CN219064500U

CN219064500U - Building supervision verticality detection device

Info

Publication number: CN219064500U
Application number: CN202223586415.0U
Authority: CN
Inventors: 卫张风
Original assignee: Guangdong Zhenzheng Construction Engineering Testing Co ltd
Current assignee: Guangdong Zhenzheng Construction Engineering Testing Co ltd
Priority date: 2022-12-31
Filing date: 2022-12-31
Publication date: 2023-05-23
Anticipated expiration: 2032-12-31

Abstract

The utility model provides a building supervision verticality detection device which comprises a vertical frame, a positioning seat, a contact layer, a measuring structure, a level gauge and a pituitary body, wherein the positioning seat is fixedly connected with the contact layer, the positioning seat is positioned at the top of the vertical frame, the measuring structure is positioned at the inner side of the vertical frame, the level gauge is integrally positioned on the surface of the vertical frame, a rope body is arranged at the outer end of the pituitary body in a matched mode, the top of the vertical frame is fixedly connected with an abutting plate, a driving hand wheel is embedded in the abutting plate, and a driving rod is fixedly connected with the surface of the driving hand wheel. The first coaming and the second coaming form a surrounding frame body to limit the movable range of the pituitary, and the guide rail arranged on the surface of the second coaming can control the guide rod to be integrally and transversely moved and adjusted on the inner side of the second coaming, so that when the pituitary is measured in a vertical state, a user moves the guide rod, and the buffer seat on the surface of the guide rod is contacted with the rope body at the outer end of the pituitary, so that the pituitary is prevented from excessively shaking.

Description

Building supervision verticality detection device

Technical Field

The utility model relates to the technical field of construction detection, in particular to a building supervision perpendicularity detection device.

Background

The perpendicularity is evaluated in a perpendicular state among straight lines, between planes or between straight lines and planes, wherein one straight line or plane is an evaluation reference, the straight line can be a straight line part or a straight line motion track of a measured sample, the plane can be a plane part or a plane formed by a motion track of the measured sample, and in the building industry, in order to ensure construction quality, structures such as wall posts and the like, masonry structures and template engineering, perpendicularity is required to be measured, two persons are required to finish the traditional perpendicularity detection device, more manpower is consumed, the use is inconvenient, and the detection efficiency of the perpendicularity detection device is reduced.

Through research finding, current straightness detection device that hangs down that is used for building engineering quality to detect, whole device size is great, and is inconvenient during the use, and the pole setting case of device bottom needs to be placed subaerial, and ground is comparatively disordered during the job site, and is not taken convenient to use, and when the plumb line is longer moreover, the plumb line is more difficult to be static in the short time of rocking everywhere easily during the use, reduces staff's work efficiency.

The utility model mainly solves the problems that the prior verticality detection device for detecting the quality of the constructional engineering has larger integral device body, is inconvenient to use, is difficult to rest in a short time when the vertical line is easy to shake everywhere when the vertical line is longer, and reduces the working efficiency of staff.

Disclosure of Invention

In order to solve the technical problems, the utility model provides a building supervision verticality detection device to solve the problems described in the background art.

The utility model discloses a building supervision verticality detection device, which is characterized by comprising the following specific technical means: the utility model provides a building is managed straightness detection device that hangs down, includes vertical frame, positioning seat, contact layer, measurement structure, spirit level and pituitary, positioning seat and contact layer fixed connection, and the positioning seat is located vertical frame top, and measurement structure is located vertical frame inboard, and the spirit level is whole to be located vertical frame's surface, and the supporting rope body that sets up of pituitary outer end, vertical frame's top fixedly connected with butt plate, the inside embedding of butt plate is provided with the drive hand wheel, drive hand wheel fixed surface is connected with the actuating lever.

Further, the positioning seat and the contact layer are arranged in a matched mode, the contact layer is integrally arranged to be a rubber layer, and the positioning seat is located at the top position and the bottom position of the inner side of the vertical frame through the butt joint plate.

Further, the level gauge is transversely arranged on the surface position of the vertical frame, and the level gauge is arranged as a visual liquid level gauge.

Further, the pituitary body is connected with the driving hand wheel through a rope body which is connected with the outer end in a matched mode.

Further, the driving hand wheel is manually controlled, the driving rod is arranged at the center of the surface of the driving hand wheel in an L shape, and the driving hand wheel is connected with the rope body which is arranged at the outer end of the pituitary body in a winding way.

Further, the whole first coaming, second coaming, guide bar, buffering seat and the guided way of including of measurement structure, the guided way wholly sets up along the second coaming, first coaming and second coaming fixed connection, guide bar and buffering seat fixed connection.

Further, the first coaming and the second coaming form a surrounding frame body, and the outer side surface of the second coaming is provided with a graduated scale.

Further, the guide rod is integrally and transversely arranged, two ends of the guide rod are slidably embedded into the guide rail, and the buffer seat is arranged in a trapezoid protruding mode along the surface of the guide rod and is located at the inner side of the second enclosing plate.

The beneficial effects are that:

1. the whole device is convenient to contact with the surface of the wall body vertically through the positioning seat and the contact layer, so that the inclination of the wall body is measured according to the vertical and horizontal degrees of the wall body.

2. The horizontal level degree of the whole device when the device is attached to the wall surface is detected through a level meter.

3. The whole pituitary body is controlled by driving the hand wheel, and the effect of inclination measurement on different height positions of the external wall surface is achieved by controlling the height of the pituitary body.

4. The first coaming plate and the second coaming plate form a surrounding frame body to limit the movable range of the pituitary, and the guide rail arranged on the surface of the second coaming plate can control the guide rod to be integrally and transversely moved and adjusted on the inner side of the second coaming plate, so that when the pituitary is measured in a vertical state, a user moves the guide rod, a buffer seat on the surface of the guide rod is contacted with a rope body at the outer end of the pituitary, and the pituitary is prevented from excessively shaking, so that the pituitary is stabilized to measure as soon as possible.

Drawings

Fig. 1 is a side view of the overall structure of the present utility model.

FIG. 2 is a schematic diagram of the connection of the measuring structure of the present utility model.

Fig. 3 is an enlarged view of the structure of fig. 1 a according to the present utility model.

In fig. 1 to 3, the correspondence between the component names and the reference numerals is:

the device comprises a 1-vertical frame, a 2-positioning seat, a 3-contact layer, a 4-measuring structure, a 5-level meter, a 6-pituitary, a 7-first enclosing plate, an 8-second enclosing plate, a 9-guide rod, a 10-buffer seat, an 11-guide rail, a 12-butt plate, a 13-driving hand wheel and a 14-driving rod.

Detailed Description

The technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are only some embodiments of the present utility model, but not all embodiments, and all other embodiments obtained by those skilled in the art without making any inventive effort based on the embodiments of the present utility model are within the scope of protection of the present utility model.

Examples:

as shown in fig. 1 to 3:

example 1: the utility model provides a building supervision straightness detection device that hangs down, including perpendicular frame 1, positioning seat 2, contact layer 3, measurement structure 4, spirit level 5 and pituitary 6, positioning seat 2 and contact layer 3 fixed connection, positioning seat 2 is located perpendicular frame 1 top, measurement structure 4 is located perpendicular frame 1 inboard, spirit level 5 wholly is located perpendicular frame 1's surface, the supporting rope body that sets up of pituitary 6 outer ends, perpendicular frame 1's top fixedly connected with butt plate 12, butt plate 12's inside embedding is provided with driving hand wheel 13, driving hand wheel 13 fixed surface has actuating lever 14.

Wherein: the positioning seat 2 and the contact layer 3 are arranged in a matched manner, the contact layer 3 is integrally arranged as a rubber layer, and the positioning seat 2 is positioned at the top position and the bottom position of the inner side of the vertical frame 1 through the butt joint plate 12;

the whole device is convenient to contact with the surface of the wall body vertically through the positioning seat 2 and the contact layer 3, so that the inclination of the wall body is measured according to the vertical and horizontal degrees of the wall body.

Wherein: the level gauge 5 is transversely arranged on the surface position of the vertical frame 1, and the level gauge 5 is arranged as a visual liquid level gauge;

the horizontal level of the whole device when the wall is attached is detected through the level meter 5.

Wherein: the pituitary 6 is connected with the driving hand wheel 13 through a rope body which is connected with the outer end in a matched way;

wherein: the driving hand wheel 3 is manually controlled, the driving rod 14 is arranged at the center of the surface of the driving hand wheel 3 in an L shape, and the driving hand wheel 3 is connected with the rope body which is arranged at the outer end of the pituitary 6 in a winding way;

the whole pituitary 6 is controlled by driving the hand wheel 3, and the effect of inclination measurement on different height positions of the external wall surface is achieved by controlling the height of the pituitary 6.

Example 2: referring to fig. 1-3 of the specification, embodiment 2 is different from embodiment 1 in that the measuring structure 4 integrally includes a first enclosing plate 7, a second enclosing plate 8, a guide rod 9, a buffer seat 10 and a guide rail 11, the guide rail 11 integrally is disposed along the second enclosing plate 8, the first enclosing plate 7 is fixedly connected with the second enclosing plate 8, and the guide rod 9 is fixedly connected with the buffer seat 10.

Wherein: the first enclosing plate 7 and the second enclosing plate 8 form an enclosing frame body, and the outer side surface of the second enclosing plate 8 is provided with a graduated scale;

wherein: the guide rod 9 is integrally and transversely arranged, two ends of the guide rod are slidably embedded in the guide rail 11, and the buffer seat 10 is arranged in a trapezoid protruding mode along the surface of the guide rod 9 and is positioned at the inner side of the second enclosing plate 8;

the first enclosing plate 7 and the second enclosing plate 8 form an enclosing frame body to limit the movable range of the pituitary gland 6, and the guide rail 11 formed on the surface of the second enclosing plate 8 controls the whole guide rod 9 to transversely move and adjust on the inner side of the second enclosing plate 8, so that when the pituitary gland 6 is measured in a vertical state, a user moves the guide rod 9, and the buffer seat 10 on the surface of the guide rod 9 is contacted with a rope body at the outer end of the pituitary gland 6, so that the pituitary gland is prevented from excessively shaking, and the pituitary gland 6 is stabilized to measure as soon as possible.

Claims

1. Building supervision straightness detection device that hangs down, its characterized in that: including perpendicular frame (1), positioning seat (2), contact layer (3), measurement structure (4), spirit level (5) and pituitary (6), positioning seat (2) and contact layer (3) fixed connection, positioning seat (2) are located perpendicular frame (1) top, measurement structure (4) are located perpendicular frame (1) inboard, spirit level (5) wholly are located perpendicular frame (1) surface, the supporting rope body that sets up of pituitary (6) outer end, perpendicular frame (1) top fixedly connected with butt joint board (12), the inside embedding of butt joint board (12) is provided with driving hand wheel (13), driving hand wheel (13) fixed surface has actuating lever (14).

2. The building supervision verticality detection device according to claim 1, wherein: the positioning seat (2) and the contact layer (3) are arranged in a matched mode, the contact layer (3) is integrally arranged to be a rubber layer, and the positioning seat (2) is located at the top position and the bottom position of the inner side of the vertical frame (1) through the butt joint plate (12).

3. The building supervision verticality detection device according to claim 1, wherein: the level gauge (5) is transversely arranged on the surface of the vertical frame (1), and the level gauge (5) is arranged as a visual liquid level gauge.

4. The building supervision verticality detection device according to claim 1, wherein: the pituitary (6) is connected with the driving hand wheel (13) through a rope body with matched connection at the outer end.

5. The building supervision verticality detection device according to claim 1, wherein: the driving hand wheel (13) is manually controlled, the driving rod (14) is arranged at the center of the surface of the driving hand wheel (13) in an L shape, and the driving hand wheel (13) is connected with the rope body which is arranged at the outer end of the pituitary body (6) in a winding way.

6. The building supervision verticality detection device according to claim 1, wherein: the measuring structure (4) integrally comprises a first enclosing plate (7), a second enclosing plate (8), a guide rod (9), a buffer seat (10) and a guide rail (11), wherein the guide rail (11) is integrally arranged along the second enclosing plate (8), the first enclosing plate (7) and the second enclosing plate (8) are fixedly connected, and the guide rod (9) and the buffer seat (10) are fixedly connected.

7. The building supervision verticality detection device according to claim 6, wherein: the first enclosing plate (7) and the second enclosing plate (8) form an enclosing frame body, and the outer side surface of the second enclosing plate (8) is provided with a graduated scale.

8. The building supervision verticality detection device according to claim 6, wherein: the guide rod (9) is integrally and transversely arranged, two ends of the guide rod are slidably embedded into the guide rail (11), and the buffer seat (10) is arranged in a trapezoid protruding mode along the surface of the guide rod (9) and is located at the inner side of the second enclosing plate (8).