CN113090023B - Large-span steel beam hoisting construction method - Google Patents

Abstract

The invention relates to a large-span steel beam hoisting construction method, which comprises the following steps: positioning the lug plate to the elevation position of the steel beam to be hoisted; the steel beam passes through a plurality of guys for guiding, wherein a guy core is sleeved on a horizontal elevation of each guy corresponding to the elevation position; a plurality of winches for hoisting the steel beam are arranged on the top floor layer at intervals, and the winches on two sides of the middle winch in the middle position are symmetrically arranged; gradually starting the winch from the middle to the two sides, and enabling the winch to rise by a preset height each time; when the steel beam is hoisted to a cable core close to the corresponding horizontal elevation of the stay cable, correcting the horizontal state of the steel beam according to the horizontal elevation; connecting a stay cable and a steel beam at the horizontal elevation; and welding the steel beam and the lug plate. The invention adopts a plurality of groups of winches to hoist integrally and synchronously, and realizes the hoisting integrity and accuracy by multi-point positioning.

Description

Large-span steel beam hoisting construction method

Technical Field

The invention relates to the technical field of buildings, in particular to a construction method for hoisting a large-span steel beam.

Background

At present, with the rapid development of economy in China, the living standard of people is continuously improved, in order to meet the increasing material culture needs of people, public buildings often adopt a method of a large-span space structure to meet the requirements of use functions, and factory crane beams, glass curtain walls and the like of meeting rooms, movie theaters, medians, exhibition halls, industrial buildings of the public buildings mostly adopt large-span steel beam structures.

This kind of girder steel structure generally divides into several subsections with the girder steel at the hoist and mount in-process, utilizes tower crane or hoist engine with every section girder steel hoist and mount to neighbouring construction area. The steel beam is positioned in sections at high altitude and then integrally welded, the integrity and the accuracy of the steel beam cannot be ensured by the field high-altitude sectional positioning welding, and the problem of difficult positioning of hoisting is easily caused in the hoisting process.

Disclosure of Invention

The invention aims to provide a large-span steel beam hoisting construction method, which adopts a plurality of groups of winches to hoist integrally and synchronously and realizes the hoisting integrity and accuracy by multi-point positioning.

In order to solve the technical problems, the invention provides the following technical scheme for solving the technical problems:

the application relates to a large-span steel beam hoisting construction method which is characterized by comprising the following steps:

positioning the lug plate to the elevation position of the steel beam to be hoisted;

the steel beam penetrates through a plurality of stay ropes for guiding, wherein a rope core is sleeved on a horizontal elevation of each stay rope, which corresponds to the elevation position;

a plurality of winches for hoisting the steel beam are arranged on the top floor layer at intervals, and the winches on two sides of the middle winch in the middle position are symmetrically arranged;

gradually starting the winch from the middle to the two sides, and enabling the winch to rise by a preset height each time;

when the steel beam is hoisted to a cable core which is close to the inhaul cable and corresponds to the horizontal elevation, correcting the horizontal state of the steel beam according to the horizontal elevation;

connecting the inhaul cable and the steel beam at the horizontal elevation;

and welding the steel beam and the lug plate.

In the present application, the distance between adjacent hoists located on both sides of the middle hoist is equal.

In this application the girder steel hoist to being close to correspond of cable during the cable core of level elevation, according to the level elevation, rectify the horizontality of girder steel specifically does:

when the steel beam is hoisted to a cable core which is close to the inhaul cable and corresponds to the horizontal elevation, the horizontal elevation is set by utilizing a level meter, and a winch corresponding to a non-horizontal position is inching to enable the steel beam to be in a horizontal state.

In this application, when hoist a plurality of girder steels to parallel interval each other, a plurality of girder steels are according to hoist and mount height from low to high perpendicular pile up, wherein press from both sides between the contact surface of two adjacent girder steels and be equipped with the protection shield.

In this application, according to the hoist and mount height from high to each girder steel of low hoist and mount in proper order, and when a girder steel was accomplished in the hoist and mount, with last girder steel is operation platform, fixes a position the otic placode that is used for next girder steel.

In the present application, the protection plate is a tetrafluoroethylene plate.

In this application the horizontal elevation height is connected the cable with the girder steel specifically is:

and welding the inner wall of a guy cable hole of the steel beam for the guy cable to pass through by utilizing a rigging at the horizontal elevation, and limiting a guy cable core of the guy cable at the horizontal elevation to be positioned in the cavity of the rigging.

In the present application, the rigging comprises at least a first and a second discrete and symmetrical member, the first and second member being structurally identical, the first member comprising:

the inner diameter of the semicircular ring transverse plate is smaller than the outer diameter of the cable core;

the top end of the semi-arc side plate is vertically connected with the bottom surface of the semi-circular transverse plate, and the outer diameter of the cable core is smaller than the inner diameter of the semi-arc side plate;

when the first member with when the second member cooperates, the cable core at least part stretches into in the cavity that the semi-arc curb plate of first member and the semi-arc curb plate of second member enclose to support and lean on the semicircle ring diaphragm of first member the basal surface of semicircle ring diaphragm of second member, just the periphery lateral wall of the semicircle ring diaphragm of first member with the periphery lateral wall of the semicircle ring diaphragm of second member respectively with the cable hole inner wall welding of girder steel.

In this application, after welding the girder steel and otic placode, still include the following step:

and polishing the steel beam and the lug plate after full welding.

In the application, a carrying pole beam is arranged on the steel beam, and the steel wire rope of each winch hoists the steel beam through the carrying pole beam;

after the steel beam and the lug plate are welded, each winch discharges force, and then the carrying pole beam is dismantled.

The construction method for hoisting the large-span steel beam disclosed by the invention has the following advantages and beneficial effects:

the hoisting machines are gradually opened from the middle to the two sides, the hoisting machines are enabled to rise to a preset height every time, the whole steel beam is guaranteed to be synchronously and slowly hoisted, the hoisting stability is achieved, the horizontal state of the steel beam is corrected at the position close to the horizontal elevation, the accurate positioning of the final steel beam is guaranteed, and the appearance decoration effect of the steel beam is improved.

Other features and advantages of the present invention will become more apparent from the following detailed description of the invention when taken in conjunction with the accompanying drawings.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments of the present invention or the description in the prior art are briefly described below, and it is obvious that the drawings described below are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a flow chart of an embodiment of a large-span steel girder hoisting construction method provided by the invention;

fig. 2 is a connection cross-sectional view of a rigging connection cable and a steel beam in an embodiment of a large-span steel beam hoisting construction method provided by the invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In order to realize the integral synchronous hoisting of the large-span steel beam, the application relates to a large-span steel beam hoisting construction method.

In the application, the hoisting construction method aims to solve the problem of realizing the integral synchronous hoisting of the steel beam with the span of 44 meters and the weight of about 16 tons at the high altitude of 167.5 meters to 199.05 meters, and the horizontal multi-point simultaneous positioning of the steel beam is also realized in the hoisting construction method.

Referring to fig. 1, the hoisting construction method is specifically explained.

Aiming at the same surface of the stay cable curtain wall, a plurality of steel beams with different hoisting heights are needed, and each steel beam is hoisted in the same hoisting mode.

S1: and positioning the lug plate to the elevation position of the steel beam to be hoisted.

After the hoisting of each steel beam is completed (namely, the steel beam is hoisted to the elevation position and is in a horizontal state), the steel beam needs to be welded to the lug plate of the main body structure to realize fixed support, and therefore, the lug plate needs to be fixed before hoisting.

In the application, the position of the ear plate is accurately positioned by using a total station, the ear plate is rechecked for the second time, and the ear plate is welded according to the drawing requirements.

S2: the steel beam passes through the direction of a plurality of guys, wherein the horizontal elevation of the corresponding elevation position of each guy is sleeved with a cable core.

Each steel beam can pass through the stay cable in the hoisting process, so that the stay cable can be tensioned before hoisting.

And all overlap on the horizontal elevation that corresponds the elevation position department of every girder steel and have the cable core, promptly, all can have the cable core between the position department that every cable corresponds each girder steel of interval hoist and mount.

The cable core is specifically an annular cylindrical cable core fixedly sleeved on the inhaul cable.

The cable core aims to connect the stay cable and the steel beam after the steel beam is hoisted in place.

The steel beam is provided with a carrying pole beam, and the steel beam is connected with a steel wire rope of a winch through the carrying pole beam to realize hoisting.

The sequence of S1 and S2 is not sequential, and the lug plate and the cable may be positioned with respect to the elevation position of the steel beam.

S3: multiple winches for hoisting steel beams are arranged on the top floor layer at intervals, and the winches on two sides of the middle winch in the middle position are symmetrically arranged.

Set up many hoists at the floor top layer, reset the quantity of hoist, the interval of adjacent hoist and the rated load of hoist according to the length and the meter of girder steel.

In the present application, the steel beam as described above has a weight of 370kg/m in meters, a total length of 44m and a weight of about 16 tons.

16 winches were selected and the nominal load of each winch was 3 tonnes, thus about 1 tonne per winch.

And each winch adopts double steel wire ropes, the diameter of each steel wire rope is 15mm, a single steel wire rope can theoretically bear 3 tons, the stress of each steel wire rope does not exceed 600kG actually, and the stress requirement is completely met.

The hoist needs to be placed on the top floor level using pedestals (e.g., welded from transverse/longitudinal i-beams) and secured using chemical anchors (e.g., M16 chemical anchors).

In this application, hoist engine symmetric distribution of hoist engine both sides in the middle of in order to ensure the girder steel level through many hoist engine hoist and mount girder steel.

For example, when the number of the windlasses is even 16, the two windlasses located in the middle are called middle windlasses, wherein the two windlasses on both sides are symmetrically distributed to the middle windlass.

For example, when the number of the winches is an odd number 15, the winch located at the middle is called a middle winch, and 7 winches at two sides are symmetrically distributed to the middle winch.

The symmetric distribution as described above includes two cases: (1) The distance between two adjacent winches on each side is different; (2) The distance between two adjacent winches on each side is the same.

In this application, the distance between two adjacent winches in all the winches is the same.

In order to avoid the abrasion of the steel wire rope of the winch, a hard PVC pipe with the diameter of 100 for example can be sleeved into a pre-opened floor slab hole, so that the steel beam can be conveniently lifted.

When hoisting a plurality of girder steels on same face, according to the drawing, the girder steel is according to hoist and mount height from low to high perpendicular stacking in proper order, requires the cable hole that supplies the cable to pass of every girder steel at same vertical position, is convenient for wear the cable.

And a protective plate is clamped between the contact surfaces of the adjacent steel beams which are vertically stacked.

This protection shield can select multiple material, for example can be the polytetrafluoroethylene board, guarantees not to let its surface impaired because of the friction between the adjacent girder steel.

S4: and gradually starting the winch from the middle to two sides, and enabling the winch to rise by a preset height every time.

The top surface of a floor where the winch is located is provided with a datum line, the winch is gradually started from the middle to two sides, and the steel beam is guaranteed not to rise more than a preset height, such as 15cm.

Should predetermine the height should not be too big to guarantee the stable hoist and mount of girder steel.

In a previous test, how high the steel beam rises when the winch is started to hold for example for a few seconds is tested through a plurality of tests, and therefore, how long the winch is kept to hold each time and rise the steel beam is set by empirical values.

Keep the interval between adjacent two hoists in all hoists equal as above, can guarantee the stable hoist and mount to the girder steel, do benefit to the horizontality of rectifying the girder steel.

S5: and when the steel beam is hoisted to the cable core close to the corresponding horizontal elevation of the stay cable, correcting the horizontal state of the steel beam according to the horizontal elevation.

As mentioned above, the elevation position to which the steel beam is hoisted is basically on the same horizontal line with the cable core on the cable at the horizontal elevation.

When the steel beam is hoisted upwards to the cable core close to the inhaul cable, the level gauge can be used for setting the horizontal elevation, the winch corresponding to the steel beam with a relatively low or higher position is inching, the positioning adjustment of multiple non-horizontal positions is realized, and the steel beam is slowly adjusted to be in a horizontal state.

It should be noted that, the place department of girder steel hoist and mount position and hoist engine position department respectively have a set of people to observe the synchronous condition, and everybody is furnished with the intercom, and every hoist engine all has the serial number, if discover the asynchronous condition, communicate the adjustment at any time.

For example, if there are 16 groups of windlasses working synchronously for each face, each face is divided into two groups of people, each group is, for example, 8, each person is at the position of the windlass and the steel beam, and each person controls 2 windlasses and uses the interphone to realize synchronous channel communication.

S6: and connecting the inhaul cable and the steel beam at the horizontal elevation.

After the steel beam is adjusted to be in a horizontal state, the cable core of the inhaul cable and the steel beam are connected through the cable tool, and then the zipper and the steel beam are connected together.

Referring to fig. 2, a cross-sectional view of connecting a cable a and a steel beam B using rigging is shown.

After the steel beam B is adjusted to be in a horizontal state, the cable core C of the corresponding cable A is positioned in the cable hole 21 of the steel beam B for the cable A to pass through.

As mentioned above, the cable core C is an annular cylinder fixedly sleeved on the cable a.

The rigging includes at least a first member 22 and a second member 23 that are discrete and symmetrical.

The structure of the first member 22 will be described as an example.

The first member 22 includes a semi-circular cross plate 221 and semi-arcuate side plates 222.

The top end of the semi-arc side plate 222 is vertically connected with the bottom surface of the semi-circular cross plate 221.

The inner diameter r1 of the semicircular ring transverse plate 221 is smaller than the radius r2 of the cable core C, and the radius r2 of the cable core C is smaller than the inner diameter r3 of the semi-arc side plate 222.

That is, when the first member 22 and the second member 23 are engaged, the semicircular lateral plate 221 of the first member 22 and the semicircular lateral plate of the second member 23 form an entire circular ring, and the semicircular lateral plate 222 of the first member 22 and the semicircular lateral plate of the second member 23 form an entire hollow cylinder.

The inner diameter of the circular ring (i.e., r 1) is smaller than the radius r2 of the cord core C, and the radius r2 of the cord core C is smaller than the inner diameter of the hollow cylinder (i.e., r 3).

The first member 22 and the second member 23 of the rigging are respectively placed into the cable hole 21 from above the cable hole 21, at this time, because the radius r2 of the cable core C is smaller than the inner diameter r3 of the hollow cylinder, the cable core C at least partially extends into the cavity D of the hollow cylinder, the top of the cable core C is in contact with the bottom surface of the circular ring, and the peripheral side wall of the cable core C has a certain margin with the inner side wall of the hollow cylinder, so that the cable core C has a certain moving space in the cavity D for releasing stress.

In order to realize the connection of the rigging and the steel beam B, the inner side wall of the cable hole 21 of each steel beam is coated with a metal material, so that a metal coating 24 with a certain thickness is formed around the inner side wall of the cable hole 21, and the outer circumferential side wall of the ring is conveniently welded on the metal coating 24.

In order to shield the cable hole 21, the rigging further comprises a third member 24 and a fourth member 25, and the third member 24 and the fourth member 25 are identical in structure.

The third member 24 and the fourth member 25 are semicircular ring plates, and the inner diameter of the semicircular ring plate is substantially equal to the radius r4 of the cross section of the cable a.

When the third member 24 and the fourth member 25 are mated, the semicircular ring plate of the third member 24 and the semicircular ring plate of the fourth member 25 form an overall circular ring.

The inner diameter of the ring is substantially equal to the radius r4 of the cross section of the stay a.

The outer circumferential side wall of the third member 24 and the outer circumferential side wall of the fourth member 25 are welded to the metal coating 24 (e.g., on the portion of the metal coating 24 above the cord core C).

A fifth member 26 and a sixth member 27 may also be included, with the third member 24, fourth member 25, fifth member 26 and sixth member 27 all being identical in construction to one another.

As described above, when the fifth member 26 and the sixth member 27 are mated, the semicircular ring plate of the fifth member 26 and the semicircular ring plate of the sixth member 27 form an entire circular ring.

The outer circumferential side wall of the fifth member 26 and the outer circumferential side wall of the sixth member 27 are welded to the metal coating 24 (e.g., on the portion of the metal coating 24 that is below the cord core C).

S7: and welding the steel beam and the lug plate.

And welding the steel beam and the lug plate to realize the fixation of the steel beam after hoisting.

And then, fully welding the steel beam and the lug plate and then grinding to reduce the stress.

And after the steel beam and the lug plate are welded, each winch unloads force, and the carrying pole beam on the steel beam can be detached at the moment.

After the last steel beam is finished, the steel beam is used as a construction operation platform, and the lug plate for the next steel beam is positioned and installed.

And then hoisting other steel beams by the same method as the hoisting construction method.

This application realizes whole synchronous hoist and mount girder steel through many hoists that set up, and hoist and mount are stable and the location is accurate, has solved the unstable and difficult problem of location of segmentation hoist and mount among the prior art.

In addition, this application has satisfied the requirement that the cable curtain is high to the girder steel accuracy, the wholeness is good, has satisfied the requirement that girder steel outward appearance decorative effect is good again, helps promoting indoor appearance design's aesthetic feeling.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (6)

1. A large-span steel beam hoisting construction method is characterized by comprising the following steps:

s1: positioning the lug plate to the elevation position of the steel beam to be hoisted;

s2: the steel beam is guided by penetrating through a plurality of tensioned cables, and a cable core is sleeved on a horizontal elevation of each cable corresponding to the elevation position;

s3: a plurality of winches for hoisting the steel beam are arranged on the top layer of the floor at intervals, the winches on two sides of the middle winch at the middle position are symmetrically arranged, the intervals between adjacent winches are the same, and the rated loads of all the winches are also the same;

s4: gradually starting the winch from the middle to the two sides, and enabling the winch to rise by a preset height each time;

s5: when the steel beam is hoisted to a cable core close to the inhaul cable and corresponding to the horizontal elevation, the horizontal elevation is set by using a level gauge, and a corresponding winch at a non-horizontal position is inching to enable the steel beam to be in a horizontal state;

s6: welding the inner wall of a guy cable hole of the steel beam for the guy cable to pass through by using a rigging at the horizontal elevation, and limiting a cable core of the guy cable at the horizontal elevation to be in a cavity of the rigging;

wherein the rigging includes at least first and second discrete and symmetrical members, the first and second members being structurally identical, the first member comprising:

the inner diameter of the semicircular ring transverse plate is smaller than the outer diameter of the cable core;

the top end of the semi-arc side plate is vertically connected with the bottom surface of the semi-circular transverse plate, and the outer diameter of the cable core is smaller than the inner diameter of the semi-arc side plate;

when the first member is matched with the second member, at least part of the cable core extends into a cavity defined by the semi-arc-shaped side plates of the first member and the second member and abuts against the bottom surface of the semi-circular cross plate of the second member of the semi-circular cross plate of the first member, and the outer circumferential side wall of the semi-circular cross plate of the first member and the outer circumferential side wall of the semi-circular cross plate of the second member are respectively welded with the inner wall of the cable hole of the steel beam;

s7: welding the steel beam and the ear plate;

when a plurality of steel beams are hoisted on the same surface, according to a drawing, the steel beams are vertically stacked in sequence from low to high according to the hoisting height, and the steel beams are hoisted in sequence from high to low according to the hoisting height.

2. The large-span steel beam hoisting construction method according to claim 1, wherein a protection plate is clamped between contact surfaces of two adjacent steel beams vertically stacked from low to high.

3. The hoisting construction method for the large-span steel beam according to claim 2,

and when the last steel beam is hoisted, the last steel beam is taken as an operation platform, and the lug plate for the next steel beam is positioned.

4. The hoisting construction method for the large-span steel beam according to claim 2,

the protection plate is a tetrafluoroethylene plate.

5. The large-span steel girder hoisting construction method according to claim 1, further comprising the following steps after the steel girder and the lug plate are welded:

and polishing the steel beam and the lug plate after full welding.

6. The large-span steel beam hoisting construction method according to claim 1, wherein a carrying pole beam is arranged on the steel beam, and the steel wire rope of each winch hoists the steel beam through the carrying pole beam;

after welding the steel beams and the ear plates, each winch unloads the force, and then the carrying pole beam is removed.

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