CN220356362U - Building engineering straightness detection device that hangs down - Google Patents

Abstract

The utility model discloses a building engineering verticality detection device, which relates to the technical field of verticality detection and comprises a device main body, wherein a groove is formed in one side of the device main body, a first sliding column is installed in the groove, a first sliding block is connected to the outer wall of the first sliding column, and a detection device box is connected to one side of the first sliding block. According to the utility model, the connecting belt, the fixed hooks, the reset springs, the I-shaped columns, the U-shaped blocks and the rotating columns are matched with each other, the connecting belt is pulled according to the requirements, the rotating columns on the two sides of the I-shaped columns rotate on the U-shaped blocks until the connecting belt is pulled to the required length, the fixed hooks are pulled by hands to hook the connecting belt, the reset springs at the bottoms of the fixed hooks are matched with the telescopic columns, a pull-back pulling force can be provided for the fixed hooks, and the auxiliary fixing structures on the two sides of the connecting belt simply and efficiently fix the positions of the connecting belt, so that the effect of conveniently adjusting the length of a hanging wire is achieved.

Description

Building engineering straightness detection device that hangs down

Technical Field

The utility model relates to the technical field of verticality detection, in particular to a building engineering verticality detection device.

Background

The perpendicularity is a tolerance requirement for controlling the included angle between the measured element and the reference element to be ninety degrees in the direction tolerance, and is divided into perpendicularity requirements of a given plane, a given direction and any direction. The perpendicularity is evaluated as the perpendicularity between straight lines, between planes, or between straight lines and planes, according to the characteristics of the measured element and the reference element. For a building, in main construction, control measurement of building verticality is an important measurement key point, control of building verticality is an important influencing factor of construction quality, and most common and economical building engineering verticality detection devices generally detect verticality through a mode of hanging and paying off a vertical support plate, a horizontal transverse plate, a hanging rope and a heavy hammer.

The following problems exist in the prior art:

1. the most common and economic type constructional engineering verticality detection in the prior art adopts a hanging paying-off mode, and when the verticality of a transverse horizontal plane of a building is measured, the building cannot be influenced by gravity, so that the application is limited, and the measurement cost is too high by completely adopting precise electronic equipment;

2. the lower plumb bob of cost is because the structure is simple to be off-line, does not have the function of conveniently adjusting the plumb bob length, just makes the detection data list have no comparison reference, can have the error, reduces the precision of device.

Disclosure of Invention

The utility model provides a building engineering verticality detection device, which aims to provide a technology for measuring the verticality of a transverse horizontal plane of a building and solve the problem that the verticality of the transverse horizontal plane of the building cannot be lost due to gravity and the application is limited; the other purpose is that the plumb bob is simple owing to the structure is biased to the lower cost, does not have the function of conveniently adjusting the plumb length, just makes the detection data list nothing can be compared the reference, can have the error, reduces the problem of the precision of device to reach the effect that has the function of conveniently adjusting the plumb length, improve the precision of device.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the utility model provides a building engineering straightness detection device that hangs down, includes the device main part, one side inside of device main part is provided with the recess, the internally mounted of recess has first slip post, the outer wall connection of first slip post has first slider, one side of first slider is connected with the detection device case, the bottom of detection device case is provided with the contrast scale, the inside of detection device case is provided with first mounting hole, the top of first mounting hole is provided with the second mounting hole, the internally mounted of second mounting hole has the second slip post, the outer wall connection of second slip post has the second slider, the top of second slider is connected with the laser pen, one side of laser pen is provided with the switch, the top of detection device case is provided with vertical direction detection component, vertical direction detection component includes pointer, contrast calibrated scale and heavy object, the bottom of pointer is connected with the outer rotation post, the inside of outer rotation post is provided with the internal rotation post, the bottom of outer rotation post is connected with the connecting rod, the bottom of connecting rod is connected with the second slider, the auxiliary structure is provided with the U type post, the auxiliary structure is connected with the fixed connection type post, one side is connected with the fixed knot and is connected with the type post.

The technical scheme of the utility model is further improved as follows: the device is characterized in that one side of the device main body is provided with eleven anti-skid pads, and the eleven anti-skid pads are distributed at equal intervals on one side and the bottom of the device main body.

By adopting the technical scheme, the anti-slip pad in the scheme can increase the friction force between the device and the detected surface and increase the stability of the device.

The technical scheme of the utility model is further improved as follows: auxiliary rolling balls are arranged between the outer rotating column and the inner rotating column, ten auxiliary rolling balls are arranged, and gaps exist among the ten auxiliary rolling balls.

By adopting the technical scheme, the auxiliary rolling ball in the scheme can increase the smoothness of the rotation between the outer rotating column and the inner rotating column, and reduce the possibility of error.

The technical scheme of the utility model is further improved as follows: the bottom of fixed knot constructs is provided with fixed block one, reset spring is installed at the top of fixed block one, reset spring's inside is provided with the flexible post, reset spring's top is provided with fixed block two.

By adopting the technical scheme, the reset spring in the scheme has a certain elastic movable range, and the fixing structure can fix the position of the connecting belt so as to adjust the paying-off length.

The technical scheme of the utility model is further improved as follows: the top of the second fixed block is connected with a fixed hook, and the top of the fixed hook is in a sharp state.

By adopting the technical scheme, the connecting belt can be hooked by the sharp-state fixed hooks in the scheme, the sharp points penetrate through the connecting belt, and when the connecting belt is placed at the turning positions of the fixed hooks, the connecting belt is fixed through simple operation.

By adopting the technical scheme, compared with the prior art, the utility model has the following technical progress:

the utility model provides a building engineering verticality detection device, which is characterized in that a laser pen, a comparison graduated scale, a switch, a second sliding block and a second sliding column are adopted to be matched, if the verticality of the horizontal direction of a related structure is required to be detected, the side edge of a device main body is placed on a detection surface, the switch is firstly turned on, the comparison graduated scale at the bottom of the device main body is irradiated by the laser pen, the graduation is recorded to determine the basic height of the switch, then the second sliding block is rotated on the second sliding column, a point is emitted by the laser pen along the top opening of the device main body to irradiate on a plane of a vertical horizontal plane, the measured height between the bottom and an irradiated point is measured by an external graduated scale, and the height difference between the basic height and the measured height is calculated in a comparison mode, so that the verticality in the horizontal direction can be calculated.

The utility model provides a building engineering verticality detection device, which is characterized in that a connecting belt, a fixed hook, a reset spring, an I-shaped column, a U-shaped block and a rotating column are matched with each other, the connecting belt is pulled according to requirements, the rotating columns on two sides of the I-shaped column rotate on the U-shaped block until the connecting belt is pulled to a required length, the fixed hook is pulled by hands to hook the connecting belt, the reset spring at the bottom of the fixed hook is matched with the telescopic column, a pull-back pulling force can be provided for the fixed hook, and auxiliary fixing structures on two sides of the connecting belt simply and efficiently fix the position of the connecting belt, so that the effect of conveniently adjusting the length of a hanging wire is achieved.

Drawings

FIG. 1 is a schematic perspective view of a device body according to the present utility model;

FIG. 2 is a schematic perspective view of a detection device box according to the present utility model;

FIG. 3 is a schematic plan view of a vertical direction detecting unit according to the present utility model;

fig. 4 is a schematic plan view of the fixing structure of the present utility model.

In the figure: 1. a device body; 11. a groove; 12. a first sliding column; 13. an anti-slip pad; 14. comparing with a graduated scale; 15. a first slider; 2. a detection device box; 21. a first mounting hole; 22. a second mounting hole; 23. a second sliding column; 24. a second slider; 25. a laser pen; 26. a switch; 3. a vertical direction detection assembly; 31. a pointer; 32. comparing the dial plate; 33. an outer rotating column; 34. an inner rotating column; 35. an auxiliary ball; 36. a connecting rod; 37. a weight block; 4. an auxiliary fixing structure; 41. a U-shaped block; 42. an I-shaped column; 43. rotating the column; 44. a fixed structure; 441. a first fixed block; 442. a return spring; 443. a telescopic column; 444. a second fixed block; 445. a fixed hook; 45. and (5) connecting the belts.

Description of the embodiments

The utility model is further illustrated by the following examples:

examples

As shown in fig. 1 to 4, the utility model provides a constructional engineering verticality detection device, which comprises a device main body 1, a groove 11 is arranged inside one side of the device main body 1, a first sliding column 12 is arranged inside the groove 11, a first sliding block 15 is connected to the outer wall of the first sliding column 12, a detection device box 2 is connected to one side of the first sliding block 15, a contrast graduated scale 14 is arranged at the bottom of the detection device box 2, a first mounting hole 21 is arranged inside the detection device box 2, a second mounting hole 22 is arranged at the top of the first mounting hole 21, a second sliding column 23 is arranged inside the second mounting hole 22, a second sliding block 24 is connected to the outer wall of the second sliding column 23, a laser pen 25 is connected to the top of the second sliding block 24, a switch 26 is arranged on one side of the laser pen 25, a vertical direction detection assembly 3 is arranged at the top of the detection device box 2, and eleven anti-skid pads 13 are distributed on one side and the bottom of the device main body 1 at equal intervals.

In this embodiment, when the verticality of the vertical direction of the related structure needs to be detected, the bottom of the device main body 1 is placed on the detection surface, the vertical direction detection component 3 is observed, if the verticality of the horizontal direction of the related structure needs to be detected, the side edge of the device main body 1 is placed on the detection surface, the switch 26 is turned on, the laser pen 25 is used for irradiating the reference scale 14 on the bottom of the device main body 1, the scale is recorded to determine the basic height of the switch 26, then the second slide block 24 is rotated on the second slide column 23, the laser pen 25 emits a point along the top opening of the device main body 1 to irradiate on a plane of the vertical horizontal plane, the detected height from the bottom to the irradiation point is measured by using the external scale, and the height difference between the basic height and the detected height is calculated in a comparison mode.

Examples

As shown in fig. 1 to 4, the present utility model provides a construction verticality detecting device, a vertical direction detecting assembly 3 includes a pointer 31, a reference dial 32 and a weight 37, the bottom of the pointer 31 is connected with an outer rotating column 33, an inner rotating column 34 is provided inside the outer rotating column 33, the bottom of the outer rotating column 33 is connected with a connecting rod 36, auxiliary rolling balls 35 are provided between the outer rotating column 33 and the inner rotating column 34, ten auxiliary rolling balls 35 are provided, and gaps exist between the ten auxiliary rolling balls 35.

In this embodiment, when the bottom of the device body 1 is placed on the detection surface, the connection belt 45 is pulled as required, the rotation columns 43 on both sides of the i-shaped column 42 rotate on the U-shaped block 41 until the connection belt 45 is pulled to a required length, and the connection belt is fixed by the auxiliary fixing structure 4, and under the action of gravity applied by the weight 37, the weight 37 drives the pointer 31 to start swinging, and the scale of the pointer 31 on the reference dial 32 is read, so as to achieve the purpose of verticality detection.

Examples

As shown in fig. 1-4, the utility model provides a building engineering verticality detection device, the bottom of a connecting rod 36 is connected with an auxiliary fixing structure 4, the auxiliary fixing structure 4 comprises a U-shaped block 41, an i-shaped column 42 is arranged in the U-shaped block 41, one side of the i-shaped column 42 is connected with a rotating column 43, a connecting belt 45 is installed on the outer wall of the i-shaped column 42, a fixing structure 44 is installed on one side of the connecting belt 45, a first fixing block 441 is arranged at the bottom of the fixing structure 44, a reset spring 442 is installed at the top of the first fixing block 441, a telescopic column 443 is arranged in the reset spring 442, a second fixing block 444 is arranged at the top of the reset spring 442, a fixed hook 445 is connected at the top of the second fixing block 444, and the top of the fixed hook 445 is in a sharp state.

In this embodiment, after the connecting band 45 is pulled according to the required length, the fixing hook 445 is pulled by hand to hook the connecting band 45, and the return spring 442 and the telescopic column 443 at the bottom of the fixing hook 445 are mutually matched, so that a pull-back tension can be provided for the fixing hook 445, and the auxiliary fixing structures 4 at two sides of the connecting band 45 simply and efficiently fix the position of the connecting band 45.

The working principle of the building engineering verticality detection device is specifically described below.

As shown in fig. 1-4, when the verticality of the vertical direction of the related structure needs to be detected, the bottom of the device main body 1 is placed on the detection surface, the connecting belt 45 is pulled according to the requirement, the rotating columns 43 on two sides of the i-shaped column 42 rotate on the U-shaped block 41 until the connecting belt 45 is pulled to the required length, the fixed hook 445 is pulled by hands to hook the connecting belt 45, the return spring 442 and the telescopic column 443 on the bottom of the fixed hook 445 are matched with each other, a pull-back pulling force can be provided for the fixed hook 445, the auxiliary fixed structures 4 on two sides of the connecting belt 45 simply and efficiently fix the position of the connecting belt 45, the weight 37 drives the pointer 31 to swing under the action of the gravity of the weight 37, the scale of the pointer 31 is read on the reference scale 32 so as to achieve the aim of detecting the verticality, and if the verticality of the horizontal direction of the related structure needs to be detected. The side of the device main body 1 is placed on the detection surface, the switch 26 is firstly turned on, the laser pen 25 irradiates the comparison graduated scale 14 at the bottom of the device main body 1, the graduation is recorded to determine the basic height of the switch 26, then the second sliding block 24 rotates on the second sliding column 23, the laser pen 25 irradiates a point on a plane of the vertical horizontal plane along the top opening of the device main body 1, the external graduated scale is used for measuring the measured height from the bottom to the irradiation point, and the height difference between the basic height and the measured height is calculated in a contrasting manner to be used for calculating the verticality.

The foregoing utility model has been generally described in great detail, but it will be apparent to those skilled in the art that modifications and improvements can be made thereto. Accordingly, it is intended to cover modifications or improvements within the spirit of the inventive concepts.

Claims (5)

1. The utility model provides a building engineering straightness detection device that hangs down, includes device main part (1), the inside recess (11) that is provided with in one side of device main part (1), the internally mounted of recess (11) has first slip post (12), the outer wall connection of first slip post (12) has first slider (15), its characterized in that: one side of the first sliding block (15) is connected with a detection device box (2), the bottom of the detection device box (2) is provided with a comparison graduated scale (14), the inside of the detection device box (2) is provided with a first mounting hole (21), the top of the first mounting hole (21) is provided with a second mounting hole (22), the inside of the second mounting hole (22) is provided with a second sliding column (23), the outer wall of the second sliding column (23) is connected with a second sliding block (24), the top of the second sliding block (24) is connected with a laser pen (25), one side of the laser pen (25) is provided with a switch (26), and the top of the detection device box (2) is provided with a vertical direction detection component (3);

the vertical direction detection assembly (3) comprises a pointer (31), a comparison dial (32) and a weight block (37), wherein an outer rotating column (33) is connected to the bottom of the pointer (31), an inner rotating column (34) is arranged in the outer rotating column (33), and a connecting rod (36) is connected to the bottom of the outer rotating column (33), and the vertical direction detection assembly is characterized in that: the bottom of connecting rod (36) is connected with supplementary fixed knot constructs (4), supplementary fixed knot constructs (4) including U type piece (41), the inside of U type piece (41) is provided with I type post (42), one side of I type post (42) is connected with rotates post (43), connecting band (45) are installed to the outer wall of I type post (42), fixed knot constructs (44) are installed to one side of connecting band (45).

2. The construction perpendicularity detection device according to claim 1, wherein: one side of the device main body (1) is provided with anti-slip pads (13), the number of the anti-slip pads (13) is eleven, and the eleven anti-slip pads (13) are distributed and arranged on one side and the bottom of the device main body (1) at equal intervals.

3. The construction perpendicularity detection device according to claim 1, wherein: auxiliary rolling balls (35) are arranged between the outer rotating column (33) and the inner rotating column (34), ten auxiliary rolling balls (35) are arranged, and gaps exist among the ten auxiliary rolling balls (35).

4. The construction perpendicularity detection device according to claim 1, wherein: the bottom of fixed knot constructs (44) is provided with fixed block one (441), reset spring (442) are installed at the top of fixed block one (441), reset spring (442)'s inside is provided with flexible post (443), reset spring (442)'s top is provided with fixed block two (444).

5. The construction perpendicularity detection device according to claim 4, wherein: the top of the second fixed block (444) is connected with a fixed hook (445), and the top of the fixed hook (445) is in a sharp state.