CN220230382U - Building wall thickness detection device - Google Patents

Abstract

The application belongs to the technical field of constructional engineering and discloses a device for detecting the thickness of a building wall body, which comprises a body, a driving mechanism, a fixed ruler, a movable ruler and a level gauge; the body is fixedly provided with a driving mechanism; one end of the body is fixedly provided with a fixed ruler which is in running fit with the driving mechanism; a movable ruler is slidably arranged on the body; the movable ruler is in threaded connection and coordination with the driving mechanism; the body is fixedly provided with a level gauge; the level gauge is fixedly connected with the movable ruler; the inner sides of the fixed ruler and the movable ruler are fixedly provided with contact inductors; the body is fixedly provided with a PLC control module and an information storage module. According to the utility model, the wall body can be automatically clamped and measured through the arrangement of the driving mechanism and the contact sensor; the body can be checked and adjusted by a level gauge to keep the body horizontally placed; the height from the ground during wall thickness measurement can be automatically measured. The body can be lifted to a high position through the supporting mechanism, and thickness measurement is carried out on a high position of the wall body.

Description

Building wall thickness detection device

Technical Field

The application relates to the technical field of constructional engineering, and more particularly relates to a device for detecting thickness of a building wall.

Background

In the building construction process, in order to ensure construction quality, accurate detection is needed to be carried out on the thickness of a part of buildings, most of the existing building wall thickness detection is carried out manually by using a tape measure or a caliper, time and labor are wasted, and inaccuracy in reading can be caused.

The prior art publication No. CN 217738121U provides a building wall thickness detection device, which comprises a detection ruler plate, wherein the top end of the detection ruler plate is fixedly connected with a hanging frame, one side of the detection ruler plate is fixedly connected with a handle, the top of one side of the detection ruler plate is fixedly connected with a positioning marker post structure, and the center of one side of the detection ruler plate is provided with a chute; the center sliding connection of spout has a slip marker post structure, spacing hole has all been seted up at the center of the front and back end of detection chi board. According to the utility model, the sliding marker post structure can be limited when the measurement value is watched after the measurement of the high place is finished by arranging the bolts, so that the phenomenon that the measurement value is inaccurate due to the fact that the sliding marker post structure moves when the measurement value is watched is prevented; the utility model can rotate and fold the marker post by arranging the simple folding structure, thereby reducing the volume and being convenient to carry.

The above prior art solution, though realizing the beneficial effects related to the prior art by the structure of the prior art, still has the following drawbacks: 1. in the measuring process, whether the device is horizontally placed or not cannot be detected, and the accuracy of data measurement cannot be guaranteed. And II: when the thickness of the wall body at the height is required to be measured, a worker is required to step on a table or a chair for measurement, the measurement is inconvenient, the safety of the measurer is not facilitated, and the risk that the worker falls down during detection exists.

In view of this, we propose a building wall thickness detection device.

Disclosure of Invention

1. The technical problem to be solved.

The device for detecting the thickness of the building wall solves the technical problems in the background technology, and can automatically clamp and measure the wall; the body can be checked and adjusted by a level gauge to keep the body horizontally placed; the body can be lifted to a high position through the supporting mechanism, and the technical effect of thickness measurement is carried out on a high position of the wall body.

2. The technical proposal is that.

The application technical scheme provides building wall thickness detection device, include: the device comprises a body, a driving mechanism, a fixed ruler, a movable ruler and a level gauge.

The body is fixedly provided with a driving mechanism.

One end of the body is fixedly provided with a fixed ruler which is in running fit with the driving mechanism.

A movable ruler is slidably arranged on the body; the movable ruler is in threaded connection with the driving mechanism.

The body is fixedly provided with a level gauge; the level gauge is fixedly connected with the movable ruler.

The inner sides of the fixed ruler and the movable ruler are fixedly provided with contact sensors.

The PLC control module and the information storage module are fixedly arranged on the body, and the PLC control module is electrically connected with the driving mechanism.

The body is fixedly provided with a laser range finder, and the height of the body from the ground can be measured through the laser range finder.

Through the technical scheme, whether the body is horizontally placed or not can be detected through the level meter; the driving mechanism drives the movable ruler, and when the contact sensors on the fixed ruler and the movable ruler sense that the movable ruler contacts the wall surface, the driving mechanism stops working, and the thickness of the wall surface can be measured by reading the scales on the movable ruler.

As an alternative of the present utility model, the driving mechanism includes a motor a and a threaded rod.

The motor A is fixedly arranged on the body, a threaded rod is coaxially and fixedly arranged on a rotating shaft of the motor A, and the threaded rod is in threaded connection with the movable ruler.

Through above-mentioned technical scheme, motor A drives the threaded rod and rotates, and the threaded rod drives the movable ruler and removes the measurement.

As an alternative scheme of the utility model, a storage box is fixedly arranged on the body, and a fixed pipe is fixedly arranged on one side of the storage box; a thread groove is arranged in the fixed pipe.

A sliding chute A and a sliding chute B are arranged on the body in parallel.

The chute A is arranged in sliding fit with the level gauge.

The outer side of the sliding groove B on the body is fixedly provided with scale marks.

As an alternative scheme of the utility model, the movable ruler is fixedly provided with an image pickup mechanism.

The camera shooting mechanism comprises a sliding block, a motor B, a supporting rod and a high-definition camera.

The sliding block is fixedly arranged on the movable ruler, and the sliding block is slidably arranged in the sliding groove B.

The sliding block is fixedly provided with a motor B, and a supporting rod is fixedly arranged on a rotating shaft of the motor B.

And a high-definition camera is fixedly arranged on the supporting rod.

An L-shaped plate is fixedly arranged on the sliding block and fixedly connected with the level gauge.

And the motor B is electrically connected with the PLC control module.

Through the technical scheme, the moving ruler can drive the high-definition camera to synchronously move when moving, and can drive the level gauge to synchronously move. The supporting rod is driven to rotate by the motor B, so that the angle of the high-definition camera is adjusted, and the high-definition camera faces the level gauge.

As an alternative scheme of the utility model, a threaded sleeve is fixedly arranged on the movable ruler, and the threaded sleeve is in threaded fit with the threaded rod. The length of the threaded sleeve is greater than the width of the movable ruler.

The inner sides of the front ends of the movable ruler and the fixed ruler are fixedly provided with laser transmitters.

Through above-mentioned technical scheme, can make the mobile ruler remove more steadily through the cooperation of threaded sleeve pipe and threaded rod.

As an alternative of the utility model, the fixing tube is detachably and fixedly provided with a supporting mechanism.

The supporting mechanism comprises a fixed rod and a telescopic rod.

An adjusting knob is fixedly arranged on the fixing rod; the telescopic link slidable sets up on the dead lever to adjust position and locking location through adjust knob.

The end of the telescopic rod is provided with threads, and the telescopic rod is in threaded fit with the fixed pipe.

A display screen is fixedly arranged on the fixed rod and connected with a high-definition camera through a wireless signal; the display screen is provided with a control switch, and the control switch is connected with the PLC control module through a wireless signal.

As an alternative scheme of the utility model, the storage batteries are fixedly arranged on the fixing rod and the body to provide power for the whole device.

As an alternative scheme of the utility model, the storage box is provided with a slot matched with the fixing rod, and after the telescopic rod is contained in the fixing rod, the fixing rod can be inserted into the storage box.

3. Has the beneficial effects of.

One or more technical solutions provided in the embodiments of the present application have at least the following technical effects or advantages.

1. According to the utility model, the wall body can be automatically clamped and measured through the arrangement of the driving mechanism and the contact sensor.

1. The body can be inspected by a level gauge and adjusted to remain horizontally positioned.

2. The height from the ground during wall thickness measurement can be automatically measured.

3. The body can be lifted to a high position through the supporting mechanism, the thickness measurement is carried out on the high position of the wall body, the height of the supporting mechanism can be adjusted, and the supporting mechanism can be detached and stored, so that the space is saved.

Drawings

Fig. 1 is a schematic structural diagram of a device for detecting thickness of a building wall according to a preferred embodiment of the present application.

Fig. 2 is a schematic structural view of a supporting mechanism of a device for detecting thickness of a building wall according to a preferred embodiment of the present disclosure in a storage state.

Fig. 3 is a schematic structural diagram of a device for detecting thickness of a building wall according to a preferred embodiment of the present application.

Fig. 4 is a schematic view of a moving rule of the device for detecting thickness of a building wall according to a preferred embodiment of the present application.

Fig. 5 is an enlarged view of a portion a in fig. 3.

Fig. 6 is a schematic structural view of a supporting mechanism of a device for detecting thickness of a building wall according to a preferred embodiment of the present utility model.

Reference numerals in the figures illustrate.

1. A body; 2. a driving mechanism; 3. a fixed ruler; 4. a movable ruler; 5. an image pickup mechanism; 6. a level gauge; 7. a support mechanism; 8. a laser range finder; 9. a laser emitter; 10. a contact sensor; 11. a fixed tube; 12. a storage tank; 13. a chute A; 14. a chute B; 15. a scale mark; 21. a motor A; 22. a threaded rod; 41. a threaded sleeve; 51. a slide block; 52. a motor B; 53. a support rod; 54. high definition camera; 55. an L-shaped plate; 71. a fixed rod; 72. a telescopic rod; 73. and a display screen.

Detailed Description

While the present utility model has been described in terms of embodiments thereof with reference to the drawings, it should be understood that the utility model is not limited to the particular embodiments, but rather should be understood to cover all embodiments of the utility model. 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.

The present application is described in further detail below in conjunction with the drawings attached to the specification.

Referring to fig. 1, 2, 3 and 6, the present utility model provides a building wall thickness detection device, comprising: the device comprises a body 1, a driving mechanism 2, a fixed ruler 3, a movable ruler 4 and a level gauge 6.

The body 1 is fixedly provided with a driving mechanism 2.

One end of the body 1 is fixedly provided with a fixed ruler 3, and the fixed ruler 3 is in running fit with the driving mechanism 2.

A movable ruler 4 is slidably arranged on the body 1; the movable ruler 4 is in threaded connection and matched with the driving mechanism 2.

The body 1 is fixedly provided with a level gauge 6; the level gauge 6 is fixedly connected with the movable ruler 4.

The inner sides of the fixed ruler 3 and the movable ruler 4 are fixedly provided with contact sensors 10.

The PLC control module and the information storage module are fixedly arranged on the body 1, and the PLC control module is electrically connected with the driving mechanism 2. The PLC control module is a programmable controller.

The body 1 is fixedly provided with a laser range finder 8, and the height of the body 1 from the ground can be measured through the laser range finder 8.

In this solution, it is possible to detect whether the body 1 is placed horizontally by means of the level gauge 6; the driving mechanism 2 drives the movable ruler 4, and when the contact sensors 10 on the fixed ruler 3 and the movable ruler 4 sense that the movable ruler contacts the wall surface, the driving mechanism 2 stops working, and the scales at the position of the movable ruler 4 are read at the moment, so that the thickness of the wall surface can be measured.

Referring to fig. 3, the driving mechanism 2 includes a motor a21 and a threaded rod 22.

The motor A21 is fixedly arranged on the body 1, a threaded rod 22 is coaxially and fixedly arranged on a rotating shaft of the motor A21, and the threaded rod 22 is in threaded connection with the movable ruler 4.

In this solution, the motor a21 drives the threaded rod 22 to rotate, and the threaded rod 22 drives the mobile ruler 4 to perform mobile measurement.

Referring to fig. 2 and 3, a storage tank 12 is fixedly provided on the body 1, and a fixing tube 11 is fixedly provided at one side of the storage tank 12; a thread groove is provided in the fixing tube 11.

The body 1 is provided with a chute A13 and a chute B14 in parallel.

The chute A13 is arranged in a sliding fit with the level 6.

The outer side of the sliding groove B14 on the body 1 is fixedly provided with a scale mark 15.

Referring to fig. 1, 2, 3 and 5, an imaging mechanism 5 is fixedly provided on the movable scale 4.

The image pickup mechanism 5 includes a slider 51, a motor B52, a support rod 53, and a high-definition camera 54.

The sliding block 51 is fixedly arranged on the movable ruler 4, and the sliding block 51 is slidably arranged in the sliding groove B14.

The sliding block 51 is fixedly provided with a motor B52, and a supporting rod 53 is fixedly arranged on a rotating shaft of the motor B52.

The supporting rod 53 is fixedly provided with a high-definition camera 54.

An L-shaped plate 55 is fixedly arranged on the sliding block 51, and the L-shaped plate 55 is fixedly connected with the level gauge 6.

In this technical solution, the moving ruler 4 can drive the high-definition camera 54 to move synchronously while driving the level 6 to move synchronously. The supporting rod 53 can be driven to rotate through the motor B52, so that the angle of the high-definition camera 54 is adjusted, and the high-definition camera 54 faces the level gauge 6.

Referring to fig. 4, a threaded sleeve 41 is fixedly arranged on the moving rule 4, and the threaded sleeve 41 is in threaded fit with the threaded rod 22. The length of the threaded sleeve 41 is greater than the width of the travelling rule 4.

The inner sides of the front ends of the movable ruler 4 and the fixed ruler 3 are fixedly provided with laser transmitters 9.

In this solution, the movement of the mobile ruler 4 can be made smoother by the cooperation of the threaded sleeve 41 with the threaded rod 22.

Referring to fig. 1, 2 and 6, the fixing tube 11 is detachably and fixedly provided with a supporting mechanism 7.

The support mechanism 7 includes a fixed lever 71 and a telescopic lever 72.

An adjusting knob is fixedly arranged on the fixed rod 71; the telescopic rod 72 is slidably disposed on the fixed rod 71, and is adjusted in position and locked in position by an adjusting knob.

The end of the telescopic rod 72 is provided with threads, and the telescopic rod 72 is in threaded engagement with the fixed tube 11.

The display screen 73 is fixedly arranged on the fixed rod 71, and the display screen 73 is connected with the high-definition camera 54 through a wireless signal; the display screen 73 is provided with a control switch, and the control switch is connected with the PLC control module through a wireless signal.

The fixed rod 71 and the body 1 are fixedly provided with storage batteries for providing power for the whole device.

The storage box 12 is provided with a slot adapted to the fixing rod 71, and after the telescopic rod 72 is accommodated in the fixing rod 71, the fixing rod 71 can be inserted into the storage box 12.

In this technical scheme, the telescopic rod 72 can be mounted on the fixed pipe 11, the position of the telescopic rod 72 on the fixed rod 71 can be adjusted, the height can be adjusted, and the body 1 can be lifted to measure the thickness of the wall body at the high position.

The utility model relates to a working principle of a building wall thickness detection device, which comprises the following steps: in use, the fixed rule 3 and the movable rule 4 are first separated by the driving mechanism 2, and the fixed rule 3 and the movable rule 4 are placed on two sides of the wall body. The body 1 is adjusted to keep horizontal, and whether the body 1 is horizontally placed or not can be checked through the level gauge 6; the driving mechanism 2 is started to drive the movable ruler 4 to move towards the fixed ruler 3, and when the contact sensors 10 on the fixed ruler 3 and the movable ruler 4 sense that the movable ruler 4 contacts the wall surface, the driving mechanism 2 stops working, and the thickness of the wall surface can be measured by reading the scales at the movable ruler 4. The height of the body 1 from the ground can be measured by the laser rangefinder 8. When the thickness of the wall body is required to be measured at a higher position, the supporting mechanism 7 in the storage box 12 is pulled out, the position of the telescopic rod 72 on the fixed rod 71 is adjusted and locked, the telescopic rod 72 is installed on the fixed pipe 11, then the body 1 can be lifted up to measure the thickness of the wall body at the higher position, at the moment, the high-definition camera 54 on the camera mechanism 5 can shoot the scale at the position of the movable ruler 4, a worker can check the thickness data of the wall body on the display screen 73, and when the thickness of the wall body at the higher position is measured, the supporting rod 53 can be driven to rotate through the motor B52, so that the angle of the high-definition camera 54 is adjusted, the high-definition camera 54 faces the level gauge 6, and the body 1 is kept horizontal. The camera shoots and wall thickness and measurement height's data are all stored in the information storage module, make things convenient for the later stage to consult. In measuring the thickness of the wall, the laser transmitter 9 can be activated to emit laser light, which when the laser light strikes a corner of the wall, indicates that the wall is flat, and if the laser light strikes a corner on or away from the wall, indicates that the wall is not flat.

According to the utility model, the wall body can be automatically clamped and measured through the arrangement of the driving mechanism and the contact sensor; the body can be checked and adjusted by a level gauge to keep the body horizontally placed; the height from the ground during wall thickness measurement can be automatically measured. The body can be lifted to a high position through the supporting mechanism, the thickness measurement is carried out on the high position of the wall body, the height of the supporting mechanism can be adjusted, and the supporting mechanism can be detached and stored, so that the space is saved.

The above embodiments are only for illustrating the technical solution of the present utility model, and not for limiting the same; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (10)

1. A building wall thickness detection device comprises a body, a driving mechanism, a fixed ruler, a movable ruler and a level gauge; the method is characterized in that:

the body is fixedly provided with a driving mechanism;

one end of the body is fixedly provided with a fixed ruler which is in running fit with the driving mechanism;

a movable ruler is slidably arranged on the body; the movable ruler is in threaded connection and coordination with the driving mechanism;

the body is fixedly provided with a level gauge; the level gauge is fixedly connected with the movable ruler;

the inner sides of the fixed ruler and the movable ruler are fixedly provided with contact inductors;

the PLC control module and the information storage module are fixedly arranged on the body, and the PLC control module is electrically connected with the driving mechanism.

2. The building wall thickness detection device according to claim 1, wherein: the storage box is fixedly arranged on the body, and a fixing pipe is fixedly arranged on one side of the storage box; a thread groove is formed in the fixed pipe;

a sliding chute A and a sliding chute B are arranged on the body in parallel;

the chute A is arranged in sliding fit with the level gauge;

the outer side of the sliding groove B on the body is fixedly provided with scale marks.

3. The building wall thickness detection device according to claim 1, wherein: the driving mechanism comprises a motor A and a threaded rod;

the motor A is fixedly arranged on the body, a threaded rod is coaxially and fixedly arranged on a rotating shaft of the motor A, and the threaded rod is in threaded connection with the movable ruler.

4. The building wall thickness detection device according to claim 2, wherein: the movable ruler is fixedly provided with a camera shooting mechanism;

the camera shooting mechanism comprises a sliding block, a motor B, a supporting rod and a high-definition camera;

the sliding block is fixedly arranged on the movable ruler and is slidably arranged in the chute B;

a motor B is fixedly arranged on the sliding block, and a supporting rod is fixedly arranged on a rotating shaft of the motor B;

a high-definition camera is fixedly arranged on the supporting rod;

an L-shaped plate is fixedly arranged on the sliding block and fixedly connected with the level gauge.

5. The building wall thickness detection device according to claim 2, wherein: the fixing tube is detachably and fixedly provided with a supporting mechanism;

the supporting mechanism comprises a fixed rod and a telescopic rod;

an adjusting knob is fixedly arranged on the fixing rod; the telescopic rod is slidably arranged on the fixed rod;

the end of the telescopic rod is provided with threads, and the telescopic rod is in threaded fit with the fixed pipe.

6. The building wall thickness detection device according to claim 5, wherein: a display screen is fixedly arranged on the fixed rod and connected with a high-definition camera through a wireless signal; the display screen is provided with a control switch, and the control switch is connected with the PLC control module through a wireless signal.

7. The building wall thickness detection device according to claim 5, wherein: the storage box is provided with a slot matched with the fixing rod.

8. The building wall thickness detection device according to claim 1, wherein: the inner sides of the front ends of the movable ruler and the fixed ruler are fixedly provided with laser transmitters.

9. A building wall thickness detection apparatus according to claim 3, wherein: the movable ruler is fixedly provided with a threaded sleeve, and the threaded sleeve is in threaded fit with the threaded rod.

10. The building wall thickness detection device according to claim 1, wherein: the body is fixedly provided with a laser range finder, and the height of the body from the ground can be measured through the laser range finder.