CN221425674U - Wall surface vertical measurer for supervision of building engineering - Google Patents

Abstract

The utility model discloses a wall surface vertical measurer for building engineering supervision, and relates to the technical field of building engineering supervision. The utility model relates to a wall surface vertical measurer for building engineering supervision, which comprises a movable seat, three groups of line laser sensors, and further comprises a measurement adjusting component arranged above the movable seat, wherein the measurement adjusting component comprises a vertical measuring frame arranged above the movable seat, extension frames arranged on two sides of the vertical measuring frame and a lifting frame arranged on one side surface of the vertical measuring frame, and an L-shaped mounting frame is fixed at the top of the movable seat.

Description

Wall surface vertical measurer for supervision of building engineering

Technical Field

The utility model relates to the technical field of building engineering supervision, in particular to a wall surface vertical measurer for building engineering supervision.

Background

The straightness that hangs down is the tolerance requirement that control measured element and benchmark factor contained angle are 90 among the direction tolerance, divide into given plane, given direction, arbitrary direction's straightness requirement that hangs down, along with the development of society, people have had more and more demands to the building engineering wall, and a car small bell of current patent, patent publication number CN219532082U includes PMKD, the last connection of PMKD is equipped with the movable roller, the last connection of movable roller is equipped with the braking vane, the last connection of PMKD is equipped with the wall laminating degree adjustable subassembly, wall laminating degree adjustable subassembly includes hydraulic stem extension board, telescopic hydraulic stem, fixed support riser, riser removal spout and riser movable block, the last connection of PMKD is equipped with the fixed support riser, be equipped with the riser removal spout on the PMKD, the last sliding connection of riser removal spout is equipped with the riser movable block, can realize the wall laminating degree automatic adjustment of wall laminating degree convenient with the wall laminating degree adjustable subassembly of wall laminating degree of wall laminating degree adjustable subassembly through the convenient realization of the automatic measuring device of wall laminating degree of monitoring of wall laminating degree.

With respect to the related art in the above, the inventors consider that there are the following drawbacks: although can realize the convenient automatic removal adjustment of wall perpendicular caliber for the building engineering supervision through the adjustable subassembly of wall laminating degree, nevertheless in the in-service use, some construction sites need to use line laser sensor or other calibrating device to calibrate the roughness of wall, guarantee the pleasing to the eye of wall, and the calibrating device in the present construction removes the inconvenient actual operation of top when the operation from the below, so we propose a wall perpendicular caliber for the building engineering supervision to solve the above-mentioned problem that exists.

Disclosure of utility model

Aiming at the defects of the prior art, the utility model provides a wall surface vertical measurer for building engineering supervision, which solves the problem that the flatness of a construction wall surface is inconvenient to detect.

In order to achieve the above purpose, the utility model is realized by the following technical scheme: the wall surface vertical measurer for building engineering supervision comprises a movable seat, three groups of line laser sensors and a measurement adjusting assembly arranged above the movable seat;

The measuring and adjusting assembly comprises a vertical measuring frame arranged above the action seat, extension frames arranged on two sides of the vertical measuring frame and a lifting frame arranged on one side surface of the vertical measuring frame.

Preferably, the top of action seat is fixed with L type mounting bracket, L type mounting bracket with be fixed with lead screw bearing frame group between the action seat, the interior axle rotation of lead screw bearing frame group is connected with the lead screw that rises, the center of crane seted up with the screw thread groove of rising lead screw looks adaptation, rise the lead screw with the screw thread groove threaded connection of crane.

Preferably, two groups of sliding rods are fixed between the lifting frame and the L-shaped mounting frame, sliding grooves matched with the sliding rods are formed in the two ends of the lifting frame, and the sliding rods are in sliding connection with the sliding grooves of the lifting frame.

Preferably, the outside of crane is connected with the gear wheel through the bearing rotation, the outside of crane is connected with the pinion through the bearing rotation, the gear wheel with the pinion meshing is connected, the inboard of survey perpendicular frame is fixed in the center of gear wheel, the inside of crane is fixed with rotation motor, rotation motor's output with the center pin connection of pinion.

Preferably, the both sides of survey frame of hanging down all have seted up the spout, two sets of extension frame respectively sliding connection is in survey the both sides spout of hanging down the frame is inside, the inboard of extension frame is fixed with the rack, survey the middle-end of hanging down the frame and rotate through the bearing and be connected with extension gear, extension gear with rack meshing is connected, survey the inboard of hanging down the frame and be fixed with extension motor, extension motor's output with extension gear's center pin connection, survey the outside of hanging down the frame and two sets of extension frame all is fixed with wired laser sensor.

Preferably, the top of L type mounting bracket is fixed with the motor that rises, the top of rising lead screw runs through to the outside of L type mounting bracket, the output of rising motor with the top of rising lead screw is connected.

Preferably, the device further comprises a moving assembly arranged at the bottom of the moving seat, wherein the moving assembly comprises two groups of universal moving wheels fixed at the bottom of the moving seat, driving wheels fixed at the bottom of the moving seat and wall plates fixed at two sides of the moving seat.

Advantageous effects

The utility model provides a wall surface vertical measurer for supervision of building engineering. Compared with the prior art, the method has the following beneficial effects:

This building engineering manages with perpendicular caliber of wall through calculating the length of line laser sensor highest and minimum distance, line laser sensor highest position distance wall, line laser sensor minimum position distance wall, obtains tangent value, can obtain the straightness that hangs down of wall, can obtain the roughness of wall through sweeping the wall.

Drawings

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

FIG. 2 is a schematic view of the structure of the vertical measuring rack and the connecting parts thereof in the utility model;

FIG. 3 is a schematic view of the structure of the extension frame and the connecting parts thereof in the present utility model;

FIG. 4 is a schematic view of the back structure of the vertical measuring rack and the connecting parts thereof in the utility model;

FIG. 5 is a schematic view of the structure of the lifting frame and its connection parts according to the present utility model;

FIG. 6 is a schematic view of a moving assembly and its connecting parts according to the present utility model;

Fig. 7 is an image schematic diagram of the line laser sensor of the present utility model.

In the figure:

1. A movable seat;

2. a measurement adjustment assembly; 21. a vertical measuring frame; 22. an extension rack; 23. a lifting frame; 24. an L-shaped mounting rack; 25. a screw rod bearing seat group; 26. lifting the screw rod; 27. a slide bar; 28. a large gear; 29. a pinion gear; 201. a rotating motor; 202. a rack; 203. an extension gear; 204. extending the motor; 205. a lifting motor;

3. a motion component; 31. a universal moving wheel; 32. a driving wheel; 33. pasting a wallboard;

4. a line laser sensor.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-7, the present utility model provides a technical solution: the utility model provides a wall perpendicular caliber for building engineering supervision, includes action seat 1 and three line laser sensor 4 of group, its characterized in that: also comprises a measurement adjusting component 2 arranged above the action seat 1;

The measuring and adjusting assembly 2 comprises a measuring stand 21 arranged above the action seat 1, extension frames 22 arranged on two sides of the measuring stand 21, and a lifting frame 23 arranged on one side surface of the measuring stand 21.

In this embodiment: the vertical measuring frame 21 is used for recording the verticality when being in the vertical direction, the vertical measuring frame 21 is used for recording the flatness of the wall surface, and the tangent value is obtained by calculating the highest distance and the lowest distance of the line laser sensor 4, the length of the highest position of the line laser sensor 4 from the wall surface and the length of the lowest position of the line laser sensor 4 from the wall surface, so that the verticality of the wall surface can be obtained.

Referring to fig. 1, 4, 5 and 6, an L-shaped mounting frame 24 is fixed at the top of the movable seat 1, a screw rod bearing seat group 25 is fixed between the L-shaped mounting frame 24 and the movable seat 1, an ascending screw rod 26 is rotatably connected to an inner shaft of the screw rod bearing seat group 25, a thread groove adapted to the ascending screw rod 26 is formed in the center of the lifting frame 23, and the ascending screw rod 26 is in threaded connection with the thread groove of the lifting frame 23.

In this embodiment: at this time, the line laser sensor 4 records the distance from the wall surface, and a display system (not shown) is disposed at the rear of the L-shaped mounting frame 24, and the display system (not shown) is connected to the line laser sensor 4 and displays the image transmitted by the line laser sensor 4.

Referring to fig. 1, 4, 5 and 6, two sets of sliding bars 27 are fixed between the lifting frame 23 and the L-shaped mounting frame 24, sliding grooves matched with the sliding bars 27 are formed at two ends of the lifting frame 23, and the sliding bars 27 are slidably connected with the sliding grooves of the lifting frame 23.

In this embodiment: by driving the lifting motor 205, the lifting screw 26 is rotated by the lifting motor 205, and the lifting frame 23 screwed to the lifting screw 26 is lifted or lowered on the track of the slide bar 27.

Referring to fig. 1 and 4, the outer side of the lifting frame 23 is rotatably connected with a large gear 28 through a bearing, the outer side of the lifting frame 23 is rotatably connected with a small gear 29 through a bearing, the large gear 28 is meshed with the small gear 29, the inner side of the vertical measuring frame 21 is fixed at the center of the large gear 28, a rotating motor 201 is fixed in the lifting frame 23, and the output end of the rotating motor 201 is connected with the central shaft of the small gear 29.

In this embodiment: by driving the rotation motor 201, the rotation motor 201 drives the pinion 29, and the pinion 29 drives the large gear 28 to rotate until the sag stand 21 is in a vertical state.

Referring to fig. 2 and 3, sliding grooves are formed on two sides of the vertical measuring frame 21, two groups of extension frames 22 are respectively and slidably connected inside the sliding grooves on two sides of the vertical measuring frame 21, a rack 202 is fixed on the inner side of the extension frames 22, an extension gear 203 is rotatably connected to the middle end of the vertical measuring frame 21 through a bearing, the extension gear 203 is in meshed connection with the rack 202, an extension motor 204 is fixed on the inner side of the vertical measuring frame 21, an output end of the extension motor 204 is connected with a central shaft of the extension gear 203, and wire laser sensors 4 are fixed on the outer sides of the vertical measuring frame 21 and the two groups of extension frames 22.

In this embodiment: by driving the extension motor 204, the extension motor 204 drives the extension gear 203 to rotate, and the rack 202 meshed with the extension gear 203 slides, so that the two groups of extension frames 22 slide in opposite directions to extend.

Referring to fig. 1, 4, 5 and 6, a lifting motor 205 is fixed at the top of the L-shaped mounting frame 24, the top of the lifting screw rod 26 penetrates to the outer side of the L-shaped mounting frame 24, and an output end of the lifting motor 205 is connected with the top of the lifting screw rod 26.

In this embodiment: by driving the lifting motor 205, the lifting screw 26 is rotated by the lifting motor 205, and the lifting frame 23 screwed to the lifting screw 26 is lifted up on the track of the slide bar 27.

Referring to fig. 1 and 6, the portable electronic device further comprises a portable module 3 disposed at the bottom of the portable module 1, wherein the portable module 3 comprises two sets of universal moving wheels 31 fixed at the bottom of the portable module 1, driving wheels 32 fixed at the bottom of the portable module 1, and wall panels 33 fixed at two sides of the portable module 1.

In this embodiment: through driving the drive wheel 32 to the wall removal, action seat 1 moves to the wall, and at first a set of wall pasting board 33 can contact the wall, continues to drive the drive wheel 32, and the universal wheel 31 of removing at the back can the whole skew that takes place of device under the effect of a set of wall pasting board 33 resistance, until another set of wall pasting board 33 also can contact the wall, makes device and wall parallel and level.

When the wall surface verticality is required to be measured, the driving wheel 32 is driven to move towards the wall surface, the action seat 1 is driven to move towards the wall surface, firstly, one group of wall plates 33 can contact the wall surface and continuously drive the driving wheel 32, the rear universal moving wheel 31 can shift the whole device under the action of the resistance of one group of wall plates 33 until the other group of wall plates 33 can contact the wall surface, the device is enabled to be flush with the wall surface, the line laser sensor 4 can record the distance from the wall surface, a display system (not shown in the figure) is arranged at the rear of the L-shaped mounting frame 24, the display system (not shown in the figure) is connected with the line laser sensor 4 and displays the image transmitted by the line laser sensor 4, the lifting motor 205 is driven by the lifting motor 205 to drive the lifting screw 26 to rotate, the lifting frame 23 in threaded connection with the lifting screw rod 26 is lifted on the track of the sliding rod 27 until the lifting frame moves to the upper side of the wall surface, the distance between the linear laser sensor 4 and the wall surface is recorded, the tangent value is obtained by calculating the highest and lowest distances between the linear laser sensor 4 and the wall surface, the length between the highest position of the linear laser sensor 4 and the wall surface, and the length between the lowest position of the linear laser sensor 4 and the wall surface, so that the perpendicularity of the wall surface can be obtained, at the moment, if the flatness of the wall surface is desired, the rotating motor 201 is driven to drive the pinion 29, the pinion 29 drives the large gear 28 to rotate until the verticality measuring frame 21 is in a vertical state, then the extending motor 204 is driven to drive the extending gear 203 to rotate, and the racks 202 meshed with the extending gear 203 slide to enable the two groups of extending frames 22 to slide oppositely for extending;

The positions of the three different line laser sensors 4, which are far from the wall surface, are recorded, when the height position calculation is carried out, the distances of the three line laser sensors 4 need to be recorded because the height positions of the three line laser sensors 4 are different, and the three line laser sensors 4 are recorded as a first line, a second line and a third line from bottom to top, and if the distance is x;

As shown in fig. 7, when the image value recorded by the first line laser sensor 4 is the image value of the lifting frame 23 at a height of 10cm from the ground, the image value recorded by the second line laser sensor 4 and the image value recorded by the first line laser sensor 4 are positioned at the same horizontal line, the image value of the lifting frame 23 at a height of x+10cm from the ground is the image value of the lifting frame 23 at a height of x+20cm from the ground, the flatness of a certain height of the wall surface can be obtained by integrating the overlapped positions of the three image values, the flatness of the whole wall surface can be obtained by integrating the image values of a plurality of groups of height wall surfaces, and the special colors are recorded at the concave and protruding positions, so that the observation can be more convenient.

In conclusion, the device can adjust the position of the line laser, obtains the tangent value by calculating the highest and lowest distances of the line laser sensor, the length of the highest position of the line laser sensor from the wall surface and the length of the lowest position of the line laser sensor from the wall surface, and can obtain the perpendicularity of the wall surface and the flatness of the wall surface by sweeping the wall surface.

And all that is not described in detail in this specification is well known to those skilled in the art.

Claims (7)

1. The utility model provides a vertical caliber of wall for building engineering supervision, includes action seat (1) and three line laser sensor (4), its characterized in that: the measuring and adjusting assembly (2) is arranged above the action seat (1);

The measuring and adjusting assembly (2) comprises a vertical measuring frame (21) arranged above the action seat (1), extension frames (22) arranged on two sides of the vertical measuring frame (21) and a lifting frame (23) arranged on one side surface of the vertical measuring frame (21).

2. The wall surface verticality measurer for supervision of constructional engineering according to claim 1, wherein: the lifting device is characterized in that an L-shaped mounting frame (24) is fixed at the top of the action seat (1), a screw rod bearing seat group (25) is fixed between the L-shaped mounting frame (24) and the action seat (1), an ascending screw rod (26) is connected with the inner shaft of the screw rod bearing seat group (25) in a rotating mode, a thread groove matched with the ascending screw rod (26) is formed in the center of the lifting frame (23), and the ascending screw rod (26) is in threaded connection with the thread groove of the lifting frame (23).

3. The wall surface verticality measurer for construction engineering supervision according to claim 2, wherein: two groups of sliding rods (27) are fixed between the lifting frame (23) and the L-shaped mounting frame (24), sliding grooves matched with the sliding rods (27) are formed in the two ends of the lifting frame (23), and the sliding rods (27) are in sliding connection with the sliding grooves of the lifting frame (23).

4. The wall surface verticality measurer for supervision of constructional engineering according to claim 1, wherein: the outside of crane (23) is connected with gear wheel (28) through the bearing rotation, the outside of crane (23) is connected with pinion (29) through the bearing rotation, gear wheel (28) with pinion (29) meshing is connected, survey the inboard of hanging down frame (21) and fix the center of gear wheel (28), the inside of crane (23) is fixed with rotation motor (201), the output of rotation motor (201) with the center pin connection of pinion (29).

5. The wall surface verticality measurer for supervision of constructional engineering according to claim 1, wherein: the utility model discloses a measuring rack, including survey frame (21), extension frame (22), wire laser sensor (4), extension frame (21), extension gear (203), extension motor (204) are fixed with in the inboard of survey frame (21), the spout has all been seted up to the both sides of survey frame (21), two sets of extension frame (22) sliding connection are in respectively inside the both sides spout of survey frame (21), the inboard of extension frame (22) is fixed with rack (202), the middle-end of survey frame (21) is connected with extension gear (203) through the bearing rotation, extension gear (203) with rack (202) meshing is connected, the inboard of survey frame (21) is fixed with extension motor (204), the output of extension motor (204) with the center pin connection of extension gear (203), survey frame (21) and two sets of the outside of extension frame (22) all is fixed with wire laser sensor (4).

6. The wall surface verticality measurer for construction engineering supervision according to claim 2, wherein: the top of L type mounting bracket (24) is fixed with and rises motor (205), the top of rising lead screw (26) runs through to the outside of L type mounting bracket (24), the output of rising motor (205) with the top of rising lead screw (26) is connected.

7. The wall surface verticality measurer for supervision of constructional engineering according to claim 1, wherein: the automatic walking device is characterized by further comprising a walking component (3) arranged at the bottom of the walking seat (1), wherein the walking component (3) comprises two groups of universal moving wheels (31) fixed at the bottom of the walking seat (1), driving wheels (32) fixed at the bottom of the walking seat (1) and wall-attaching plates (33) fixed at two sides of the walking seat (1).