CN220170255U - Portable wall body straightness calibrating tool that hangs down - Google Patents

Abstract

The utility model discloses a portable wall perpendicularity calibration tool which comprises a base, a support rod and a hack lever, wherein the support rod is arranged on one side of the base, and the hack lever is rotatably arranged on the support rod; the utility model discloses a laser beam calibration wall body, including hack lever, hack lever top is provided with the spirit level, hack lever bottom slip is provided with the laser emission platform, and this spirit level is used for calibrating the hack lever level, makes the vertical laser ray calibration wall body straightness that hangs down of laser emission platform emission. The utility model can be placed on one side of a built wall body, the level of a hack lever is regulated according to a level meter, and then the laser emission table is started to generate vertical laser rays for calibrating the perpendicularity of the wall body, so that the problem that the perpendicularity of the wall body is difficult to calibrate accurately in a traditional visual inspection or hanging line plumb calibration mode is solved, when the height of the laser emission table needs to be regulated, the number of connecting rods of the supporting rod can be increased, and when the distance between the laser rays and the wall body needs to be regulated, the laser emission table can be pushed to slide for regulation.

Description

Portable wall body straightness calibrating tool that hangs down

Technical Field

The utility model relates to a portable wall perpendicularity calibration tool.

Background

In building construction, the masonry wall is very important construction operation, the verticality of the masonry wall, namely the verticality of the wall and the ground, not only can influence the aesthetic degree of a building, but also can influence the structural stability and the service life of the building, if the verticality of the wall is insufficient, the wall is easily influenced by external factors to have the problems of inclination, cracking and the like, and serious consequences such as wall collapse can be caused after long-term use;

the perpendicularity calibration mode adopted in the traditional wall building process is generally visual measurement or calibration by using a hanging wire plumb, the error of the first visual measurement calibration mode is large, the second hanging wire plumb calibration mode is not only needed to be handheld, but also unstable and easy to shake to influence the calibration, and therefore the utility model provides a portable wall perpendicularity calibration tool for solving the problems.

Disclosure of Invention

The utility model aims to provide a portable wall perpendicularity calibration tool, which solves the problem that the perpendicularity calibration mode adopted in the traditional wall building process in the background technology is generally visual inspection or plumb bob calibration, and the perpendicularity of the wall cannot be accurately calibrated in both modes.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the portable wall perpendicularity calibration tool comprises a base, a support rod and a hack lever, wherein the support rod is arranged on one side of the base, and the hack lever is rotatably arranged on the support rod;

the top of the hack lever is provided with a level meter, the bottom of the hack lever is provided with a laser emitting table in a sliding way, the level gauge is used for calibrating the level of the hack lever to enable the laser emission table to emit vertical laser rays to calibrate the perpendicularity of the wall;

the base is also provided with a solar cell panel, and the solar cell panel is electrically connected with the laser emission table to supply power for the laser emission table.

Further, the support rod comprises a push rod and a plurality of connecting rods, the push rod and the connecting rods are of hollow structures, a pin head is arranged at one end of each connecting rod, and the push rod and the connecting rods are spliced end to form the support rod structure.

Further, a pin rod is arranged on the base, and the supporting rod is inserted and installed on one side of the base through the pin rod.

Furthermore, a slotted hole is formed in one end of the hack lever, the supporting rod is inserted into the slotted hole of the hack lever, and the intersecting part of the supporting rod and the hack lever is penetrated by the pin shaft to form the hack lever rotation arrangement.

Further, the contained angle department of bracing piece and hack lever still is provided with electric telescopic handle, electric telescopic handle's both ends rotate with bracing piece and hack lever respectively and are connected, and this electric telescopic handle is connected for its power supply with solar cell panel electricity, and electric telescopic handle still is connected the regulation and control body of rod with the controller electricity and is flexible to regulate and control the hack lever and rotate.

Further, the bottom of the hack lever is provided with a sliding rail, and the laser emitting table is slidably mounted on the sliding rail.

Further, the top of the laser emission table is provided with a chute, and the chute of the laser emission table is matched with the track of the sliding rail and is of a T-shaped assembly structure so as to form the sliding arrangement of the laser emission table.

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

the utility model can be placed on one side of a built wall body, the level of a hack lever is regulated according to a level meter, and then the laser emission table is started to generate vertical laser rays for calibrating the perpendicularity of the wall body, so that the problem that the perpendicularity of the wall body is difficult to calibrate accurately in a traditional visual inspection or hanging line plumb calibration mode is solved, when the height of the laser emission table needs to be regulated, the number of connecting rods of the supporting rod can be increased, and when the distance between the laser rays and the wall body needs to be regulated, the laser emission table can be pushed to slide for regulation.

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 base and the connecting rod of the present utility model;

fig. 3 is a schematic structural view of the ejector pin and the rack bar according to the present utility model.

In the figure: 1. a base; 2. a support rod; 21. a push rod; 22. a connecting rod; 221. a pin head; 3. a hack lever; 4. A level gauge; 5. a laser emitting stage; 6. a solar cell panel; 7. a pin rod; 8. an electric telescopic rod; 9. a slide rail.

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. 1-3, a portable wall perpendicularity calibration tool comprises a base 1, a support rod 2 and a support rod 3, wherein the support rod 2 is arranged on one side of the base 1, and the support rod 3 is rotatably arranged on the support rod 2;

the top of the hack lever 3 is provided with a level meter 4, the bottom of the hack lever 3 is provided with a laser emission table 5 in a sliding manner, and the level meter 4 is used for calibrating the level of the hack lever 3, so that the laser emission table 5 emits vertical laser rays to calibrate the verticality of a wall;

the base 1 is also provided with a solar panel 6, which solar panel 6 is electrically connected with the laser emitting table 5 for supplying power thereto.

In this embodiment, the support rod 2 includes a push rod 21 and a plurality of connecting rods 22, where the push rod 21 and the connecting rods 22 are hollow structures, one end of the connecting rod 22 is provided with a pin head 221, and the push rod 21 and the plurality of connecting rods 22 are spliced end to form the support rod 2 structure;

the structure of the support rod 2 can adjust the length of the support rod 2 through adjusting the connecting rod 22, so that the support rod 2 can be suitable for the height of a masonry wall;

the base 1 is provided with a pin rod 7, and the supporting rod 2 is inserted and connected with the pin rod 7 to be installed on one side of the base 1, so that the supporting rod 2 can be conveniently disassembled and assembled.

In the embodiment, a slotted hole is formed in one end of the hack lever 3, the supporting rod 2 is inserted into the slotted hole of the hack lever 3, and the intersection of the supporting rod 2 and the hack lever 3 is penetrated by a pin shaft to form a rotary arrangement of the hack lever 3;

an electric telescopic rod 8 is further arranged at the included angle between the support rod 2 and the hack lever 3, two ends of the electric telescopic rod 8 are respectively connected with the support rod 2 and the hack lever 3 in a rotating mode, the electric telescopic rod 8 is electrically connected with the solar panel 6 to supply power to the electric telescopic rod, and the electric telescopic rod 8 is further electrically connected with the controller to regulate and control the rod body to stretch, so that the hack lever 3 is regulated and controlled to rotate;

the laser emission table 5 and the electric telescopic rod 8 are connected with a long wire, the wire is routed from the inside of the supporting rod 2, the end part of the wire is connected with a plug, the wire of the solar cell panel 6 is routed in the base 1, the end part of the wire is connected with a slot at the top of the pin rod 7, when the supporting rod 2 is installed, the plug of the long wire is inserted into the slot of the pin rod 7 to be connected, and then the supporting rod 2 is installed on the pin rod 7, so that the solar cell panel 6 can supply power for the laser emission table 5 and the electric telescopic rod 8, and the electric telescopic rod 8 is also connected with an external controller for regulating and controlling the expansion of a rod body;

according to the level 4, the electric telescopic rod 8 is regulated and controlled to push the hack lever 3 to rotate until the level is reached, so that the laser emitting table 5 can emit vertical laser rays.

In the embodiment, a sliding rail 9 is arranged at the bottom of the hack lever 3, and the laser emitting table 5 is slidably arranged on the sliding rail 9;

the top of the laser emission table 5 is provided with a chute, and the chute of the laser emission table 5 is matched with the track of the sliding rail 9 and is of a T-shaped assembly structure so as to form a sliding arrangement of the laser emission table 5;

when the distance between the laser ray and the wall body needs to be adjusted, the laser emitting table 5 can be pushed to slide for adjustment.

When the utility model is specifically used, the calibration tool is placed on one side of a masonry wall, the hack lever 3 is close to the wall and is positioned above the masonry wall, the number of connecting rods 22 of the supporting rod 2 can be increased according to the stacking height of the wall, the height of the hack lever 3 is adjusted to be suitable for the use, the electric telescopic rod 8 is started, the hack lever 3 is pushed to rotate by the electric telescopic rod 8, the micro-adjustment of the level meter 4 is carried out until the hack lever 3 is horizontal, the laser emitting table 5 is started to emit vertical laser rays for calibrating the verticality of the wall, and when the distance between the laser rays and the wall is required to be adjusted, the laser emitting table 5 can be pushed to slide for adjustment.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (7)

1. A portable wall body straightness calibrating tool that hangs down, its characterized in that: the novel lifting device comprises a base (1), a supporting rod (2) and a hack lever (3), wherein the supporting rod (2) is arranged on one side of the base (1), and the hack lever (3) is rotatably arranged on the supporting rod (2);

the top of the hack lever (3) is provided with a level meter (4), the bottom of the hack lever (3) is provided with a laser emission table (5) in a sliding manner, and the level meter (4) is used for calibrating the level of the hack lever (3) so that the laser emission table (5) emits vertical laser rays to calibrate the verticality of a wall;

the base (1) is also provided with a solar cell panel (6), and the solar cell panel (6) is electrically connected with the laser emitting table (5) to supply power to the laser emitting table.

2. The portable wall perpendicularity calibration tool of claim 1, wherein: the support rod (2) comprises a top rod (21) and a plurality of connecting rods (22), wherein the top rod (21) and the connecting rods (22) are hollow structures, pin heads (221) are arranged at one ends of the connecting rods (22), and the top rod (21) and the connecting rods (22) are spliced end to form the support rod (2) structure.

3. The portable wall perpendicularity calibration tool of claim 2, wherein: the base (1) is provided with a pin (7), and the supporting rod (2) is inserted and installed on one side of the base (1) through the pin (7).

4. The portable wall perpendicularity calibration tool of claim 1, wherein: one end of the hack lever (3) is provided with a slotted hole, the supporting rod (2) is inserted into the slotted hole of the hack lever (3), and the intersection of the supporting rod (2) and the hack lever (3) is penetrated by a pin shaft to form the rotary setting of the hack lever (3).

5. The portable wall perpendicularity calibration tool of claim 1, wherein: the electric telescopic rod comprises a support rod (2) and a rack rod (3), wherein an electric telescopic rod (8) is further arranged at the included angle between the support rod (2) and the rack rod (3), two ends of the electric telescopic rod (8) are respectively connected with the support rod (2) and the rack rod (3) in a rotating mode, the electric telescopic rod (8) is electrically connected with a solar cell panel (6) to supply power to the electric telescopic rod, and the electric telescopic rod (8) is electrically connected with a controller to regulate and control rod body to stretch, so that the rack rod (3) is regulated and controlled to rotate.

6. The portable wall perpendicularity calibration tool of claim 1, wherein: the bottom of the hack lever (3) is provided with a sliding rail (9), and the laser emitting table (5) is slidably arranged on the sliding rail (9).

7. The portable wall perpendicularity calibration tool of claim 6, wherein: the top of the laser emission table (5) is provided with a chute, and the chute of the laser emission table (5) is matched with the track of the sliding rail (9) and is of a T-shaped assembly structure so as to form the sliding arrangement of the laser emission table (5).