CN217403850U

CN217403850U - Building major structure detection device

Info

Publication number: CN217403850U
Application number: CN202220249357.3U
Authority: CN
Inventors: 李磊
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-02-07
Filing date: 2022-02-07
Publication date: 2022-09-09
Anticipated expiration: 2032-02-07

Abstract

The utility model relates to a building technical field just discloses a building subject structure detection device, get mechanism, slewing mechanism and moving mechanism including base, adjustment mechanism, drilling, adjustment mechanism is located the top of base, the drilling is got the below that the mechanism is located adjustment mechanism, slewing mechanism is located the drilling and is got the rear end of mechanism, moving mechanism is located the outer end of base. This building major structure detection device, through installing two sampling barrels, two pivots can drive the sampling barrel and rotate and bore a hole and get the core, the sampling barrel is together fixed with the pivot when getting the core, when need not getting the core, can dismantle the sampling barrel and wash, the diameter of these two sampling barrels can be inequality, but the length of two sampling barrels is unanimous, when the core is got in the drilling, can utilize two sampling barrels that length is the same to carry out synchronous coring to the concrete in the different position of short distance, prevent that the degree of depth of drilling is inconsistent, the quality of coring and concrete is got in the influence.

Description

Building major structure detection device

Technical Field

The utility model relates to a building technical field specifically is a building major structure detection device.

Background

The method is characterized in that the method refers to assets formed by artificial buildings, belongs to the category of fixed assets, and comprises two categories of houses and structures, wherein the houses refer to engineering buildings for people to live, work, study, production, management, entertainment, article storage and other social activities, the buildings are distinguished from the buildings, the structures refer to engineering buildings except the houses, such as enclosing walls, roads, dams, water wells, tunnels, water towers, bridges, chimneys and the like, the detection of the main structure of the buildings comprises the index detection of steel bars in concrete, the concrete and the steel bars are usually detected by adopting a core drilling sampling method, and core drilling sampling is carried out in places without the steel bars so as to reversely push the positions of the steel bars and deduce the corrosion degree of the steel bars.

Among the prior art, when the core drilling sample, if near same drilling hole is drilled again, the hole depth of so new drilling must keep unanimous with near hole depth, and current core drilling sampling device only has a sampler barrel when drilling, therefore hardly guarantees new hole and keeps unanimous with the degree of depth with regard to the hole, can influence the quality and the efficiency of drilling the core, and current core drilling sampling device can only downward sample mostly, can not upwards sample, and the suitability is relatively poor.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

An object of the utility model is to provide a building main part structure detection device, in order to solve and to propose prior art among the above-mentioned background art, when the coring sample, if bore near same drilling again, the hole depth degree of so new drilling must keep unanimous with near hole depth degree, current coring sampling device only has a sampling tube when drilling, therefore hardly guarantee new hole and keep unanimous with the degree of depth with regard to the hole, can influence the quality and the efficiency of core is got in the drilling, and current coring sampling device can only take a sample downwards mostly, can not upwards take a sample, the relatively poor problem of suitability.

(II) technical scheme

In order to achieve the above purpose, the utility model provides a following technical scheme: a building main body structure detection device comprises a base, an adjusting mechanism, a drilling and coring mechanism, a rotating mechanism and a moving mechanism, wherein the adjusting mechanism is positioned above the base;

adjustment mechanism includes guide bar, roof, hand wheel, screw thread post, stopper and sliding block, guide bar fixed mounting is in the left and right sides of base upper end, the quantity of guide bar is two, roof fixed mounting is in the upper end of guide bar.

Preferably, hand wheel movable mounting is in the upper end of roof, screw thread post fixed mounting is at the lower extreme of hand wheel, the screw thread post runs through the roof and extends to the below of roof, stopper fixed mounting is at the lower extreme of screw thread post, sliding block threaded connection is in the outer end of screw thread post, sliding block and guide bar swing joint, through the installation hand wheel, when the core was got in drilling, rotate the hand wheel, can drive the screw thread post and rotate, can drive the sliding block from this and slide from top to bottom along screw thread post and guide bar, can drive the drilling from this and get the core mechanism and make progress or downstream, treat to detect the concrete and drill the sample.

Preferably, the drilling and coring mechanism comprises a supporting block, a driving motor, a first rotating shaft, a first rotating wheel, a belt, a second rotating wheel, a second rotating shaft, a first sampling cylinder and a second sampling cylinder, wherein the supporting block is movably arranged at the front end of the sliding block, the driving motor is fixedly arranged on the left side of the upper end of the supporting block, the first rotating shaft is fixedly connected to the lower end of the driving motor, the first rotating shaft penetrates through the supporting block and extends to the lower part of the supporting block, and the first rotating shaft can be driven to rotate by installing the driving motor.

Preferably, first runner fixed mounting is in the outer end of first pivot, belt swivelling joint is in the outer end of first runner, second runner swivelling joint is in the inner of belt, second pivot fixed mounting is at the axle head of second runner, and through the installation belt, the rotation of first runner can drive first runner and rotate, under the effect of belt, can drive second runner and second pivot and rotate.

Preferably, the lower extreme in first pivot is installed to first sampler barrel, be connected for dismantling between first sampler barrel and the first pivot, the lower extreme in the second pivot is installed to the second sampler barrel, be connected for dismantling between second sampler barrel and the second pivot, through installing two sampler barrels, two pivots can drive the sampler barrel and rotate and bore the core, the sampler barrel is together fixed with the pivot during coring, when need not coring, can dismantle the sampler barrel and wash, the diameter of these two sampler barrels can not be the same, but the length of two sampler barrels is unanimous, when the core is got in the drilling, can utilize two sampler barrels that length is the same to carry out the core in step to the not equidirectional concrete of near distance, prevent that the degree of depth of drilling is inconsistent, influence the quality of coring and concrete.

Preferably, the rotating mechanism comprises a rotating column and a rotating block, the rotating column is fixedly mounted at the rear end of the supporting block, the rotating column penetrates through the sliding block and extends to the rear side of the sliding block, the rotating block is fixedly mounted at the rear end of the rotating column, and the rotating column can be driven to rotate by mounting the rotating block, so that the drilling coring mechanism can be driven to rotate, the direction of the sampling cylinder can be adjusted, and the sampling cylinder can be used for coring downwards and also coring upwards.

Preferably, the moving mechanism comprises a front roller, a rear brake wheel and a handrail, the front roller is movably mounted in front of the left end and the right end of the base, the rear brake wheel is mounted at the rear end of the base, the handrail is fixedly mounted at the rear side of the upper end of the base, and the device can be braked in time by mounting the rear brake wheel, so that the stability of the device is improved.

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

1. the building main structure detection device is characterized in that two sampling cylinders are installed, the two rotating shafts can drive the sampling cylinders to rotate to drill and core, the sampling cylinders are fixed together with the rotating shafts during coring, the sampling cylinders can be detached to be cleaned when coring is not needed, the diameters of the two sampling cylinders can be different, but the lengths of the two sampling cylinders are the same, when drilling and coring are performed, the two sampling cylinders with the same length can be used for synchronously coring concrete in different directions at a short distance, the depth of drilling is prevented from being inconsistent, and the quality of coring and concrete is influenced;

2. this building major structure detection device through the installation turning block, rotates the turning block and can drive the rotation post and rotate, can drive the drilling from this and get the rotation of core mechanism to the direction of adjustment sampler barrel makes it can get the core downwards, also can upwards get the core.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic view of a partial three-dimensional structure of the threaded post of the present invention;

FIG. 3 is a schematic view of the three-dimensional structure of the rotating mechanism and the drilling and coring mechanism of the present invention;

fig. 4 is the schematic view of the local section structure of the core drilling mechanism of the present invention.

In the figure: 1. a base; 2. an adjustment mechanism; 201. a guide bar; 202. a top plate; 203. a hand wheel; 204. a threaded post; 205. a limiting block; 206. a slider; 3. drilling and core-taking mechanism; 301. a support block; 302. a drive motor; 303. a first rotating shaft; 304. a first runner; 305. a belt; 306. a second runner; 307. a second rotating shaft; 308. a first sampling cylinder; 309. a second sampling tube; 4. a rotating mechanism; 401. rotating the column; 402. rotating the block; 5. a moving mechanism; 501. a front roller; 502. a rear brake wheel; 503. an armrest.

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 efforts all belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a building main body structure detection device comprises a base 1, an adjusting mechanism 2, a drilling and core-taking mechanism 3, a rotating mechanism 4 and a moving mechanism 5, wherein the adjusting mechanism 2 is positioned above the base 1, the drilling and core-taking mechanism 3 is positioned below the adjusting mechanism 2, the rotating mechanism 4 is positioned at the rear end of the drilling and core-taking mechanism 3, and the moving mechanism 5 is positioned at the outer end of the base 1;

the adjusting mechanism 2 comprises guide rods 201, a top plate 202, a hand wheel 203, a threaded column 204, limiting blocks 205 and sliding blocks 206, the guide rods 201 are fixedly arranged on the left side and the right side of the upper end of the base 1, the number of the guide rods 201 is two, and the top plate 202 is fixedly arranged on the upper end of the guide rods 201;

the hand wheel 203 is movably arranged at the upper end of the top plate 202, the threaded column 204 is fixedly arranged at the lower end of the hand wheel 203, the threaded column 204 penetrates through the top plate 202 and extends to the lower part of the top plate 202, the limiting block 205 is fixedly arranged at the lower end of the threaded column 204, the sliding block 206 is in threaded connection with the outer end of the threaded column 204, the sliding block 206 is movably connected with the guide rod 201, and by installing the hand wheel 203, when core drilling is performed, the hand wheel 203 is rotated to drive the threaded column 204 to rotate, so that the sliding block 206 can be driven to slide up and down along the threaded column 204 and the guide rod 201, and the core drilling and taking mechanism 3 can be driven to move up or down to perform drilling and sampling on concrete to be detected; the core drilling and taking mechanism 3 comprises a supporting block 301, a driving motor 302, a first rotating shaft 303, a first rotating wheel 304, a belt 305, a second rotating wheel 306, a second rotating shaft 307, a first sampling cylinder 308 and a second sampling cylinder 309, wherein the supporting block 301 is movably arranged at the front end of a sliding block 206, the driving motor 302 is fixedly arranged at the left side of the upper end of the supporting block 301, the first rotating shaft 303 is fixedly connected to the lower end of the transmission end of the driving motor 302, the first rotating shaft 303 penetrates through the supporting block 301 and extends to the lower part of the supporting block 301, and the driving motor 302 is arranged to drive the first rotating shaft 303 to rotate; the first rotating wheel 304 is fixedly arranged at the outer end of the first rotating shaft 303, the belt 305 is rotatably connected at the outer end of the first rotating wheel 304, the second rotating wheel 306 is rotatably connected at the inner end of the belt 305, the second rotating shaft 307 is fixedly arranged at the shaft end of the second rotating wheel 306, the first rotating wheel 304 can be driven to rotate by the rotation of the first rotating shaft 303 through the installation of the belt 305, and the second rotating wheel 306 and the second rotating shaft 307 can be driven to rotate under the action of the belt 305; the first sampling cylinder 308 is installed at the lower end of the first rotating shaft 303, the first sampling cylinder 308 is detachably connected with the first rotating shaft 303, the second sampling cylinder 309 is installed at the lower end of the second rotating shaft 307, the second sampling cylinder 309 is detachably connected with the second rotating shaft 307, the two rotating shafts can drive the sampling cylinders to rotate to carry out drilling and coring by installing the two sampling cylinders, the sampling cylinders are fixed with the rotating shafts together during coring, the sampling cylinders can be detached to be cleaned when coring is not needed, the diameters of the two sampling cylinders can be different, but the lengths of the two sampling cylinders are the same, when the core is drilled, the two sampling cylinders with the same length can be used for synchronously coring concrete in different directions at a short distance, the depth of the drilled hole is prevented from being different, and the quality of the coring and the concrete is influenced;

the rotating mechanism 4 comprises a rotating column 401 and a rotating block 402, the rotating column 401 is fixedly installed at the rear end of the supporting block 301, the rotating column 401 penetrates through the sliding block 206 and extends to the rear of the sliding block 206, the rotating block 402 is fixedly installed at the rear end of the rotating column 401, and the rotating block 402 can drive the rotating column 401 to rotate by installing the rotating block 402, so that the core drilling and taking mechanism 3 can be driven to rotate, the direction of the sampling cylinder can be adjusted, and the core can be taken downwards and upwards; the moving mechanism 5 comprises a front roller 501, a rear brake wheel 502 and a handrail 503, the front roller 501 is movably arranged in front of the left end and the right end of the base 1, the rear brake wheel 502 is arranged at the rear end of the base 1, the handrail 503 is fixedly arranged at the rear side of the upper end of the base 1, and the device can be braked in time by arranging the rear brake wheel 502, so that the stability of the device is improved.

The working principle is as follows: firstly, the driving motor 302 drives the first rotating shaft 303 to rotate, the rotation of the first rotating shaft 303 can drive the first rotating wheel 304 to rotate, under the action of the belt 305, the second rotating wheel 306 and the second rotating shaft 307 can be driven to rotate, the two rotating shafts can drive the sampling cylinders to rotate for drilling and coring, the hand wheel 203 is rotated to drive the threaded column 204 to rotate, thereby the sliding block 206 can be driven to slide up and down along the threaded column 204 and the guide rod 201, thereby the sampling cylinders can be driven to move up and down, the concrete to be detected is drilled and sampled, the diameters of the two sampling cylinders can be different, but the lengths of the two sampling cylinders are the same, when in drilling, the two sampling cylinders with the same length can be used for synchronously coring the concrete in different directions at a short distance, the rotating block 402 can be rotated to drive the rotating column 401 to rotate, thereby the core drilling mechanism 3 can be driven to rotate, thereby the direction of adjustment sampling tube makes it can get the core downwards, also can upwards get the core.

It should be finally noted that the above only serves to illustrate the technical solution of the present invention, and not to limit the scope of the present invention, and that simple modifications or equivalent replacements performed by those skilled in the art to the technical solution of the present invention do not depart from the spirit and scope of the technical solution of the present invention.

Claims

1. The utility model provides a building major structure detection device, includes base (1), adjustment mechanism (2), drilling core taking mechanism (3), slewing mechanism (4) and moving mechanism (5), its characterized in that: the adjusting mechanism (2) is located above the base (1), the drilling and coring mechanism (3) is located below the adjusting mechanism (2), the rotating mechanism (4) is located at the rear end of the drilling and coring mechanism (3), and the moving mechanism (5) is located at the outer end of the base (1);

adjustment mechanism (2) include guide bar (201), roof (202), hand wheel (203), screw thread post (204), stopper (205) and sliding block (206), guide bar (201) fixed mounting is in the left and right sides of base (1) upper end, the quantity of guide bar (201) is two, roof (202) fixed mounting is in the upper end of guide bar (201).

2. The building main body structure detection device according to claim 1, wherein: hand wheel (203) movable mounting is in the upper end of roof (202), screw thread post (204) fixed mounting is at the lower extreme of hand wheel (203), screw thread post (204) run through roof (202) and extend to the below of roof (202), stopper (205) fixed mounting is at the lower extreme of screw thread post (204), sliding block (206) threaded connection is in the outer end of screw thread post (204), sliding block (206) and guide bar (201) swing joint.

3. The building main body structure detection device according to claim 2, wherein: the core drilling and taking mechanism (3) comprises a supporting block (301), a driving motor (302), a first rotating shaft (303), a first rotating wheel (304), a belt (305), a second rotating wheel (306), a second rotating shaft (307), a first sampling cylinder (308) and a second sampling cylinder (309), wherein the supporting block (301) is movably arranged at the front end of a sliding block (206), the driving motor (302) is fixedly arranged on the left side of the upper end of the supporting block (301), the first rotating shaft (303) is fixedly connected to the lower end of the transmission end of the driving motor (302), and the first rotating shaft (303) penetrates through the supporting block (301) and extends to the lower side of the supporting block (301).

4. A building body structure detection apparatus according to claim 3, wherein: the first rotating wheel (304) is fixedly installed at the outer end of the first rotating shaft (303), the belt (305) is rotatably connected at the outer end of the first rotating wheel (304), the second rotating wheel (306) is rotatably connected at the inner end of the belt (305), and the second rotating shaft (307) is fixedly installed at the shaft end of the second rotating wheel (306).

5. The building main body structure detection device according to claim 4, wherein: first sampling section of thick bamboo (308) are installed at the lower extreme of first pivot (303), be connected for dismantling between first sampling section of thick bamboo (308) and first pivot (303), the lower extreme at second pivot (307) is installed in second sampling section of thick bamboo (309), be connected for dismantling between second sampling section of thick bamboo (309) and second pivot (307).

6. The building main body structure detection device according to claim 5, wherein: the rotating mechanism (4) comprises a rotating column (401) and a rotating block (402), the rotating column (401) is fixedly mounted at the rear end of the supporting block (301), the rotating column (401) penetrates through the sliding block (206) and extends to the rear of the sliding block (206), and the rotating block (402) is fixedly mounted at the rear end of the rotating column (401).

7. The building main body structure detection device according to claim 6, wherein: the moving mechanism (5) comprises a front roller (501), a rear brake wheel (502) and an armrest (503), the front roller (501) is movably mounted in front of the left end and the right end of the base (1), the rear brake wheel (502) is mounted at the rear end of the base (1), and the armrest (503) is fixedly mounted on the rear side of the upper end of the base (1).