CN213120475U - Building structure displacement testing arrangement based on BIM - Google Patents

Abstract

The utility model discloses a building structure displacement testing device based on BIM, which relates to the technical field of intelligent construction, and comprises a test bench, a vibration mechanism, a lifting mechanism, a displacement mechanism and a testing mechanism, wherein the test bench comprises a bottom plate, a bedplate, a first through ring and a second through ring, the vibration mechanism comprises slide bars, one surface of each slide bar is connected with the lower surface of the bottom plate, the lifting mechanism comprises a first slide cylinder, a first slide rail and a slide seat, the three first slide cylinders are respectively in sliding fit with the three first through rings, the lower surface of the first slide rail is connected with the upper surface of the bedplate, the displacement mechanism comprises a second slide cylinder and a second slide rail, the three second slide cylinders are respectively in sliding fit with the three second through rings, the lower surface of the second slide rail is connected with the upper surface of the bedplate, the testing mechanism comprises a fixed plate, the upper surface of the slide seat is connected with the lower surface of the fixed plate, in the utility, the second sliding barrel is in sliding fit with the second through ring and respectively drives the displacement mechanism and the testing mechanism to move up and down.

Description

Building structure displacement testing arrangement based on BIM

Technical Field

The utility model relates to an intelligence construction technical field specifically is a building structure displacement testing arrangement based on BIM.

Background

Building structure displacement test is one of the main project of managing, and in the building field, all countries in the world have corresponding regulation to the displacement control in the high-rise building structure, now, in carrying out building structure displacement test, need use building structure displacement testing arrangement, along with the development of building trade and the progress of science and technology, the different types of building structure displacement testing arrangement that is used for has appeared in the market, mainly introduces a building structure displacement testing arrangement based on BIM here.

The existing building structure displacement testing device based on the BIM has the problems that the testing function is incomplete in the vertical direction, a testing mechanism is too simple and the like, and therefore the building structure displacement testing device based on the BIM is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a building structure displacement testing arrangement based on BIM to solve test function imperfection, accredited testing organization too simple scheduling problem in the vertical direction that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

the utility model provides a building structure displacement testing arrangement based on BIM, includes testboard, vibration mechanism, elevating system, displacement mechanism and accredited testing organization, the testboard includes bottom plate, platen, first logical ring sum second logical ring, vibration mechanism includes the slide bar, four slide bar surfaces all are connected with the bottom plate lower surface, elevating system includes first slide cartridge, first slide rail and slide, three first slide cartridge respectively with three first logical ring sliding fit, first slide rail lower surface and platen upper surface connection, displacement mechanism includes second slide cartridge and second slide rail, three second slide cartridge respectively with three second logical ring sliding fit, second slide rail lower surface and platen upper surface connection, accredited testing organization includes the fixed plate, the slide upper surface is connected with the fixed plate lower surface.

Preferably, the test bench further comprises a connecting plate, the connecting plate is arranged between the bottom plate and the bedplate, one surfaces of the three first through rings are respectively connected with the lower surface of the bedplate, the three second through rings are arranged on the lower surface of the bedplate, and the connecting plate mainly plays a role in connecting the bottom plate and the bedplate.

Preferably, the vibration mechanism further comprises sliding columns, springs and supporting discs, through holes are formed in the four sliding columns, the four sliding rods are in sliding fit with the four through holes respectively, the four springs are arranged between the four supporting discs and the bottom plate respectively, the four supporting discs are installed on the lower surfaces of the four sliding columns respectively, and the springs can be adjusted elastically.

Preferably, elevating system still includes the stopper, three first smooth section of thick bamboo is all installed in first slide rail lower surface, slide and first slide rail sliding fit, two stoppers are all installed in first slide rail upper surface, and the stopper can prevent that the slide from sliding excessively.

Preferably, displacement mechanism still includes slide, revolving stage and places the platform, slide and second slide rail sliding fit, three second slide cartridge is all installed in second slide rail lower surface, revolving stage one end and slide normal running fit, the revolving stage other end with place a surface connection, place and to place the interior main test model that can place of platform.

Preferably, accredited testing organization still includes displacement sensor, spliced pole and receiver, a displacement sensor surface and fixed plate upper surface connection, the spliced pole sets up between displacement sensor and receiver, a receiver surface and fixed plate upper surface connection, displacement sensor can carry out whole test task.

Compared with the prior art, the beneficial effects of the utility model are that:

the first sliding barrel is in sliding fit with the first through ring, the second sliding barrel is in sliding fit with the second through ring, the displacement mechanism and the testing mechanism are driven to move up and down respectively, the sliding seat is in sliding fit with the first sliding rail, the sliding plate is in sliding fit with the second sliding rail, the displacement mechanism and the testing mechanism are driven to perform sliding testing in the same direction respectively, the sliding rod is in sliding fit with the sliding column, and the elastic vibration effect of the spring is added, so that the whole testing result is closer to reality.

Drawings

Fig. 1 is a schematic overall structure diagram of a building structure displacement testing device based on BIM.

Fig. 2 is a schematic front view of a building structure displacement testing device based on BIM.

Fig. 3 is a schematic top view of a building structure displacement testing device based on BIM.

Fig. 4 is a schematic cross-sectional structure view of a building structure displacement testing device based on BIM at a-a in fig. 3.

In the figure: 100. a test bench; 110. a base plate; 120. a platen; 130. a connecting plate; 140. a first through ring; 150. a second through ring; 200. a vibration mechanism; 210. a traveler; 220. a slide bar; 230. a spring; 240. supporting a disc; 300. a lifting mechanism; 310. a first slide drum; 320. a first slide rail; 330. a slide base; 340. a limiting block; 400. a displacement mechanism; 410. a second slide drum; 420. a second slide rail; 430. a slide plate; 440. a rotating table; 450. a placing table; 500. a testing mechanism; 510. a fixing plate; 520. a displacement sensor; 530. connecting columns; 540. a receiver.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 to 4, in an embodiment of the present invention, a building structure displacement testing apparatus based on BIM includes a testing table 100, a vibration mechanism 200, a lifting mechanism 300, a displacement mechanism 400 and a testing mechanism 500, the testing table 100 includes a bottom plate 110, a bedplate 120, a first through ring 140 and a second through ring 150, the vibration mechanism 200 includes slide bars 220, one surface of each of the four slide bars 220 is connected to a lower surface of the bottom plate 110, the lifting mechanism 300 includes a first slide cylinder 310, a first slide rail 320 and a slide carriage 330, the three first slide cylinders 310 are respectively in sliding fit with the three first through rings 140, the lower surface of the first slide rail 320 is connected to an upper surface of the bedplate 120, the displacement mechanism 400 includes a second slide cylinder 410 and a second slide rail 420, the three second slide cylinders 410 are respectively in sliding fit with the three second through rings 150, the lower surface of the second slide rail 420 is connected to the upper surface of the bedplate 120, the testing mechanism 500 includes, the upper surface of the sliding base 330 is connected with the lower surface of the fixing plate 510.

Preferably, the test bench 100 further comprises a connecting plate 130, the connecting plate 130 is disposed between the bottom plate 110 and the platen 120, one surface of each of the three first through-rings 140 is connected to the lower surface of the platen 120, the three second through-rings 150 are mounted on the lower surface of the platen 120, and the connecting plate 130 mainly serves to connect the bottom plate 110 and the platen 120.

Preferably, the vibration mechanism 200 further includes sliding columns 210, springs 230, and supporting discs 240, through holes are disposed inside the four sliding columns 210, the four sliding rods 220 are respectively in sliding fit with the four through holes, the four springs are respectively disposed between the four supporting discs 240 and the bottom plate 110, the four supporting discs 240 are respectively mounted on the lower surfaces of the four sliding columns 210, and the springs 230 can be elastically adjusted.

Preferably, the lifting mechanism 300 further includes a limiting block 340, the three first sliding barrels 310 are all mounted on the lower surface of the first sliding rail 320, the sliding base 330 is in sliding fit with the first sliding rail 320, the two limiting blocks 340 are both mounted on the upper surface of the first sliding rail 320, and the limiting blocks 340 can prevent the sliding base 330 from sliding excessively.

Preferably, the displacement mechanism 400 further includes a sliding plate 430, a rotating plate 440 and a placing table 450, the sliding plate 430 is slidably engaged with the second sliding rail 420, the three second sliding drums 410 are all mounted on the lower surface of the second sliding rail 420, one end of the rotating plate 440 is rotatably engaged with the sliding plate 430, the other end of the rotating plate 440 is connected with one surface of the placing table 450, and the main test model can be placed in the placing table 450.

Preferably, the testing mechanism 500 further includes a displacement sensor 520, a connection column 530 and a receiver 540, wherein a surface of the displacement sensor 520 is connected to an upper surface of the fixing plate 510, the connection column 530 is disposed between the displacement sensor 520 and the receiver 540, a surface of the receiver 540 is connected to an upper surface of the fixing plate 510, and the displacement sensor 520 can perform all testing tasks.

The utility model discloses a theory of operation is:

the first sliding barrel 310 is in sliding fit with the first through ring 140, the second sliding barrel 410 is in sliding fit with the second through ring 150, and respectively drives the displacement mechanism 400 and the testing mechanism 500 to move up and down, the sliding seat 330 is in sliding fit with the first sliding rail 320, the sliding plate 430 is in sliding fit with the second sliding rail 420, and respectively drives the displacement mechanism 400 and the testing mechanism 500 to perform sliding testing in the same direction, and the sliding rod 220 is in sliding fit with the sliding column 210, and the elastic vibration effect of the spring 230 is added, so that the whole testing result is closer to reality.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides a building structure displacement testing arrangement based on BIM, includes testboard (100), vibration mechanism (200), elevating system (300), displacement mechanism (400) and accredited testing organization (500), its characterized in that: the test bench (100) comprises a bottom plate (110), a bedplate (120), first through rings (140) and second through rings (150), the vibration mechanism (200) comprises slide bars (220), one surfaces of the four slide bars (220) are connected with the lower surface of the bottom plate (110), the lifting mechanism (300) comprises first slide cylinders (310), first slide rails (320) and slide seats (330), the three first slide cylinders (310) are respectively in sliding fit with the three first through rings (140), the lower surfaces of the first slide rails (320) are connected with the upper surface of the bedplate (120), the displacement mechanism (400) comprises second slide cylinders (410) and second slide rails (420), the three second slide cylinders (410) are respectively in sliding fit with the three second through rings (150), the lower surfaces of the second slide rails (420) are connected with the upper surface of the bedplate (120), the test mechanism (500) comprises a fixing plate (510), the upper surface of the sliding seat (330) is connected with the lower surface of the fixing plate (510).

2. The BIM-based building structure displacement testing device of claim 1, wherein: the test bench (100) further comprises a connecting plate (130), the connecting plate (130) is arranged between the bottom plate (110) and the bedplate (120), one surfaces of the three first through rings (140) are respectively connected with the lower surface of the bedplate (120), and the three second through rings (150) are all arranged on the lower surface of the bedplate (120).

3. The BIM-based building structure displacement testing device of claim 1, wherein: the vibrating mechanism (200) further comprises sliding columns (210), springs (230) and supporting discs (240), through holes are formed in the four sliding columns (210), the four sliding rods (220) are in sliding fit with the four through holes respectively, the four springs (230) are arranged between the four supporting discs (240) and the bottom plate (110) respectively, and the four supporting discs (240) are installed on the lower surfaces of the four sliding columns (210) respectively.

4. The BIM-based building structure displacement testing device of claim 1, wherein: the lifting mechanism (300) further comprises a limiting block (340), the three first sliding barrels (310) are mounted on the lower surface of the first sliding rail (320), the sliding seat (330) is in sliding fit with the first sliding rail (320), and the two limiting blocks (340) are mounted on the upper surface of the first sliding rail (320).

5. The BIM-based building structure displacement testing device of claim 1, wherein: the displacement mechanism (400) further comprises a sliding plate (430), a rotating table (440) and a placing table (450), the sliding plate (430) is in sliding fit with a second sliding rail (420), the three second sliding barrels (410) are mounted on the lower surface of the second sliding rail (420), one end of the rotating table (440) is in rotating fit with the sliding plate (430), and the other end of the rotating table (440) is connected with one surface of the placing table (450).

6. The BIM-based building structure displacement testing device of claim 1, wherein: the testing mechanism (500) further comprises a displacement sensor (520), a connecting column (530) and a receiver (540), one surface of the displacement sensor (520) is connected with the upper surface of the fixing plate (510), the connecting column (530) is arranged between the displacement sensor (520) and the receiver (540), and one surface of the receiver (540) is connected with the upper surface of the fixing plate (510).

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