the building details can be observed more clearly, the control progress is controlled, the fixed rod is directly separated from the telescopic rod by the design convenience of the locking bolt, the disassembly and separation are convenient, and the daily assembly and maintenance are convenient, the threaded rod is fixedly used with a building frame of a bridge.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and detailed embodiments, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive labor. Wherein:
fig. 1 is a structural diagram of the large-span bridge construction monitoring and managing device based on the BIM technology;
fig. 2 is a structural diagram of the auxiliary sliding assembly in fig. 1 of the monitoring and management equipment for large-span bridge construction based on the BIM technology of the present invention;
fig. 3 is the utility model relates to a standby power supply's block diagram in large-span bridge construction control management equipment figure 1 based on BIM technique.
In the figure: 100. a monitoring component; 110. a surveillance camera; 120. a protective outer cover; 130. a connecting seat; 200. a connecting assembly; 210. a concave connecting frame; 220. fixing the rod; 230. a through hole; 240. locking the bolt; 300. an auxiliary sliding assembly; 310. a sliding frame; 320. a rectangular opening; 330. a metal rod; 340. a circular rolling rod; 400. fixing the driving component; 410. installing a frame; 420. a telescopic rod; 430. a threaded rod; 500. a standby power supply component; 510. a standby power supply body; 520. a female frame; 530. a shock absorbing spring.
Detailed Description
In order to make the above objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings.
In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be implemented in other ways than those specifically described herein, and one skilled in the art may similarly generalize the present invention without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.
Next, the present invention will be described in detail with reference to the schematic drawings, and in the detailed description of the embodiments of the present invention, for convenience of explanation, the sectional view showing the device structure will not be partially enlarged according to the general scale, and the schematic drawings are only examples, and should not limit the scope of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in the actual fabrication.
In order to make the objects, technical solutions and advantages of the present invention clearer, embodiments of the present invention will be described in further detail below with reference to the accompanying drawings.
The utility model provides a large-span bridge construction monitoring management equipment based on BIM technique, through connection structure and supplementary sliding construction mutually support, reach the effect that carries out the length change when the unable completion of adjustment focus is observed, such structural design conveniently adjusts the camera and observes the horizontal distance between the building body, is convenient for like this when the focus adjustment is not suitable for more clear observation building body, improves the practicality.
Fig. 1-3 show the utility model relates to an overall structure schematic diagram of an embodiment of large-span bridge construction monitoring management equipment based on BIM technique, please refer to fig. 1-3, and the main part of a large-span bridge construction monitoring management equipment based on BIM technique of this embodiment includes monitoring component 100, coupling assembling 200, supplementary sliding assembly 300 and fixed drive assembly 400.
The monitoring component 100 is used for monitoring the construction progress and the details, and is concrete, and the monitoring component 100 includes surveillance camera head 110, sets up at the protection enclosing cover 120 of surveillance camera head 110 top surface and sets up the connecting seat 130 in surveillance camera head 110 bottom surface, and when specifically using, surveillance camera head 110 directly aims at the bridge job site and monitors, and protection enclosing cover 120 prevents to be pounded by the foreign matter bad.
The connecting assembly 200 is used for connecting the camera, and is matched with the auxiliary sliding assembly 300 to complete length change, specifically, the connecting assembly 200 comprises a concave connecting frame 210 connected to the side wall of the connecting seat 130, a fixing rod 220 fixed to the top surface of the concave connecting frame 210, a through hole 230 formed in the side wall of the fixing rod 220 and a locking bolt 240 arranged on the side surface of the through hole 230, when the connecting assembly is specifically used, the fixing rod 220 fixed to the top surface of the concave connecting frame 210 is penetrated and locked with the telescopic rod 420, so that when the monitoring camera 110 is damaged, the locking bolt 240 is directly unscrewed to be detached, and daily maintenance is facilitated.
The auxiliary sliding assembly 300 is used for being matched with the connecting assembly 200 to complete sliding, and the length change effect is achieved, specifically, the auxiliary sliding assembly 300 comprises a sliding frame 310 arranged on the inner side of the concave connecting frame 210, a rectangular opening 320 formed in the side wall of the sliding frame 310, a metal rod 330 fixed on the bottom surface of the concave connecting frame 210 and a circular rolling rod 340 fixed on the bottom surface of the metal rod 330, when the auxiliary sliding assembly is used specifically, the concave connecting frame 210 drives the circular rolling rod 340 to roll in the rectangular opening 320 in the moving process, and therefore the auxiliary monitoring camera 110 moves forwards, and the length change effect is achieved.
Fixed drive assembly 400 is used for installing surveillance camera head 110 and uses and drive surveillance camera head 110 antedisplacement, it is concrete, fixed drive assembly 400 is including connecting at the distolateral installing frame 410 of sliding frame 310, connect at the installing frame 410 lateral wall and with the telescopic link 420 of through-hole 230 joint and connect the threaded rod 430 at another lateral wall of installing frame 410, when specifically using, when exceeding focus adjustment range and can't see clearly the object, user control telescopic link 420 stretches out and draws back this moment, flexible in-process drives dead lever 220 and moves forward, circular rolling rod 340 rolls forward in rectangle opening 320 during the removal, change the horizontal position of surveillance camera head 110 with this drive.
With reference to fig. 1-3, this embodiment's a large-span bridge construction monitoring management equipment based on BIM technique, during the specific use, concave type connection frame 210 projection connecting seat 130 is connected, when exceeding focus adjustment scope and can't see clearly the object, user control telescopic link 420 stretches out and draws back this moment, flexible in-process drives dead lever 220 and moves forward, circular roll pole 340 rolls forward in rectangle opening 320 during the removal, thereby drive surveillance camera head 110 and move forward, be convenient for more clear observation building details, the control progress, design convenience through locking bolt 240 is direct directly separates dead lever 220 is direct with telescopic link 420, be convenient for dismantle the separation, make things convenient for daily equipment maintenance, fixed the use on the building frame through threaded rod 430 and bridge.
In this embodiment, because the stand-by power supply body 510 is installed in the installation frame 410, if the installation frame 410 is shaken by external force, the internal stand-by power supply body 510 easily collides with the installation frame 410, and the healthy use of the battery is affected, therefore, the shock absorption is performed by arranging the stand-by power supply assembly 500, and the damage prevention device is specific, further comprising the stand-by power supply assembly 500, the stand-by power supply assembly 500 comprises the stand-by power supply body 510 placed in the installation frame 410, the concave frame 520 sleeved on the bottom surface of the stand-by power supply body 510, and the shock absorption spring 530 connecting the bottom surface of the concave frame 520 with the inner side bottom surface of the installation frame 410, when the stand-by power supply body 510 is specifically used, when the installation frame 410 is impacted by the outside, the shock absorption spring 530 is located on the bottom surface to absorb shock, the influence caused by shaking of the installation frame 410 on the stand-by power supply body 510 is reduced, and the degree of wear is reduced.
While the invention has been described above with reference to an embodiment, various modifications may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, as long as there is no structural conflict, the various features of the disclosed embodiments of the present invention can be used in any combination with each other, and the non-exhaustive description of these combinations in this specification is merely for the sake of brevity and resource conservation. Therefore, it is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.
Claims (6)
1. The utility model provides a large-span bridge construction monitoring management equipment based on BIM technique which characterized in that includes:
the monitoring assembly (100) comprises a monitoring camera (110), a protective outer cover (120) arranged on the top surface of the monitoring camera (110) and a connecting seat (130) arranged on the bottom surface of the monitoring camera (110);
the connecting assembly (200) comprises a concave connecting frame (210) connected to the side wall of the connecting seat (130), a fixing rod (220) fixed on the top surface of the concave connecting frame (210), a through hole (230) formed in the side wall of the fixing rod (220) and a locking bolt (240) arranged on the side surface of the through hole (230);
the auxiliary sliding assembly (300) comprises a sliding frame (310) arranged on the inner side of the concave connecting frame (210), a rectangular opening (320) formed in the side wall of the sliding frame (310), a metal rod (330) fixed on the bottom surface of the concave connecting frame (210) and a circular rolling rod (340) fixed on the bottom surface of the metal rod (330);
fixed drive assembly (400), including connect in installation frame (410) that slide frame (310) are terminal side, connect in installation frame (410) lateral wall and with telescopic link (420) and the connection of through-hole (230) joint are in the threaded rod (430) of another lateral wall of installation frame (410).
2. The BIM technology-based large-span bridge construction monitoring and management device as claimed in claim 1, wherein there are two threaded rods (430), and the two threaded rods (430) are symmetrically arranged at the central line position of the installation frame (410).
3. The BIM technology-based large-span bridge construction monitoring and management device as claimed in claim 2, wherein the locking bolt (240) locks the tail end of the expansion link (420) with the fixing rod (220).
4. The BIM technology-based large-span bridge construction monitoring and management device according to claim 3, further comprising a standby power supply assembly (500), wherein the standby power supply assembly (500) comprises a standby power supply body (510) placed in the installation frame (410), a concave frame (520) sleeved on the bottom surface of the standby power supply body (510), and a damping spring (530) connecting the bottom surface of the concave frame (520) with the inner bottom surface of the installation frame (410).
5. The BIM technology-based large-span bridge construction monitoring and management device as claimed in claim 4, wherein the damping springs (530) are provided in two numbers, and the two damping springs (530) are linearly distributed.
6. The BIM technology-based large-span bridge construction monitoring and management device as claimed in claim 5, wherein the telescopic rod (420) has a telescopic length equal to the opening length of the rectangular opening (320).
Priority Applications (1)
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CN202120042661.6U CN214790322U (en) | 2021-01-08 | 2021-01-08 | BIM technology-based large-span bridge construction monitoring and management equipment |
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CN202120042661.6U CN214790322U (en) | 2021-01-08 | 2021-01-08 | BIM technology-based large-span bridge construction monitoring and management equipment |
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CN214790322U true CN214790322U (en) | 2021-11-19 |
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CN202120042661.6U Active CN214790322U (en) | 2021-01-08 | 2021-01-08 | BIM technology-based large-span bridge construction monitoring and management equipment |
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2021
- 2021-01-08 CN CN202120042661.6U patent/CN214790322U/en active Active
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