CN219810405U - Measuring mechanism for high-rise climbing frame and high-rise climbing frame using same - Google Patents

Abstract

The utility model discloses a measuring mechanism for a high-rise climbing frame and the high-rise climbing frame using the measuring mechanism, and belongs to the technical field of climbing frame measurement. The utility model relates to a measuring mechanism for a high-rise climbing frame, which is provided with a laser emitting component capable of emitting laser and a scale rod capable of receiving the laser. And even when measuring on domatic or rugged platform, can also realize accurate measurement through the length of adjustment expansion bracket to applicable various measurement scenes, simple structure, practicality, low in manufacturing cost, stability is high, and measurement effect is good.

Description

Measuring mechanism for high-rise climbing frame and high-rise climbing frame using same

Technical Field

The utility model relates to a measuring mechanism for a high-rise climbing frame and the high-rise climbing frame using the same, and belongs to the technical field of climbing frame measurement.

Background

The building outer wall climbing frame system is an important research field in the field of hoisting machinery in recent years, the overall weight of a climbing frame platform can reach tens of tons or even hundreds of tons, and local deformation or overall inclination in the lifting process can bring about great potential safety hazards. The climbing frame platform is attached to the outer wall of the high-rise building and can be lifted or lowered through the electric hoist. The climbing frame device on the market does not have a device for detecting the balance degree of the climbing frame body, so the balance of the climbing frame body is not well controlled. And building site environment is abominable, hardly finds suitable horizontal plane as the reference standard of setting up and climbing frame platform.

Further, since the climbing frame platform is rectangular, and the long side of the climbing frame platform is about several meters and is arranged around a building, the measuring equipment directly applying the prior art has various disadvantages, such as: the existing instrument and device for measuring the balance of the climbing frame are difficult to measure the height state and the relative height of two hoisting points of a hoist of the climbing frame far away, and are inconvenient for leveling the climbing frame of a high building; some measuring devices, such as level gauges, are only suitable for local small-scale measurements and need to be positioned on a perfectly flat plane for proper measurement; some measuring devices are huge, time-consuming, labor-consuming and expensive, thus making the leveling of the entire climbing frame platform very difficult.

The information disclosed in this background is only for the understanding of the background of the inventive concept and therefore it may comprise information that does not form the prior art.

Disclosure of Invention

Aiming at the problems or one of the problems, the utility model aims to provide a laser emitting component capable of emitting laser and a scale rod capable of receiving the laser, wherein the laser emitting component and the scale rod are respectively placed at corresponding positions of a climbing frame of a high building when in use, the laser emitted by a laser emitter is scanned to the scale rod, and the scale value on the scale rod is read to realize the measurement of the climbing frame of the high building, so that the leveling work of the climbing frame is facilitated; and even when measuring on domatic or rugged platform, can also realize accurate measurement through the length of adjustment expansion bracket to applicable various measurement scenes, simple structure, practicality, low in manufacturing cost, high measuring mechanism for high building climbs the frame of stability.

Aiming at the problems or one of the problems, the second aim of the utility model is to provide a measuring mechanism which uses the laser emitted by a laser emitter to sweep the scale bar and reads the scale value on the scale bar to realize the measurement of the climbing frame of the high building, thereby being convenient for the leveling work of the climbing frame; and even when measuring on domatic or rugged platform, can also realize accurate measurement through the length of adjustment expansion bracket, simple structure, practicality, low in manufacturing cost, stability is high, and measurement effect is good, can avoid loaded down with trivial details leveling work's high building to climb the frame.

In order to achieve one of the above objects, a first technical solution of the present utility model is:

a measuring mechanism for a climbing frame of a high building comprises a laser emitting component capable of emitting laser and a scale rod capable of receiving the laser;

the laser emission component at least comprises a telescopic frame and a laser emitter;

the laser emitted by the laser emitter can sweep the scale bar, and the measurement of the climbing frame of the high building is realized by reading the scale value on the scale bar.

According to the utility model, through continuous exploration and test, the laser emission component capable of emitting laser and the scale rod capable of receiving the laser are arranged, when the device is used, the laser emission component and the scale rod are respectively placed at corresponding positions (lifting points) of the climbing frame of a high building, the laser emitted by the laser emitter is scanned to the scale rod, and the scale value on the scale rod is read, so that the height difference between lifting points of any climbing frame hoist on a climbing frame platform is measured remotely, and the leveling work of the climbing frame is facilitated. And even when measuring on domatic or rugged platform, can also realize accurate measurement through the length of adjustment expansion bracket to applicable various measurement scenes, simple structure, practicality, low in manufacturing cost, stability is high, and measurement effect is good.

As a preferred technical measure:

the scale rod is assembled on the scale assembly;

the scale assembly comprises a hinged telescopic tripod II, an adjustable tripod II and an assembly block II assembled on the tripod II, and an angle measuring instrument II is arranged on the assembly block II.

As a preferred technical measure:

the laser emission component further comprises an adjustable cradle head I and an assembly block I assembled on the cradle head I, wherein an angle measuring instrument I, a tape and a laser emitter are arranged on the assembly block I;

the telescopic frame is a telescopic tripod I.

As a preferred technical measure:

the telescopic tripod I and the telescopic tripod II respectively comprise a side link and three telescopic supporting feet;

the support foot comprises at least three knuckle arms, three clamping rings and a rubber foot pad.

As a preferred technical measure:

the first and second holders at least comprise a handle, three switches, a main rod, an auxiliary rod and a holder surface;

the three switches are divided into a first switch, a second switch and a third switch;

the first switch, the second switch and the handle can adjust the front-back left-right rotary motion of the tripod head so as to adjust the horizontal of the tripod head; the three-purpose switch is used for locking the main rod and the auxiliary rod and can be used for adjusting the height of the cradle head and indirectly adjusting the height of the first assembly block or/and the second assembly block.

As a preferred technical measure:

the first assembly block and/or the second assembly block are/is rectangular blocks with uniform, flat and smooth surfaces, and are fixed and clung to the cloud table top through bolts, and the upper surfaces of the first assembly block and/or the second assembly block are parallel to the cloud table top.

As a preferred technical measure:

the first angle measuring instrument is fixedly arranged on the first assembly block through a plurality of fasteners, can measure the inclination angle and the angle position of the first assembly block at the same time, and can provide a reference for adjusting the level of the first assembly block;

or/and, the angle measuring instrument II is fixedly arranged on the assembly block II through a plurality of fasteners, can measure the inclination angle and the angle position of the assembly block II at the same time, and can provide a reference for adjusting the level of the assembly block II.

As a preferred technical measure:

the laser transmitter is fixedly arranged on the first assembly block through a plurality of bolts, and the emitted light rays are parallel to the upper surface of the first assembly block;

or/and the tape measure is used for measuring the horizontal linear distance between certain two points to be measured; the bottom of the measuring tape is provided with a measuring tape positioning seat for adjusting the height of the measuring tape outlet and the laser emitted by the laser emitter to be at the same level.

As a preferred technical measure:

one end of the scale rod is fixed on the second assembly block through threads, the scale rod is perpendicular to the second assembly block, the scale on the scale rod is accurate to 1mm, the middle of the scale rod is a zero scale mark, the scale mark is 0, the scale above the zero scale mark is gradually increased, and the scale below the zero scale mark is gradually decreased.

In order to achieve one of the above objects, a second technical solution of the present utility model is:

the high-rise climbing frame is applied to the measuring mechanism, the climbing frame main body, the climbing frame hoist and the bottom frame body for the high-rise climbing frame;

two ends of the climbing frame main body are respectively provided with a climbing frame hoist, and the lower end of the climbing frame main body is provided with a bottom frame body;

the bottom frame body comprises a plurality of longitudinal horizontal rods, vertical rods and transverse horizontal rods;

the longitudinal horizontal rod is connected with the vertical rod through a steel pipe fastener, and the longitudinal horizontal rod is connected with the transverse horizontal rod through a steel pipe fastener;

the bottom of the climbing frame main body is leveled through the measuring mechanism for the high-rise climbing frame and the bottom frame body, and the climbing frame main body is lifted by utilizing the climbing frame hoist.

According to the utility model, through continuous exploration and test, the measuring mechanism is utilized, laser emitted by the laser emitter is scanned to the scale bar, and the scale value on the scale bar is read, so that the measurement of the climbing frame of a high building is realized, and the leveling work of the climbing frame is facilitated; and even when measuring on domatic or rugged platform, can also realize accurate measurement through the length of adjustment expansion bracket, simple structure, practicality, low in manufacturing cost, stability is high, and measurement effect is good, can avoid loaded down with trivial details leveling work.

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

according to the utility model, through continuous exploration and test, the laser emission component capable of emitting laser and the scale rod capable of receiving the laser are arranged, when the device is used, the laser emission component and the scale rod are respectively placed at corresponding positions of the climbing frame of a high building, laser emitted by the laser emitter is scanned to the scale rod, and the scale value on the scale rod is read, so that the height difference between any climbing frame hoist lifting points on the climbing frame platform is measured remotely, and the climbing frame leveling work is facilitated. And even when measuring on domatic or rugged platform, can also realize accurate measurement through the length of adjustment expansion bracket to applicable various measurement scenes, simple structure, practicality, low in manufacturing cost, stability is high, and measurement effect is good.

According to the utility model, through continuous exploration and test, the measuring mechanism is utilized, laser emitted by the laser emitter is scanned to the scale bar, and the scale value on the scale bar is read, so that the measurement of the climbing frame of a high building is realized, and the leveling work of the climbing frame is facilitated; and even when measuring on domatic or rugged platform, can also realize accurate measurement through the length of adjustment expansion bracket, simple structure, practicality, low in manufacturing cost, stability is high, and measurement effect is good, can avoid loaded down with trivial details leveling work.

Drawings

FIG. 1 is a schematic view of a laser emitting assembly of the present utility model for use in a measurement mechanism for a high-rise climbing frame;

FIG. 2 is a schematic view of a scale assembly of the measuring mechanism for a high-rise climbing frame of the present utility model;

FIG. 3 is a schematic view of a head of a measuring mechanism for a high-rise climbing frame;

FIG. 4 is a schematic illustration of a measurement principle of the measurement mechanism for the high-rise climbing frame of the present utility model;

FIG. 5 is a schematic illustration of an integrated creeper platform leveling apparatus of this utility model;

fig. 6 is a schematic view of a structure of the climbing frame base and the bottom frame body of the present utility model.

Reference numerals illustrate:

1. a laser emitting assembly; 2. a scale assembly; 3. tilting the platform; 4. measuring a point A; 5. measuring a point B; 6. zero point scale marks; 7. target height; 11. a telescopic tripod; 111. arm-saving; 112. a clamping ring; 113. a rubber foot pad; 12. a side link; 13. a cradle head; 131. a cloud deck; 132. a handle; 133. an X switch; 134. a switch I; 135. a switch II; 136. a switch III; 137. a secondary shaft; 138. a main shaft; 14. i-shaped assembly blocks; 15. a laser emitter; 16. an angle measuring instrument; 17. a tape measure; 171. a tape measure positioning seat; 21. a type II fitting block; 22. a scale bar; 31. moving the lifting point 1; 32. moving the lifting point No. 2; 33. moving the lifting point 3; 34. moving the lifting point No. 4; 35. climbing frame hoist lifting point 5; 36. moving the lifting point number 6; 37. moving the lifting point 7; 38. moving the lifting point 8; 39. integral building climbing frame scaffold board; 40. climbing frame hoist; 41. a climbing frame base; 42. diagonal measurement point number 1; 43. diagonal measurement point number 2; 44. diagonal measurement point number 3; 45. diagonal measurement point number 4; 46. a bottom frame body upright post; 47. a bottom frame longitudinal horizontal bar; 48. a bottom frame transverse horizontal rod.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

On the contrary, the utility model is intended to cover any alternatives, modifications, equivalents, and variations as may be included within the spirit and scope of the utility model as defined by the appended claims. Further, in the following detailed description of the present utility model, certain specific details are set forth in order to provide a better understanding of the present utility model. The present utility model will be fully understood by those skilled in the art without the details described herein.

It is to be noted that when two elements are "fixedly connected," the two elements may be directly connected or intervening elements may also be present. In contrast, when an element is referred to as being "directly on" another element, there are no intervening elements present. The terms "horizontal," "transverse," "upper," "lower," and the like are used herein for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. The term "or/and" as used herein includes any and all combinations of one or more of the associated listed items.

As shown in fig. 1-6, one embodiment of a measuring mechanism for a high-rise climbing frame of the present utility model:

a measuring mechanism for a high-rise climbing frame can measure specific height differences between different measuring points 5 on a climbing frame platform and comprises a laser emitting component capable of assisting in emitting horizontal laser and a scale component capable of receiving the laser and reading scales.

The laser emission component comprises a hinged telescopic tripod 11, an adjustable tripod head 13 and an assembly block on the tripod head 13, wherein an angle measuring instrument, a laser emitter 15 and a tape measure 17 are arranged on the assembly block.

The scale assembly comprises a hinged telescopic tripod 11, an adjustable tripod head 13 and an assembly block on the tripod head 13, wherein an angle measuring instrument and a scale rod 22 are arranged on the assembly block.

The telescopic tripod 11 comprises a side link 12 and three telescopic supporting feet. Each telescopic support foot is composed of three knuckle arms 111, three clamping rings 112 and one rubber foot 113.

The cradle head 13 is composed of a handle 132, three switches, a main rod, an auxiliary rod and a cradle head 13 surface.

The rotary motion of the cradle head 13 in the front-back and left-right directions can be adjusted through two switches and a handle 132, so that the level of the cradle head 13 surface can be adjusted. One of the switches is used for locking the main rod and the auxiliary rod, and can be used for adjusting the height of the cradle head 13, so that the height of the assembly block can be indirectly adjusted.

The assembly blocks are rectangular blocks with uniform, flat and smooth surfaces and are fixed and clung to the surface of the cradle head 13 through bolts. The upper surface of the device is parallel to the surface of the cradle head 13.

The angle measuring instrument is fixedly arranged on the assembly block through three bolts, and can simultaneously measure the inclination angle and the angle position of the assembly block, so that accurate reference is provided for adjusting the level of the assembly block.

The laser transmitter 15 is fixedly arranged on the assembly block through four bolts, and the light rays emitted by the laser transmitter are parallel to the upper surface of the assembly block.

The measuring tape 17 is used for measuring the horizontal linear distance between two to-be-measured points. The bottom of the tape measure 17 is provided with a tape measure 17 positioning seat for adjusting the height of the extension opening of the tape measure 17 to be at the same level with the laser emitted by the laser emitter 15.

One end of the scale rod 22 is fixed on the assembly block through threads, the scale rod 22 is perpendicular to the assembly block, the scale on the scale rod 22 is accurate to 1mm, the middle of the scale rod is provided with a zero point scale mark 6, the scale mark is 0, the scale above the zero point scale mark 6 is increased, and the scale below the zero point scale mark 6 is decreased.

The measuring mechanism for the climbing frame of the high-rise building skillfully uses the principle of laser linear irradiation, can directly or indirectly remotely measure the height difference and the height condition between any movable lifting points on the climbing frame platform, further can provide data for realizing one-time accurate leveling before the climbing frame is lifted, and can avoid complicated leveling work. And even when measuring on a slope or an uneven platform, the accurate measurement can be realized only by enabling the assembly block to be positioned at the target height 7 by randomly adjusting the length of the supporting leg on the telescopic tripod 11. The measuring device is low in cost, high in practicality and high in stability. The stability of putting of flexible tripod 11 can be improved through adjusting the heavy object that laser emission subassembly and scale subassembly bottom hung, the difficult condition of turning on one's side appears in the assurance in measurement work.

The utility model is applied to a specific embodiment of a measuring mechanism for a climbing frame of a high building:

as shown in fig. 1, 2 and 4, the present embodiment proposes a measuring mechanism for a high-rise climbing frame that mainly measures a height difference between two moving lifting points, comprising: a laser emitting assembly 1 capable of assisting in emitting horizontal laser light and a scale assembly 2 which receives the laser light and can read a scale.

Referring to fig. 3, the laser emitting assembly includes a hinged telescopic tripod 11, an adjustable tripod head 13, and an I-shaped mounting block 14 on the tripod head, on which a laser emitter 15, an angle measuring device 16, and a tape measure 17 are mounted.

The scale assembly comprises a hinged telescopic tripod 11, an adjustable tripod head 13 and a II-type assembly block 21 on the tripod head, wherein an angle measuring instrument 16 and a scale rod 22 are arranged on the assembly block.

The telescopic tripod 11 comprises a side link 12 and three telescopic supporting feet. Each telescopic support foot is composed of four knuckle arms 111, three clamping rings 112 and one rubber foot 113. The side link 12 is used to secure and allow simultaneous extension and retraction of three support feet. When link bar hinge base 122 is lowered to the lowest end of main shaft 138, the three support foot overhang angles are maximized. By loosening or clamping the three clamping rings 112, the extension or shortening of the three knuckle arms 111 of the support foot can be adjusted. The lengths of the three supporting feet are respectively adjusted, so that the tripod is stably and vertically arranged on the plane to be measured, and the heights of the I-type assembly block 14 on the laser emission assembly and the II-type assembly block 21 on the scale assembly from the plane to be measured are indirectly adjusted.

The I-shaped assembly block 14 is a rectangular block with a uniform and smooth surface, and a threaded hole is formed in the center of the lower plane of the I-shaped assembly block.

The II-type assembling block 21 is characterized in that a round boss is added to the center of the upper surface of the I-type assembling block 14, and a threaded hole with a certain depth is formed in the center of the boss.

The cradle head 13 includes: yun Taimian 131, handle 132, X switch 133, switch I134, switch II135, switch III136, secondary shaft 137, primary shaft 138, etc.

One end of the X switch 133 is provided with threads, the I-type assembling block 14 and the II-type assembling block 21 can be fixed on the cloud deck 131 through the X switch 133, and the upper large surface and the lower large surface of the I-type assembling block 14 and the II-type assembling block 21 are parallel to the cloud deck 131.

Through elasticity switch I134 and switch II135 respectively, can adjust the front and back of cloud mesa and turn over about through operating handle 132 to adjust the level of cloud mesa, and then indirectly adjusted the level of assembly piece upper and lower surface.

A switch III136 for lockingly connecting the secondary shaft 137 and the primary shaft 138. The auxiliary shaft 137 and the main shaft 138 form a telescopic rod structure, and the telescopic length of the auxiliary shaft 137 can be adjusted by loosening and locking the switch III136, so that the height of the assembly block from the platform to be measured can be adjusted.

The angle measuring instrument 16 is mounted on the type I mounting block 14 and the type II mounting block 21 by three bolts, and the angle measuring instrument 16 can simultaneously measure the inclination angle and direction of the mounting blocks, thereby providing a reference for adjusting the level of the mounting blocks.

The laser transmitter 15 is fixedly arranged on the I-shaped assembling block 14 through four bolts, and the emitted light is parallel to the upper surface of the I-shaped assembling block 14.

The measuring tape 17 is used for measuring the horizontal linear distance between two to-be-measured points. The height of the steel rule extension opening is adjusted to be at the same level with the laser emitted by the laser emitter 15 by installing the rule positioning seat 171 at the bottom of the rule.

One end of the scale rod 22 is fixed on the II-type assembly block 21 through threaded connection, the scale rod 22 is perpendicular to the upper surface of the II-type assembly block 21, scales on the scale rod 22 are accurate to 1mm, and the scale rod is gradually increased from the middle zero point to the two ends.

The measuring process of the measuring mechanism for the climbing frame of the high building comprises the following specific measuring processes:

step one, as shown in fig. 4, first, the laser emitting assembly 1 and the scale assembly 2 are placed at the same measuring point a, and the hinge base 122 of their side link 12 is lowered to the lowest end of the main shaft 138, so that the overhanging angle of the three support feet is maximized. The extension or shortening of the three articulated arms 111 of the support foot can then be adjusted by loosening or clamping the three clamping rings 112, so that the lengths of their three support feet are adjusted, so that the laser emitting assembly 1 and the scale assembly 2 are stably and relatively vertically arranged on the plane to be measured. According to the indication of angle measuring instruments on the I-type assembling block and the II-type assembling block, the switch I134 and the switch II135 are respectively loosened and tightened, and the front, the back, the left and the right of the cloud table top can be adjusted through the operating handle 132, so that the cloud table top of the adjusting laser emitting assembly 1 and the scale assembly 2 are in a horizontal state, and the upper surface and the lower surface of the I-type assembling block and the lower surface of the II-type assembling block are in a horizontal state indirectly.

Step two, calibrating zero by a scale rod: for the laser emitting assembly 1, the handle 132 of the laser emitting assembly is horizontally rotated to horizontally rotate the I-shaped assembly block, so that laser emitted by the laser emitter horizontally scans the scale bar, and then the telescopic length of the auxiliary shaft 137 can be adjusted by loosening and locking the switch III136 of the laser emitting assembly, so that the zero point scale mark of the scale bar can be adjusted. The target height 7 of the II-type assembly block of the scale assembly 2 from the measuring point A is measured and recorded as h ₀ 。

And thirdly, the scale assembly 2 is stably and vertically arranged at the point B to be measured according to the operation of the first step, and the upper surface and the lower surface of the cloud deck of the scale assembly 2 and the upper surface and the lower surface of the II-type assembly block 21 are both in a horizontal state. For the scale assembly 2, by releasing and locking the switch III136 thereof, the telescopic length of the auxiliary shaft 137 can be adjusted, so that the target height of the II-type assembly block at the distance measuring point A is h ₀ 。

Step four, the handle 132 of the laser emission component 1 is horizontally rotated to horizontally rotate the I-shaped assembly block, so that laser emitted by the laser emitter horizontally scans the scale bar, and the scale value a emitted by the laser at the moment and the height or the low height relative to the zero scale value are recorded. At this time, the absolute value |a-0| of the difference between the scale value of the laser light and the zero scale value is the height difference h between the measurement point A4 and the measurement point B5. By observing whether the scale irradiated by the laser is high or low relative to the zero scale mark at this time, the relative heights of the measurement point A4 and the measurement point B5 can be obtained. If the measured scale is above the zero scale mark, the measurement point B is higher than the measurement point A. Otherwise, the measurement point A is higher than the measurement point B.

And fifthly, stretching the tape of the I-shaped assembly block on the laser emission assembly 1 to the laser irradiation position of the scale bar, and recording that the stretched length of the tape is L, wherein L is the horizontal distance between the measuring point A4 and the measuring point B5. The inclination angle of the two measuring points is

Through the above steps, the measuring mechanism for the high-rise climbing frame measures the height difference between the two moving lifting points a and B and the relative height in the horizontal direction. And simultaneously measuring the horizontal distances of the two movable lifting points A and B, and further calculating the inclination angles of the two measuring points to judge whether the inclination angle of the climbing frame meets the regulation.

The utility model is applied to a specific embodiment for leveling the initial position of the integral climbing frame platform:

taking an integral building climbing frame system with 8 lifting points in fig. 5 as an example, 8 climbing frame hoists are arranged on a building climbing frame platform and 8 lifting points which are uniformly distributed on an integral building climbing frame scaffold board 39, each climbing frame hoists has a load real-time monitoring function, the building climbing frame platform is a rigid platform, and each lifting point is equidistant with the building climbing frame platform. If the 4 lifting points of the diagonal angle of the climbing frame platform are at the same height, the climbing frame platform is in a horizontal state, and if the climbing frame platform is in an inclined state, the height difference in the vertical direction appears between the positions where the lifting points are moved diagonally on the platform. Because the building is shielded, laser can not penetrate through the wall, the height difference between two pairs of movable lifting points on opposite angles on the climbing frame platform can not be directly measured, and a transition measuring point can be additionally found and used as a bridge to indirectly measure the opposite angle measuring point on the climbing frame platform. If the height difference between the diagonal moving lifting points A and B on the climbing frame platform cannot be directly measured, a transition measuring point C can be additionally found, and the following conditions are ensured by selecting the transition measuring point C: in measuring a and C and measuring C and B, respectively, the laser is not blocked by the building.

The 8 lifting points comprise a No. 1 mobile lifting point 31, a No. 2 mobile lifting point 32, a No. 3 mobile lifting point 33, a No. 4 mobile lifting point 34, a No. 5 climbing frame hoist lifting point 35, a No. 6 mobile lifting point 36, a No. 7 mobile lifting point 37 and a No. 8 mobile lifting point 38.

The diagonal measurement points include a diagonal measurement point No. 1 42, a diagonal measurement point No. 2 43, a diagonal measurement point No. 3 44, and a diagonal measurement point No. 4 45.

As shown in fig. 6, a specific embodiment of the present utility model for leveling the initial position of the attached lifting building climbing frame platform is:

leveling the initial position of the attached lifting building climbing frame platform, which comprises the following specific contents:

the attached lifting building climbing frame is arranged on the bottom frame body before lifting. Before installation, the building climbing frame should generally be firstly leveled by the bottom frame body, the common leveling modes of the bottom frame body are divided into two types, the first type is to directly adjust the height of the bottom scaffold steel pipe for leveling, and the second type is to set up a truss on the basis of the bottom scaffold for leveling. The first category has lower accuracy and is difficult to ensure the level of the climbing frame. The second category is too dependent on the flatness of the bottom scaffolding body, so that the installed climbing platform is often not horizontal if the bottom scaffolding is not flat. As shown in fig. 6, the bottom frame is formed by connecting each longitudinal horizontal bar 47, each vertical bar 46 and each transverse horizontal bar 48 by means of steel pipe fasteners. Each longitudinal horizontal rod 47 and each vertical rod 46 are connected by a steel pipe fastener, and each longitudinal horizontal rod 47 and each transverse horizontal rod 48 are connected by a steel pipe fastener. If the heights of the steel pipe fasteners at the two ends of each longitudinal horizontal rod 47 in the vertical direction are different, the connection points at the two ends of the longitudinal horizontal rods 47 are not at the same height, so that the longitudinal horizontal rods 47 are not in a horizontal state, and each transverse horizontal rod 48 on the longitudinal horizontal rods 47 is not horizontal. When the steel pipe fasteners at the two ends of each longitudinal horizontal rod 47 are adjusted to be at the same height, the leveling of the bottom frame body is completed. For each section of attached lifting building climbing frame, due to the anti-eversion characteristic, the climbing frame can be lifted and lowered along the building wall only by installing a climbing frame hoist 40 at two ends of the climbing frame.

Further, a section of climbing frame base 41 is placed on the leveled bottom frame body by using a tower crane, the climbing frame base 41 is a rectangular steel plate with a flat surface, and the length and the width of the climbing frame base 41 can be just placed for a section of building climbing frame. After the measurement is completed, the frame base 41 is removed from the bottom frame with the tower crane.

In the utility model, the fixed connection mode can be screw connection, welding, riveting, inserting connection or connection through a third component, and the fixed connection mode can be selected by a person skilled in the art according to actual conditions.

Finally, it should be noted that: the above embodiments are only for illustrating the technical aspects of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the above embodiments, it should be understood by those of ordinary skill in the art that: modifications and equivalents may be made to the specific embodiments of the utility model without departing from the spirit and scope of the utility model, which is intended to be covered by the claims.

Claims (10)

1. A measuring mechanism for a climbing frame of a high building is characterized in that,

the scale rod comprises a laser emitting component capable of emitting laser and a scale rod capable of receiving the laser;

the laser emission component at least comprises a telescopic frame and a laser emitter;

the laser emitted by the laser emitter can sweep the scale bar, and the measurement of the climbing frame of the high building is realized by reading the scale value on the scale bar.

2. A measuring mechanism for a high-rise climbing frame according to claim 1, wherein,

the scale rod is assembled on the scale assembly;

the scale assembly comprises a hinged telescopic tripod II, an adjustable tripod II and an assembly block II assembled on the tripod II, and an angle measuring instrument II is arranged on the assembly block II.

3. A measuring mechanism for a high-rise climbing frame according to claim 2, wherein,

the laser emission component further comprises an adjustable cradle head I and an assembly block I assembled on the cradle head I, wherein an angle measuring instrument I, a tape and a laser emitter are arranged on the assembly block I;

the telescopic frame is a telescopic tripod I.

4. A measuring mechanism for a high-rise climbing frame according to claim 3, wherein,

the telescopic tripod I and the telescopic tripod II respectively comprise a side link and three telescopic supporting feet;

the support foot comprises at least three knuckle arms, three clamping rings and a rubber foot pad.

5. A measuring mechanism for a high-rise climbing frame according to claim 3, wherein,

the first and second holders at least comprise a handle, three switches, a main rod, an auxiliary rod and a holder surface;

the three switches are divided into a first switch, a second switch and a third switch;

the first switch, the second switch and the handle can adjust the front-back left-right rotary motion of the tripod head so as to adjust the horizontal of the tripod head; the three-purpose switch is used for locking the main rod and the auxiliary rod and can be used for adjusting the height of the cradle head and indirectly adjusting the height of the first assembly block or/and the second assembly block.

6. A measuring mechanism for a high-rise climbing frame according to claim 3, wherein,

the first assembly block and/or the second assembly block are/is rectangular blocks with uniform, flat and smooth surfaces, and are fixed and clung to the cloud table top through bolts, and the upper surfaces of the first assembly block and/or the second assembly block are parallel to the cloud table top.

7. A measuring mechanism for a high-rise climbing frame according to any one of claims 3 to 6, wherein,

the first angle measuring instrument is fixedly arranged on the first assembly block through a plurality of fasteners, can measure the inclination angle and the angle position of the first assembly block at the same time, and can provide a reference for adjusting the level of the first assembly block;

or/and, the angle measuring instrument II is fixedly arranged on the assembly block II through a plurality of fasteners, can measure the inclination angle and the angle position of the assembly block II at the same time, and can provide a reference for adjusting the level of the assembly block II.

8. A measuring mechanism for a high-rise climbing frame according to claim 7, wherein,

the laser transmitter is fixedly arranged on the first assembly block through a plurality of bolts, and the emitted light rays are parallel to the upper surface of the first assembly block;

or/and the tape measure is used for measuring the horizontal linear distance between certain two points to be measured; the bottom of the measuring tape is provided with a measuring tape positioning seat for adjusting the height of the measuring tape outlet and the laser emitted by the laser emitter to be at the same level.

9. A measuring mechanism for a high-rise climbing frame according to claim 8, wherein,

one end of the scale rod is fixed on the second assembly block through threads, the scale rod is perpendicular to the second assembly block, the scale on the scale rod is accurate to 1mm, the middle of the scale rod is a zero scale mark, the scale mark is 0, the scale above the zero scale mark is gradually increased, and the scale below the zero scale mark is gradually decreased.

10. A climbing frame for a high building, which is characterized in that,

use of a measuring mechanism for a high-rise climbing frame, a climbing frame body, a climbing frame hoist and a bottom frame body according to any one of claims 1-9;

two ends of the climbing frame main body are respectively provided with a climbing frame hoist, and the lower end of the climbing frame main body is provided with a bottom frame body;

the bottom frame body comprises a plurality of longitudinal horizontal rods, vertical rods and transverse horizontal rods;

the longitudinal horizontal rod is connected with the vertical rod through a steel pipe fastener, and the longitudinal horizontal rod is connected with the transverse horizontal rod through a steel pipe fastener;

the bottom of the climbing frame main body is leveled through the measuring mechanism for the high-rise climbing frame and the bottom frame body, and the climbing frame main body is lifted by utilizing the climbing frame hoist.