CN219656893U - Civil engineering wall body straightness calibrating device that hangs down - Google Patents

Abstract

The utility model discloses a device for calibrating verticality of a civil wall, and relates to the field of civil engineering. Civil engineering wall body straightness calibrating device that hangs down, including base and horizontal adjustment mechanism, horizontal adjustment mechanism installs on the base, still includes: the multi-section electric hydraulic push rods are symmetrically arranged on two sides of the base; the top plate is arranged at the telescopic ends of the two multi-section electric hydraulic push rods; the first connecting ropes are symmetrically arranged on one side of the base, and two ends of each first connecting rope are respectively connected with the base and the top plate; the counterweight plate is connected to the two first connecting ropes in a sliding manner; compared with the mode of detecting the perpendicularity by adopting a single connecting rope to be matched with a plumb in the prior art, the distance meter in the device can stably move under the matching of the first connecting rope and the counterweight plate, so that the fluctuation amount of the distance meter in moving is reduced, and the accuracy of detecting and calibrating the perpendicularity of a wall body is effectively improved.

Description

Civil engineering wall body straightness calibrating device that hangs down

Technical Field

The utility model belongs to the technical field of civil engineering, and particularly relates to a device for calibrating verticality of a civil wall.

Background

Civil engineering, i.e. civil engineering and construction engineering, is a generic term for civil engineering and construction engineering, and is an engineering subject for building various facilities and places for activities such as human life, production, protection, etc., covering buildings and facilities in places in various engineering fields such as houses, roads, railways, airports, bridges, etc. in various fields such as above-ground, underground, land, above-water, underwater, etc.

The prior art has the following problems: wall perpendicularity calibration devices are often required to be used in civil engineering, but the existing calibration devices cannot adjust positions between the devices and the wall surfaces according to the thickness of the building wall, and the existing devices cannot specifically adjust the perpendicularity of the measured part of the wall surfaces according to requirements during measurement, and cannot intuitively obtain a difference of wall perpendicularity measurement during measurement.

In the prior art, application number is CN202022499461.1, the name is a wall body perpendicularity calibrating device for civil engineering, and the wall body perpendicularity calibrating device for civil engineering is disclosed, and comprises a shell which is arranged in a concave structure, wherein a sliding groove is fixedly arranged on the top end surface of the shell, a hook sliding block is slidably connected on the top end surface of the sliding groove, and a motor is fixedly arranged above the inner side wall of the left end surface of the shell;

although the above patent can obtain the difference of wall perpendicularity measurement more intuitively according to the thickness of the wall and the distance from the wall, the wire barrel of the patent may shake during paying off, so that the plumb bob may have a certain influence on the accuracy of the perpendicularity calibration, and the utility model is proposed in view of the above.

Disclosure of Invention

The technical problem to be solved by the utility model is to overcome the defects of the prior art, and provide a civil wall perpendicularity calibrating device which can overcome the problems or at least partially solve the problems.

In order to solve the technical problems, the utility model adopts the basic conception of the technical scheme that: civil engineering wall body straightness calibrating device that hangs down, including base and horizontal adjustment mechanism, horizontal adjustment mechanism installs on the base, still includes: the multi-section electric hydraulic push rods are symmetrically arranged on two sides of the base; the top plate is arranged at the telescopic ends of the two multi-section electric hydraulic push rods; the first connecting ropes are symmetrically arranged on one side of the base, and two ends of each first connecting rope are respectively connected with the base and the top plate; the counterweight plate is connected to the two first connecting ropes in a sliding manner; the distance meter is fixedly connected to the lower end of the counterweight plate; and the driving mechanism is used for controlling the weight plate to move up and down on the first connecting rope and is arranged on the top plate.

Further, actuating mechanism includes driving motor, winding rope wheel, driving motor fixed connection is on the roof, winding rope wheel fixed connection is at driving motor's output, the winding rope wheel is located between two first connecting ropes, the winding rope wheel is last to be winded and is connected with the stay cord, the stay cord is kept away from the one end of winding rope wheel and the intermediate position fixed connection of counter weight board.

In order to reduce the occupation space of the device, thereby be convenient for the staff to carry the device more convenient, and still further, two multisection electric hydraulic push rods are crisscross to be set up on the base, rotate between multisection electric hydraulic push rod's the lower extreme and the base and be connected, the roof is close to multisection electric hydraulic push rod's position fixedly connected with fixed sleeve, multisection electric hydraulic push rod's flexible end is pegged graft in fixed sleeve, fixedly connected with accomodates the frame on the base, accomodate the frame setting in the outside of two multisection electric hydraulic push rods.

In order to avoid the top plate from inclining under the tensile force of the first connecting rope, further, two second connecting ropes are symmetrically arranged on one side, far away from the first connecting rope, of the base, and two ends of each second connecting rope are respectively connected with the base and the top plate.

In order to enable the top plate to be in a horizontal state all the time, further, the positions, close to the first connecting rope and the second connecting rope, on the base are respectively fixedly connected with the first hinging seat and the second hinging seat, the first hinging seat and the second hinging seat are respectively connected with the first rope wheel and the second rope wheel through torsion springs in a rotating mode, the lower ends of the first connecting rope and the second connecting rope are respectively connected onto the first rope wheel and the second rope wheel in a winding mode, and the positions, close to the second connecting rope, on the top plate are fixedly connected with balancing weights.

In order to level the base more accurately, further, horizontal adjustment mechanism includes pneumatic cylinder and hemisphere, pneumatic cylinder fixed connection is in four corners of base, the position that the base bottom is close to the pneumatic cylinder is provided with the recess, the hemisphere setting in the recess, and with the telescopic link fixed connection of pneumatic cylinder, it installs first bar type spirit level, second bar type spirit level to accomodate the frame on the embedded first bar type spirit level of installing respectively, first bar type spirit level is perpendicular setting with the second bar type spirit level.

After the technical scheme is adopted, compared with the prior art, the utility model has the following beneficial effects: according to the utility model, through the cooperation of the base, the multi-section electric hydraulic push rod, the top plate, the two first connecting ropes, the counterweight plate, the distance measuring instrument, the driving mechanism and the like, compared with the mode of detecting the perpendicularity by adopting a single connecting rope to cooperate with the plumb in the prior art, the device can enable the distance measuring instrument to stably move downwards under the cooperation of the first connecting rope and the counterweight plate, so that the fluctuation amount of the distance measuring instrument during movement is reduced, and the accuracy of detecting and calibrating the perpendicularity of a wall body is effectively improved.

The following describes the embodiments of the present utility model in further detail with reference to the accompanying drawings.

Drawings

In the drawings:

fig. 1 is a schematic structural diagram of a device for calibrating verticality of a civil wall according to the present utility model;

fig. 2 is a schematic structural view of a detachable storage frame in the calibrating device for verticality of a civil engineering wall;

fig. 3 is a schematic structural diagram of a counterweight, a hydraulic cylinder and a hemisphere in the calibrating device for verticality of a civil engineering wall.

In the figure: 1. a base; 101. a groove; 102. a hydraulic cylinder; 103. a hemisphere; 104. a first bar level; 105. a second bar level; 2. a multi-section electric hydraulic push rod; 3. a top plate; 301. a fixed sleeve; 4. a first sheave; 401. a first connecting rope; 402. a weight plate; 403. a range finder; 404. a driving motor; 405. a rope winding wheel; 406. a pull rope; 5. a second sheave; 501. a second connecting rope; 502. and (5) balancing weights.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions in the embodiments will be clearly and completely described with reference to the accompanying drawings in the embodiments of the present utility model, and the following embodiments are used to illustrate the present utility model, but are not intended to limit the scope of the present utility model.

Example 1:

referring to fig. 1-3, the civil engineering wall perpendicularity calibrating device comprises a base 1 and a horizontal adjusting mechanism, wherein the horizontal adjusting mechanism is installed on the base 1, and the device further comprises: the multi-section electric hydraulic push rods 2 are symmetrically arranged on two sides of the base 1; the top plate 3 is arranged at the telescopic ends of the two multi-section electric hydraulic push rods 2; the first connecting rope 401 is symmetrically arranged on one side of the base 1, and two ends of the first connecting rope 401 are respectively connected with the base 1 and the top plate 3; a weight plate 402 slidably coupled to the two first coupling ropes 401; the range finder 403 is fixedly connected to the lower end of the weight plate 402; a driving mechanism for controlling the weight plate 402 to move up and down on the first connecting rope 401, mounted on the top plate 3;

the driving mechanism comprises a driving motor 404 and a rope winding wheel 405, wherein the driving motor 404 is fixedly connected to the top plate 3, the rope winding wheel 405 is fixedly connected to the output end of the driving motor 404, the rope winding wheel 405 is positioned between two first connecting ropes 401, a pull rope 406 is wound on the rope winding wheel 405, and one end of the pull rope 406, far away from the rope winding wheel 405, is fixedly connected with the middle position of the counterweight plate 402.

In the civil engineering process, when the wall body needs to be subjected to verticality calibration, a worker firstly moves the device to the side of the wall body needing to be calibrated, then horizontally adjusts the base 1 through the horizontal adjusting mechanism to ensure the accuracy of detecting the verticality of the wall body, after the base 1 is horizontally adjusted, the top plate 3 is driven to move upwards through the multi-section electric hydraulic push rod 2 until the top plate 3 is higher than the wall body and two first connecting ropes 401 are in a tight state, then the rope 406 is controlled to be released through the driving motor 404, meanwhile, the distance meter 403 is started to measure the distance between the weight plates 402 and the wall body, the weight plates 402 continuously move downwards under the action of self gravity due to the fact that the rope 405 is continuously released, then the distance meter 403 can smoothly move downwards under the action of the matching of the first connecting ropes 401 and the weight plates 402, so that the distances between different positions of the wall body and the weight plates 402 can be measured, then the distance between the weight plates can be measured according to the distance meter 403 can be compared with the measured data of each position, whether the accuracy of the wall body meets the requirements or not can be determined, and the accuracy of the wall body can be repeatedly calibrated by adopting the multi-section electric push rod 403, and the method can be matched with the wall body 3 according to the requirements of the detection mode that the vertical adjustment is finished, and the vertical adjustment is completed by the base 2, and the vertical adjustment is completed by the matching mode is compared with the wall body is achieved by the wall body with the two pieces of the measuring ropes, and the requirements, and the accuracy is matched with the quality is matched with the requirements 1 through the quality requirements 2 and the quality measured and the quality accuracy and the quality measurement technology, the device can enable the range finder 403 to stably move downwards under the cooperation of the first connecting rope 401 and the weight plate 402, reduces the fluctuation amount of the range finder 403 during movement, and accordingly effectively improves the accuracy of wall perpendicularity detection and calibration.

Example 2:

referring to fig. 1 to 3, the calibration device for verticality of a civil wall is substantially the same as that of embodiment 1, and further: two multisection formula electric hydraulic push rods 2 are crisscross to be set up on base 1, rotate between multisection formula electric hydraulic push rods 2's lower extreme and the base 1 and be connected, roof 3 is close to multisection formula electric hydraulic push rods 2's position fixedly connected with fixed sleeve 301, multisection formula electric hydraulic push rods 2's flexible end is pegged graft in fixed sleeve 301, fixedly connected with accomodate the frame on base 1, accomodate the frame setting in two multisection formula electric hydraulic push rods 2's the outside, after the measurement calibration to wall body straightness is accomplished, alright control multisection formula electric hydraulic push rods 2 drive roof 3 and descend this moment, after multisection formula electric hydraulic push rods 2 is retracted to the lower extreme, at this moment the staff alright upwards lift roof 3, make multisection formula electric hydraulic push rods 2 and fixed sleeve 301 separate, then rotate multisection formula electric hydraulic push rods 2, alright accomodate into accomodate in the frame, finally, cover roof 3 on accomodate the frame, can accomplish the accomodate work to this device through making multisection formula electric hydraulic push rods 2's lower extreme and base 1 rotate and connect, the upper end through fixed sleeve 301 and roof 3 detachable connection, simultaneously, can drive the device to take up the device with the distance meter under accomodating the cooperation, the device is convenient and the device is carried out, the device is convenient for carrying, the device is further has the practicality to take up, the device is convenient for the device to take up.

Two second connecting ropes 501 are symmetrically arranged on one side, far away from the first connecting rope 401, of the base 1, two ends of each second connecting rope 501 are respectively connected with the base 1 and the top plate 3, and the second connecting ropes 501 are arranged at positions far away from the first connecting ropes 401, so that the top plate 3 can be limited after the top plate 3 rises to the maximum height, the top plate 3 is prevented from inclining under the tensile force of the first connecting ropes 401, and the accuracy of measuring the wall perpendicularity of the range finder 403 is effectively guaranteed.

The position on the base 1, which is close to the first connecting rope 401 and the second connecting rope 501, is fixedly connected with the first hinging seat and the second hinging seat respectively, the first hinging seat and the second hinging seat are respectively connected with the first rope pulley 4 and the second rope pulley 5 through torsion springs in a rotating way, the lower ends of the first connecting rope 401 and the second connecting rope 501 are respectively wound on the first rope pulley 4 and the second rope pulley 5, the counterweight 502 is fixedly connected with the position on the top plate 3, which is close to the second connecting rope 501, the first rope pulley 4 and the second rope pulley 5 are respectively connected with the first hinging seat and the second hinging seat through torsion springs in a rotating way, when the device is completely detected and calibrated, the first connecting rope 401 and the second connecting rope 501 are respectively stored on the first rope pulley 4 and the second rope pulley 5, which are connected, so that the first connecting rope 401 and the second connecting rope 501 are conveniently stored and tidied, the next use is influenced, the counterweight 502 is provided for workers to work conveniently, and the distance meter is arranged at the position, which is close to the second connecting rope 401 and the second connecting rope 501, the position, which is close to the top plate 403, the second connecting rope 501, the distance meter 403 and the whole distance meter 403 are arranged on one side of the top plate, and the whole distance meter is in a measuring device, and the whole weight meter is in the same in the measuring precision.

Example 3:

referring to fig. 1 to 3, the calibration device for verticality of civil engineering wall is substantially the same as that of embodiment 2, and further: the horizontal adjustment mechanism comprises a hydraulic cylinder 102 and hemispheres 103, the hydraulic cylinder 102 is fixedly connected at four corners of a base 1, a groove 101 is formed in the bottom of the base 1 and close to the hydraulic cylinder 102, the hemispheroids 103 are arranged in the groove 101 and fixedly connected with the telescopic ends of the hydraulic cylinder 102, a first strip type level gauge 104 and a second strip type level gauge 105 are respectively embedded and installed on a storage frame, the first strip type level gauge 104 and the second strip type level gauge 105 are vertically arranged, when the device is moved to a wall to detect the perpendicularity of the wall, the four hydraulic cylinders 102 can be controlled according to the first strip type level gauge 104 and the second strip type level gauge 105 at the moment, so that the hemispheroids 103 are controlled by the hydraulic cylinder 102 to move until the horizontal bubbles in the first strip type level gauge 104 and the second strip type level gauge 105 are all in the middle positions, and the whole leveling work of the device can be completed, and the accuracy of wall perpendicularity measurement and calibration can be effectively guaranteed.

The above description is only of the preferred embodiments of the present utility model, and is not intended to limit the present utility model in any way, although the present utility model has been described in the preferred embodiments, and is not limited thereto.

Claims (6)

1. Civil engineering wall body straightness calibrating device that hangs down, including base (1) and horizontal adjustment mechanism, horizontal adjustment mechanism installs on base (1), its characterized in that still includes:

the multi-section electric hydraulic push rods (2) are symmetrically arranged on two sides of the base (1);

the top plate (3) is arranged at the telescopic ends of the two multi-section electric hydraulic push rods (2);

the first connecting ropes (401) are symmetrically arranged on one side of the base (1), and two ends of each first connecting rope (401) are respectively connected with the base (1) and the top plate (3);

a weight plate (402) slidably connected to the two first connecting ropes (401);

the range finder (403) is fixedly connected to the lower end of the weight plate (402);

a driving mechanism for controlling the weight plate (402) to move up and down on the first connecting rope (401) is mounted on the top plate (3).

2. The civil engineering wall perpendicularity calibrating device according to claim 1, wherein the driving mechanism comprises a driving motor (404) and a rope winding wheel (405), the driving motor (404) is fixedly connected to the top plate (3), the rope winding wheel (405) is fixedly connected to the output end of the driving motor (404), the rope winding wheel (405) is located between two first connecting ropes (401), a pull rope (406) is wound on the rope winding wheel (405), and one end, far away from the rope winding wheel (405), of the pull rope (406) is fixedly connected with the middle position of the counterweight plate (402).

3. The civil engineering wall perpendicularity calibration device according to claim 2, wherein two multi-section electric hydraulic pushing rods (2) are arranged on a base (1) in a staggered mode, the lower ends of the multi-section electric hydraulic pushing rods (2) are rotationally connected with the base (1), a fixed sleeve (301) is fixedly connected with the position, close to the multi-section electric hydraulic pushing rods (2), of a top plate (3), the telescopic ends of the multi-section electric hydraulic pushing rods (2) are inserted into the fixed sleeve (301), a storage frame is fixedly connected to the base (1), and the storage frame is arranged on the outer sides of the two multi-section electric hydraulic pushing rods (2).

4. A civil engineering wall perpendicularity calibrating device according to claim 3, wherein two second connecting ropes (501) are symmetrically arranged on one side, far away from the first connecting rope (401), of the base (1), and two ends of each second connecting rope (501) are respectively connected with the base (1) and the top plate (3).

5. The civil engineering wall perpendicularity calibrating device according to claim 4, wherein the base (1) is fixedly connected with a first hinging seat and a second hinging seat at positions close to a first connecting rope (401) and a second connecting rope (501), the first hinging seat and the second hinging seat are respectively connected with a first rope wheel (4) and a second rope wheel (5) through torsion springs in a rotating mode, the lower ends of the first connecting rope (401) and the second connecting rope (501) are respectively connected to the first rope wheel (4) and the second rope wheel (5) in a winding mode, and a balancing weight (502) is fixedly connected to the top plate (3) at positions close to the second connecting rope (501).

6. The civil engineering wall perpendicularity calibration device according to claim 3, wherein the horizontal adjustment mechanism comprises a hydraulic cylinder (102) and hemispheres (103), the hydraulic cylinder (102) is fixedly connected to four corners of a base (1), a groove (101) is formed in the bottom of the base (1) and close to the position of the hydraulic cylinder (102), the hemispheres (103) are arranged in the groove (101) and fixedly connected with the telescopic ends of the hydraulic cylinder (102), a first strip type level meter (104) and a second strip type level meter (105) are respectively embedded in the storage frame, and the first strip type level meter (104) and the second strip type level meter (105) are vertically arranged.