CN111337006A - Verticality detection device for building engineering - Google Patents

Abstract

The invention discloses a perpendicularity detection device for building engineering, which comprises a supporting plate, wherein a groove is formed in one side of the supporting plate, a moving mechanism is installed above the supporting plate, and a measuring mechanism is installed above the moving mechanism. The invention has high automation degree, an operator can carry out detection work without too much work experience during use, the detected numerical value can be determined through the matching of the pointer and the scale marks, the accuracy of the result is ensured, the height can be adjusted to detect different positions of a building object, and the detection work efficiency is improved.

Description

Verticality detection device for building engineering

Technical Field

The invention belongs to the technical field of building engineering detection instruments, and particularly relates to a perpendicularity detection device for building engineering.

Background

Along with the continuous acceleration of the development process of urbanization, the number of construction projects in cities is increasing, the construction measurement in the construction projects also arouses the high attention of the majority of construction units, and in the daily construction process, perpendicularity detection is often required to be carried out on buildings, structures and the like, so that the construction safety and the construction quality are ensured. The existing technology usually adopts the mode of matching the verticality detection ruler or the plumb bob with the plumb line when detecting the verticality of the building object, although the detection mode is simple and easy to operate, the result detected has certain relevance with the working experience of operators, the error is easy to generate, the result is inaccurate, sometimes the different height positions of the building object need to be detected, the existing detection mode needs to be realized only by using other auxiliary tools, the application range has certain limitation, and the detection work efficiency is reduced.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, and provides a perpendicularity detection device for building engineering, which has high automation degree, can be used for detecting without too much work experience of operators, can determine a detected numerical value through the matching of a pointer and a scale mark, ensures the accuracy of a result, can adjust the height to detect different positions of a building object, and thus improves the detection work efficiency.

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

the utility model provides a straightness detection device that hangs down for building engineering, includes the backup pad, backup pad one side is seted up flutedly, moving mechanism is installed to the backup pad top, moving mechanism installs measuring mechanism in the top, and moving mechanism can drive measuring mechanism and remove, and measuring mechanism can adjust the height that detects, detects building object different positions to the work efficiency who detects has been improved.

Preferably, the moving mechanism comprises an L-shaped plate, a rack, a vertical plate and a first driving motor, the L-shaped plate is arranged above the supporting plate, the surface of the L-shaped plate is provided with scale marks, two sides of the bottom of the L-shaped plate are provided with first guide blocks, two first supporting seats are arranged on two sides of the top of the supporting plate, the number of the first supporting seats on the same side of the supporting plate is two, a first guide rod is arranged between the two first supporting seats, the end part of the first guide rod is arranged on the first supporting seat, the first guide block is arranged on the first guide rod, the L-shaped plate is driven to slide along the first guide rod through the first guide block, the vertical plate is arranged at the bottom of the L-shaped plate, the bottom end of the vertical plate extends into the first groove, the first driving motor is arranged at one side of the vertical plate, the end part of the output shaft of the first driving, drive gear through a driving motor and rotate, the gear and the meshing of rack pass through the riser and drive the motion of L template on first guide arm.

Preferably, the measuring mechanism comprises a support, a stand column, a second driving motor and a first lead screw, the support is mounted at the top of the L-shaped plate, the stand column is hinged to one side of the support through a rotating shaft, a through groove is formed in the stand column, a pointer is mounted at the bottom of the stand column and is located right above the scale mark, a bearing seat is mounted in the middle of the upper portion of the pointer and is arranged in the through groove, the second driving motor is mounted at the top of the stand column, a first lead screw is mounted on an output shaft of the second driving motor, the first lead screw is located in the through groove, the bottom of the first lead screw is mounted on the bearing seat, a first sliding block is mounted on the first lead screw, a threaded hole matched with the first lead screw is formed in the first sliding block, a sliding groove is formed in one side of the stand column and is communicated, the end part of the measuring block and the end part of the L-shaped plate are on the same vertical plane, a first telescopic rod is installed on the side wall of the L-shaped plate on one side of the stand column, the number of the first telescopic rods is two, the first telescopic rods are located on the upper side and the lower side of the rotating shaft, the measuring mechanism moves towards the direction of the building object to be detected through the moving mechanism, the L-shaped plate is in contact with the building object, at the moment, if the measuring block is in contact with the building object, the building object is vertical, if the measuring block is not in contact with the building object, the building object is not vertical, the first lead screw is driven to rotate through the second driving motor, the first slide block on the first lead screw drives the measuring block to move up and down through the connecting rod, different positions of the building object are detected, after the positions are adjusted, the first telescopic rod close to the measuring block is in working extension, the pointer rotates along with the rotation, and the offset angle is determined through the numerical value on the scale mark indicated by the pointer; when the measuring block contacts the L-shaped plate of the building object and does not contact the building object, the upright post and the pointer rotate in opposite directions, the offset angle is determined according to the numerical value on the scale mark indicated by the pointer, and the building objects inclined at different angles can be measured through the measuring mechanism, so that the application range of the device is expanded, and the working efficiency is improved.

Preferably, a leveling mechanism is arranged below the supporting plate, the leveling mechanism comprises a bottom plate, springs, first adjusting mechanisms, a connecting plate and second adjusting mechanisms, the springs are mounted on the bottom plate, the number of the springs is four, the springs are arranged at four end parts of the bottom plate, the top parts of the springs are connected with the bottom part of the supporting plate, two first adjusting mechanisms are mounted on one side of the bottom plate, the two first adjusting mechanisms are symmetrically distributed, each first adjusting mechanism comprises two second supporting seats, a second lead screw, a second sliding block and a first rocking handle, the two second supporting seats are fixedly mounted on the bottom plate, the second lead screw is rotatably mounted on the two second supporting seats, one end of the second lead screw extends to the outer side of the second supporting seat, the first rocking handle is fixedly mounted at the end part of the second lead screw, the second sliding block is mounted on the second lead screw, and a threaded hole matched with the second lead screw is formed in the second sliding, the two ends of the other side of the bottom plate are fixedly provided with third supporting seats, a second guide rod is arranged between the two third supporting seats, the two ends of the second guide rod are respectively and fixedly arranged on the two third supporting seats, the second guide rod is provided with two second guide blocks, the second guide blocks are provided with through holes matched with the second guide rods, a connecting plate is arranged between the second guide blocks and the second sliding blocks, the two ends of the connecting plate are respectively fixed at the tops of the second guide blocks and the second sliding blocks, the second guide blocks and the second sliding blocks are in one-to-one correspondence, the connecting plate is provided with two second adjusting mechanisms which are symmetrically distributed, each second adjusting mechanism comprises two fourth supporting seats, a third screw rod, a third sliding block and a second rocking handle, the two fourth supporting seats are fixedly arranged on the connecting plate, and the third screw rod is rotatably arranged on the two fourth supporting seats, one end of the third screw rod extends to the outer side of the fourth supporting seat, the second rocking handle is fixedly arranged at the end part of the third screw rod, the third sliding block is arranged on the third screw rod, a threaded hole matched with the third screw rod is formed in the third sliding block, a second telescopic rod is fixedly arranged at the top of the third sliding block, the second screw rod is rocked by the first rocking handle to rotate, the second sliding block is driven to move along the second screw rod, the second sliding block drives the second guide block to move along the second guide rod through the connecting plate, the second adjusting mechanism arranged on the connecting plate moves along with the second guide rod, the third screw rod is rocked by the second rocking handle to rotate, the third sliding block is driven to move along the third screw rod, the second telescopic rod moves along with the third guide rod, the supporting plate is jacked up through the extension of the second telescopic rod, so that the supporting plate is in a balanced state, and the verticality detection device meets, the support plate can be jacked up transversely and longitudinally through the leveling mechanism, so that the support plate is measured after being in a balanced state, the accuracy of a measuring result is ensured, and the application range is expanded.

Preferably, second telescopic link top fixed mounting has the roof, the roof is cylindricly, has increased the area of contact of second telescopic link with the backup pad through the roof, and the second telescopic link of being convenient for has improved stability when upwards jack-up.

Preferably, the walking wheels are fixedly mounted below the bottom plate, the handrail frame is fixed on one side of the bottom plate and pushes the handrail frame to enable the device to move integrally through the walking wheels, so that the whole position of the device can be adjusted conveniently, and the working efficiency is improved.

Preferably, the supporting plate is provided with two gradienters, the two gradienters are arranged on two sides of the supporting plate, and whether the supporting plate reaches a horizontal state or not can be observed in real time when the leveling mechanism adjusts the supporting plate, so that purposeful adjustment is carried out, and the working efficiency is improved.

The invention has the beneficial effects that:

1) this device degree of automation is high, and operating personnel need not too many work experience during the use alright detect work, can confirm the numerical value that detects through the cooperation of pointer and scale mark, has guaranteed the accuracy of result, can adjust the height and detect building object different positions to the work efficiency who detects has been improved.

2) The support plate can be transversely and longitudinally jacked up by arranging the leveling mechanism, so that the support plate is in a balanced state and then is measured, the accuracy of a measuring result is ensured, and the application range is expanded.

3) Second telescopic link top fixed mounting has the roof, the roof is cylindricly, has increased the area of contact of second telescopic link with the backup pad through the roof, and the second telescopic link of being convenient for has improved stability when upwards jack-up.

4) The walking wheels are fixedly mounted below the bottom plate, the handrail frame is fixed on one side of the bottom plate and is pushed to enable the device to move integrally through the walking wheels, so that the whole position of the device can be adjusted conveniently, and the working efficiency is improved.

5) The leveling mechanism is provided with two leveling instruments, the two leveling instruments are arranged on two sides of the supporting plate, and whether the supporting plate reaches a horizontal state or not can be observed in real time when the leveling mechanism adjusts the supporting plate through the leveling instruments, so that purposeful adjustment is carried out, and the working efficiency is improved.

Drawings

FIG. 1 is a schematic structural diagram of a perpendicularity detecting device for construction engineering.

Fig. 2 is a schematic structural diagram of a moving mechanism in the perpendicularity detecting device for construction engineering of the present invention.

Fig. 3 is a schematic view of the connection of a first driving motor, a gear and a rack in the perpendicularity detection device for construction engineering.

Fig. 4 is a schematic structural view of a measuring mechanism in the perpendicularity detecting device for construction engineering of the present invention.

FIG. 5 is a schematic diagram of the internal structure of a vertical column in the perpendicularity detecting apparatus for construction engineering according to the present invention.

FIG. 6 is a schematic structural diagram of a leveling mechanism in the perpendicularity detecting device for construction engineering.

In the figure: 1. a support plate; 11. a groove; 2. a moving mechanism; 201. an L-shaped plate; 202. a first support base; 203. a first guide bar; 204. a first guide block; 205. a rack; 206. a vertical plate; 207. a first drive motor; 208. a gear; 209. scale lines; 3. a measuring mechanism; 301. a support; 302. a rotating shaft; 303. a column; 304. a pointer; 305. a first telescopic rod; 306. a chute; 307. a second drive motor; 308. a connecting rod; 309. a measuring block; 310. a through groove; 311. a bearing seat; 312. a first slider; 313. a first lead screw; 4. a leveling mechanism; 401. a base plate; 402. a spring; 403. a second support seat; 404. a second lead screw; 405. a second slider; 406. a first rocking handle; 407. a third support seat; 408. a second guide bar; 409. a second guide block; 410. a connecting plate; 411. a fourth supporting seat; 412. a third lead screw; 413. a third slider; 414. a second telescopic rod; 415. a second rocking handle; 416. a top plate; 417. a level gauge; 5. a traveling wheel; 6. an armrest frame.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described below with reference to fig. 1 to 6, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, are merely for convenience of description of the present invention, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

The utility model provides a straightness detection device that hangs down for building engineering, includes backup pad 1, 1 one side of backup pad is seted up flutedly 11, moving mechanism 2 is installed to 1 top of backup pad, measuring mechanism 3 is installed to 2 tops of moving mechanism, and moving mechanism 2 can drive measuring mechanism 3 and remove, and measuring mechanism 3 can adjust the height that detects, detects building object different positions to the work efficiency who detects has been improved.

The moving mechanism 2 comprises an L-shaped plate 201, a rack 205, a vertical plate 206 and a first driving motor 207, wherein the L-shaped plate 201 is arranged above a support plate 1, the surface of the L-shaped plate 201 is provided with scale marks 209, two sides of the bottom of the L-shaped plate 201 are provided with first guide blocks 204, two sides of the top of the support plate 1 are provided with first support seats 202, the number of the first support seats 202 on the same side of the support plate 1 is two, a first guide rod 203 is arranged between the two first support seats 202, the end part of the first guide rod 203 is arranged on the first support seat 202, the first guide block 204 is arranged on the first guide rod 203, the L-shaped plate 201 is driven by the first guide block 204 to slide along the first guide rod 203, the vertical plate 206 is arranged at the bottom of the L-shaped plate 201, the bottom end of the vertical plate 206 extends into the first groove 11, the first driving motor 207 is arranged at one side of the vertical plate 206, a rack 205 is installed on one side wall of the groove 11, the gear 208 is meshed with the rack 205, the gear 208 is driven to rotate by the first driving motor 207, and the gear 208 is meshed with the rack 205 and drives the L-shaped plate 201 to move on the first guide rod 203 by the vertical plate 206.

The measuring mechanism 3 comprises a support 301, a vertical column 303, a second driving motor 307 and a first lead screw 313, the support 301 is installed at the top of the L-shaped plate 201, the vertical column 303 is hinged to one side of the support 301 through a rotating shaft 302, a through groove 310 is formed in the vertical column 303, a pointer 304 is installed at the bottom of the vertical column 303, the pointer 304 is located right above the scale mark 209, a bearing seat 311 is installed in the middle of the upper portion of the pointer 304, the bearing seat 311 is arranged in the through groove 310, the second driving motor 307 is installed at the top of the vertical column 303, a first lead screw 313 is installed on an output shaft of the second driving motor 307, the first lead screw 313 is located in the through groove 310, the bottom of the first lead screw 313 is installed on the bearing seat 311, a first sliding block 312 is installed on the first lead screw 313, a threaded hole matched with the first lead screw 313 is formed in the, a connecting rod 308 is installed on one side, facing the sliding chute, of the first sliding block 312, a measuring block 309 is installed at the end of the connecting rod 308, the end of the measuring block 309 and the end of the L-shaped plate 201 are on the same vertical plane, a first telescopic rod 305 is installed on the side wall of the L-shaped plate 201 on one side of the upright column 303, the number of the first telescopic rods 305 is two and is located on the upper side and the lower side of the rotating shaft 302, the measuring mechanism 3 moves towards the direction of the building object to be detected through the moving mechanism 2, the L-shaped plate 201 is in contact with the building object, at the moment, if the measuring block 309 is in contact with the building object, the vertical direction is indicated, if the measuring block 309 is not in contact with the building object, the building object is not vertical, the first guide screw 313 is driven to rotate through the second driving motor 307, the first sliding block 312 on the first guide screw 313, after the position is adjusted, a first telescopic rod 305 close to the measuring block extends to contact with the upright post 303 until the measuring block 309 contacts with a building object, the upright post 303 rotates along the support 301 through the rotating shaft 302, the pointer 304 rotates along with the upright post, and the offset angle is determined through the numerical value on the scale mark 209 indicated by the pointer 304; when the measuring block 309 contacts the L-shaped plate 201 of the building object and does not contact the building object, the upright post 303 and the pointer 304 rotate in opposite directions, the offset angle is determined according to the numerical value on the scale mark 209 indicated by the pointer 304, building objects inclined at different angles can be measured through the measuring mechanism 3, the application range of the device is expanded, and the working efficiency is improved.

The supporting plate 1 below is equipped with leveling mechanism 4, leveling mechanism 4 includes bottom plate 401, spring 402, first adjustment mechanism, connecting plate 410, second adjustment mechanism, bottom plate 401 below fixed mounting has walking wheel 5, bottom plate 401 one side is fixed with handrail frame 6, promotes handrail frame 6 and makes the device drive the moving as a whole through walking wheel 5 to the adjustment of the device overall position of being convenient for has improved the efficiency of work, spring 402 installs on bottom plate 401, the quantity of spring 402 is four and sets up in four tip of bottom plate 401, the top and the supporting plate 1 bottom of spring 402 are connected, two first adjustment mechanism are installed to bottom plate 401 one side, two first adjustment mechanism symmetric distributions, first adjustment mechanism includes two second supporting seats 403, second lead screw 404, second slider 405, first rocking handle 406, two second supporting seats 403 fixed mounting are on bottom plate 401, the second screw rod 404 is rotatably mounted on the two second supporting seats 403, one end of the second screw rod 404 extends to the outer side of the second supporting seat 403, the first rocking handle 406 is fixedly mounted at the end of the second screw rod 404, the second sliding block 405 is mounted on the second screw rod 404, a threaded hole matched with the second screw rod 404 is formed in the second sliding block 405, third supporting seats 407 are fixedly arranged at two ends of the other side of the bottom plate 401, a second guide rod 408 is arranged between the two third supporting seats 407, two ends of the second guide rod 408 are respectively fixedly mounted on the two third supporting seats 407, two second guide blocks 409 are arranged on the second guide rod 408, through holes matched with the second guide rod 408 are formed in the second guide blocks 409, a connecting plate 410 is arranged between the second guide blocks and the second sliding block 405, two ends of the connecting plate 410 are respectively fixed at the tops of the second guide blocks 409 and the second sliding block 405, the second guide blocks 409 and the second sliding blocks 405 are in one-to-one correspondence, two second adjusting mechanisms are arranged on the connecting plate 410 and are symmetrically distributed, each second adjusting mechanism comprises two fourth supporting seats 411, a third lead screw 412, a third sliding block 413 and a second rocking handle 415, the two fourth supporting seats 411 are fixedly arranged on the connecting plate 410, the third lead screw 412 is rotatably arranged on the two fourth supporting seats 411, one end of the third lead screw 412 extends to the outer side of the fourth supporting seat 411, the second rocking handle 415 is fixedly arranged at the end part of the third lead screw 412, the third sliding block 413 is arranged on the third lead screw 412, a threaded hole matched with the third lead screw 412 is formed in the third sliding block 413, a second telescopic rod 414 is fixedly arranged at the top of the third sliding block 413, a top plate 416 is fixedly arranged at the top of the second telescopic rod 414, and the top plate 416 is cylindrical, the contact area between the second telescopic rod 414 and the support plate 1 is increased through the top plate 416, so that the stability is improved while the second telescopic rod 414 is jacked upwards.

The second lead screw 404 is shaken to rotate through the first rocking handle 406 to drive the second slide block 405 to move along the second lead screw 404, the second slide block 405 drives the second guide block 409 to move along the second guide rod 408 through the connecting plate 410, the second adjusting mechanism arranged on the connecting plate 410 moves along with the second guide block, the third lead screw 412 is shaken to rotate through the second rocking handle 415 to drive the third slide block 413 to move along the third lead screw 412, the second telescopic rod 414 moves along with the second guide block, the support plate 1 is jacked up through the extension of the second telescopic rod 414 to enable the support plate 1 to reach a balanced state, errors occur in a measurement result due to the fact that the verticality detection device meets the condition of uneven ground when in use, the support plate 1 can be jacked up transversely and longitudinally through the leveling mechanism 4 to enable the support plate 1 to be in the balanced state, accuracy of the measurement result is guaranteed, the application range is expanded, the level gauge 417 is installed on the support plate 1, the quantity of the gradienter 417 is two and is installed on both sides of the supporting plate 1, the gradienter 417 is a mature product sold in the market, for example, a T-shaped gradienter with the model of 600 series, and whether the supporting plate 1 reaches the horizontal state can be observed in real time when the leveling mechanism 4 adjusts the supporting plate 1 through the gradienter 417, so that purposeful adjustment is carried out, and the working efficiency is improved.

A straightness detection device that hangs down for building engineering, its working process as follows: the handrail frame is pushed to move the device to one side of a building to be measured through the travelling wheels, the first rocking handle is rocked to enable the second lead screw to rotate, the second sliding block is driven to move along the second lead screw, the second sliding block drives the second guide block to move along the second guide rod through the connecting plate, the second adjusting mechanism arranged on the connecting plate moves along the second guide rod, the second rocking handle is rocked to enable the third lead screw to rotate, the third sliding block is driven to move along the third lead screw, the second telescopic rod moves along with the third lead screw, the supporting plate is jacked up through the extension of the second telescopic rod to enable the supporting plate to reach a balanced state, the gear is driven to rotate through the first driving motor, the gear and the rack are meshed to drive the L-shaped plate to move on the first guide rod through the vertical plate, the L-shaped plate is contacted with the building object, at the moment, if the measuring block is contacted with the building object, the first lead screw is driven to rotate by the second driving motor, the first slide block on the first lead screw drives the measuring block to move up and down through the connecting rod, different positions of the building object are detected, after the positions are adjusted, a first telescopic rod close to the measuring block extends to be in contact with the stand column until the measuring block is in contact with the building object, the stand column rotates along the support through the rotating shaft, the pointer rotates along with the stand column, and the offset angle is determined through the numerical value on the scale mark indicated by the pointer; when the measuring block is contacted with the L-shaped plate of the building object and is not contacted with the building object, the upright post and the pointer rotate in opposite directions, and the offset angle is determined according to the numerical value on the scale mark indicated by the pointer.

The foregoing is merely exemplary and illustrative of the present invention and various modifications, additions and substitutions may be made by those skilled in the art to the specific embodiments described without departing from the scope of the present invention as defined in the accompanying claims.

Claims (9)

1. The utility model provides a straightness detection device that hangs down for building engineering, includes the backup pad, its characterized in that, backup pad one side is equipped with the recess, moving mechanism is installed to the backup pad top, measuring mechanism is installed to the moving mechanism top.

2. The perpendicularity detecting device for building engineering according to claim 1, wherein the moving mechanism comprises an L-shaped plate, a rack, a vertical plate and a first driving motor, the L-shaped plate is arranged above the supporting plate, the surface of the L-shaped plate is provided with scale marks, first guide blocks are arranged on two sides of the bottom of the L-shaped plate, first supporting seats are arranged on two sides of the top of the supporting plate, two first supporting seats are arranged on the same side of the supporting plate, a first guide rod is arranged between the two first supporting seats, the end portion of the first guide rod is arranged on the first supporting seat, the first guide block is arranged on the first guide rod, the vertical plate is arranged at the bottom of the L-shaped plate, the bottom end of the vertical plate extends into the first groove, the first driving motor is arranged on one side of the vertical plate, the end portion of the output shaft of the first driving motor penetrates through the vertical plate, the gear is meshed with the rack.

3. The perpendicularity detecting device for building engineering according to claim 2, wherein the measuring mechanism comprises a support, a stand column, a second driving motor and a first lead screw, the support is mounted at the top of the L-shaped plate, the stand column is hinged at one side of the support through a rotating shaft, a through groove is formed in the stand column, a pointer is mounted at the bottom of the stand column and is located right above a scale mark, a bearing seat is mounted in the middle above the pointer and is arranged inside the through groove, the second driving motor is mounted at the top of the stand column, the first lead screw is mounted on an output shaft of the second driving motor, the first lead screw is located inside the through groove, the bottom of the first lead screw is mounted on the bearing seat, a first sliding block is mounted on the first lead screw, a threaded hole matched with the first lead screw is formed in the first sliding block, the chute is linked together with leading to the groove, the connecting rod is installed towards one side of chute to first slider, and the measuring block is installed to the connecting rod tip, the tip of measuring block tip and L template is on same vertical plane, install first telescopic link on the L template lateral wall of stand one side, the quantity of first telescopic link is two and is located the upper and lower both sides of pivot.

4. The verticality detection device for construction engineering according to claim 1, wherein a leveling mechanism is disposed below the supporting plate, the leveling mechanism includes a bottom plate, a spring, a first adjusting mechanism, a connecting plate, and a second adjusting mechanism, the spring is mounted on the bottom plate, the number of the springs is four, and the springs are disposed at four ends of the bottom plate, the top of the spring is connected to the bottom of the supporting plate, two first adjusting mechanisms are mounted at one side of the bottom plate, the two first adjusting mechanisms are symmetrically distributed, the first adjusting mechanism includes two second supporting seats, a second lead screw, a second slider, and a first rocking handle, the two second supporting seats are fixedly mounted on the bottom plate, the second lead screw is rotatably mounted on the two second supporting seats, one end of the second lead screw extends to the outer side of the second supporting seats, the first rocking handle is fixedly mounted at the end of the second lead screw, the second sliding block is arranged on a second screw rod, a threaded hole matched with the second screw rod is arranged on the second sliding block, third supporting seats are fixedly arranged at two ends of the other side of the bottom plate, a second guide rod is arranged between the two third supporting seats, two ends of the second guide rod are respectively fixedly arranged on the two third supporting seats, two second guide blocks are arranged on the second guide rod, through holes matched with the second guide rod are arranged on the second guide blocks, a connecting plate is arranged between the second guide blocks and the second sliding block, two ends of the connecting plate are respectively fixed at the tops of the second guide blocks and the second sliding block, the second guide blocks and the second sliding block are in one-to-one correspondence, two second adjusting mechanisms are arranged on the connecting plate and are symmetrically distributed, the second adjusting mechanisms comprise two fourth supporting seats, a third screw rod, a third sliding block and a second rocking handle, and the two fourth supporting seats are fixedly arranged on the connecting plate, the third lead screw is rotatably installed on the two fourth supporting seats, one end of the third lead screw extends to the outer side of the fourth supporting seats, the second rocking handle is fixedly installed at the end portion of the third lead screw, the third sliding block is installed on the third lead screw, a threaded hole matched with the third lead screw is formed in the third sliding block, and a second telescopic rod is fixedly arranged at the top of the third sliding block.

5. The perpendicularity detecting device for building engineering according to claim 4, wherein a top plate is fixedly mounted at the top of the second telescopic rod.

6. The verticality detection apparatus for construction engineering according to claim 5, wherein the top plate is cylindrical.

7. The perpendicularity detecting device for building engineering according to claim 4, wherein traveling wheels are fixedly mounted below the bottom plate, and an armrest frame is fixed on one side of the bottom plate.

8. The verticality detection apparatus for construction engineering according to claim 1, wherein a level gauge is mounted on the support plate.

9. The verticality detection apparatus for construction engineering according to claim 8, wherein the number of the levels is two and the levels are installed on both sides of the supporting plate.

Images