CN107227741B - Basement supporting construction - Google Patents

Abstract

The invention discloses a kind of basement supporting construction, it is characterized in that arch brace is arranged in the middle part of basement, basement is arranged right-angled intersection and steel lattice column is arranged to support beam crossover sites to support beam, arch brace and right-angled intersection, and basement fender post uses cast-in-situ bored pile；Cement mixing pile water stopping curtain is arranged in cast-in-situ bored pile periphery；Concrete capping beam is set at the top of cast-in-situ bored pile, and when basement cutting depth is less than or equal to 3.5m, vertical plane uses row's supporting construction, and steel suspension cable drawknot node is arranged, and steel suspension cable uses prestressed stretch-draw；Concrete cast-in-place slab is arranged in four corners；When basement cutting depth is greater than 3.5m, vertical plane is using two rows of supporting construction；Steel suspension cable drawknot node is set, and steel suspension cable uses prestressed stretch-draw；Steel pipe is set between arch brace and concrete capping beam to support.

Description

Basement supporting construction

Technical field

The present invention relates to a kind of supporting construction, in particular to a kind of basement supporting construction.

Background technique

When basement excavation is deeper, setting concrete resists passive earth pressure to support, and concrete is excessive to support to be arranged not But it will increase engineering cost, and be unfavorable for cutting the earth, concrete can be very big to the suffered horizontal axle power of support, how both to have reduced mixed Solidifying soil can ensure that safety is the project that engineering staff faces to the axle power of support again.But how to be reduced in the case where ensuring secured premise Cost.

Summary of the invention

The purpose of the present invention is to provide a kind of basement supporting construction to solve the deficiencies in the prior art.

Arch brace is arranged in the present invention in the middle part of basement, and arch brace area is 30~80m², arch brace center is At the centroid of basement geometry, arch brace height is 500~700mm, and arch brace width is 250~300mm.

Right-angled intersection is arranged to support beam in basement, and right-angled intersection is to centroid of the crosspoint in basement geometry for supportting beam Place.Right-angled intersection is 600~800mm to support depth of beam, and right-angled intersection is 250~300mm to support beam width.

Steel lattice column is arranged to support beam crossover sites in arch brace and right-angled intersection, steel lattice column be inserted into engineering pile 500~ 600mm, steel lattice column are higher by concrete and bear down on one top surface of the beam 0.7~0.9m of absolute altitude, and prestressed stretch-draw pier is arranged above steel lattice column.

Basement fender post uses cast-in-situ bored pile；Cement mixing pile water stopping curtain, cement is arranged in cast-in-situ bored pile periphery Stirring cement mixing pile diameter used by pile water stopping curtain is 500mm, and adjacent cement mixing pile is mutually twisted 300~400mm； Concrete capping beam is set at the top of cast-in-situ bored pile, and it is highly 500~600mm that concrete, which bears down on one beam width as 300mm,；It is local When lower room cutting depth is more than or equal to 3.5m, concrete breast beam is set, position is arranged vertical in concrete breast beam in the middle part of basement With concrete capping beam be in plane it is identical, it is highly 500~600mm that concrete breast beam width, which is 300mm,.

When basement cutting depth is less than or equal to 3.5m, vertical plane uses row's supporting construction, in right-angled intersection pair It supports 1/8 span of beam top, 1/4 span, 3/4 span and 7/8 span position and drawknot node on steel suspension cable is set, in right-angled intersection to support Drawknot node under 3/8 span of beam lower part, 1/2 span and 5/8 span position setting steel suspension cable, span refers to right-angled intersection to support here Beam and concrete capping beam crosspoint and arch brace and right-angled intersection are to the distance between support beam crosspoint.Steel suspension cable is using pre- Stress tension.

When basement cutting depth is greater than 3.5m, vertical plane is using two rows of supporting construction；First row supporting construction exists Right-angled intersection is to drawknot node on support 1/8 span of beam top, 1/4 span, 3/4 span and 7/8 span position setting steel suspension cable, ten Word cross-pair supports 3/8 span of beam lower part, 1/2 span and 5/8 span position and drawknot node under steel suspension cable is arranged, and four corners setting is mixed Solidifying soil Bars In Poured Concrete Slab, concrete cast-in-situ plate suqare are more than or equal to 5m², concrete cast-in-place slab is with a thickness of 12~15mm, and arrangement of reinforcement is using straight Diameter is 12~14mm；It is concentrated since the four corners of first row supporting construction will appear stress, being provided with concrete cast-in-place slab can Effectively to alleviate the stress at these positions.Second row supporting construction is arranged at the 1/2 of cutting depth, second row supporting construction Drawknot node on steel suspension cable is arranged to support 1/8 span of beam top, 1/4 span, 3/4 span and 7/8 span position in right-angled intersection, Right-angled intersection is to drawknot node under support 3/8 span of beam lower part, 1/2 span and 5/8 span position setting steel suspension cable, and steel suspension cable is using pre- Stress tension；Steel pipe is set between arch brace and concrete capping beam to support.

When basement cutting depth is greater than 3.5m, construction procedure includes:

(1) construction fender post；

(2) concrete capping beam is set at the top of fender post；

(3) when the Construction of Engineering Pile of steel lattice column is arranged, steel lattice column is inserted into when engineering pile concrete is unhardened；

(4) first row arch brace and first row right-angled intersection are poured to support beam concrete；

(5) concrete cast-in-place slab of first row supporting construction is poured；

(6) the steel suspension cable drawknot node of first row supporting construction is set；Right-angled intersection is to support beam top main reinforcement welded suspending hook As drawknot node on steel suspension cable；Under steel suspension cable drawknot node be provided that right-angled intersection to support beam in the small round tube of oblique plastics is set, Steel suspension cable is in the small round tube of oblique plastics, and right-angled intersection is to support beam lower part main reinforcement welded suspending hook as drawknot node under steel suspension cable；

(7) prestressed stretch-draw is carried out to the steel suspension cable of first row supporting construction；

Tension sequence is using as follows: using tensioning three times, first time tensioning parameter is using as follows: pretensioning arch brace model The steel suspension cable of upper drawknot node in the range between the steel suspension cable of interior upper drawknot node, then tensioning arch brace and concrete capping beam is enclosed, Then the steel suspension cable of drawknot node, range between last tensioning arch brace and concrete capping beam are descended within the scope of tensioning arch brace The steel suspension cable of interior lower drawknot node, tension stress use the 30% of total tension stress.Second of tensioning parameter is using as follows: pretensioning The steel suspension cable of upper drawknot node within the scope of arch brace, then upper drawknot node in the range between tensioning arch brace and concrete capping beam Steel suspension cable, then within the scope of tensioning arch brace lower drawknot node steel suspension cable, last tensioning arch brace bears down on one with concrete The steel suspension cable of lower drawknot node, tension stress use the 60% of total tension stress in the range between beam.Third time tensioning parameter uses It is as follows: the steel suspension cable of upper drawknot node within the scope of pretensioning arch brace, then model between tensioning arch brace and concrete capping beam The steel suspension cable of interior upper drawknot node is enclosed, the steel suspension cable of drawknot node, last tensioning arch brace are then descended within the scope of tensioning arch brace With the steel suspension cable of drawknot node lower in the range between concrete capping beam, tension stress uses the 100% of total tension stress.

For different earth excavation depth and different spans, using different total stretching forces, as shown in table 1, different is opened It digs depth or different spans determines total stretching force according to interpolation method.

Total stretching force under 1 different situations of table

(8) 2cm below earth excavation to second row supporting construction bottom absolute altitude；

(9) casting concrete waist rail；

(10) second row arch brace and right-angled intersection are poured to support beam concrete；

(11) steel pipe of second row supporting construction is set to support；

(12) the steel suspension cable drawknot node of second row supporting construction is set；Right-angled intersection is to support beam top main reinforcement welded suspending hook As drawknot node on steel suspension cable；Under steel suspension cable drawknot node be provided that right-angled intersection to support beam in the small round tube of oblique plastics is set, Steel suspension cable is in the small round tube of oblique plastics, and drawknot node is welded on right-angled intersection to support beam lower part main reinforcement under steel suspension cable；

(13) prestressed stretch-draw is carried out to the steel suspension cable of second row supporting construction；The steel suspension cable tensioning of second row supporting construction Parameter is identical as the steel suspension cable tensioning parameter of first row supporting construction；

(14) earthwork between second row arch brace and concrete breast beam is excavated to basement bottom board bottom absolute altitude；Retain the The earthwork is conducive to basement and stablizes within the scope of two row's arch braces to form central island effect；

(15) basement bottom board and sidewall of basement between second row arch brace and concrete breast beam are poured；In annulus Steel plate water stopper is arranged in the basement bottom board of support zone；

(16) earthwork is excavated within the scope of second row arch brace to basement bottom board bottom absolute altitude；

(17) basement bottom board within the scope of second row arch brace is poured；

(18) the steel suspension cable of second row supporting construction is first removed, then removes second row arch brace and right-angled intersection to support beam Concrete；

(19) the steel suspension cable of first row supporting construction is first removed, then removes first row arch brace and right-angled intersection to support beam Concrete.

When basement cutting depth is less than or equal to 3.5m, construction procedure includes:

(1) construction fender post；

(2) concrete capping beam is set at the top of fender post；

(3) when the Construction of Engineering Pile of steel lattice column is arranged, steel lattice column is inserted into when engineering pile concrete is unhardened；

(4) arch brace and right-angled intersection are poured to support beam concrete；

(5) concrete cast-in-place slab of supporting construction is poured；

(6) the steel suspension cable drawknot node of supporting construction is set；Right-angled intersection is to support beam top main reinforcement welded suspending hook as steel Drawknot node on suspension cable；Under steel suspension cable drawknot node be provided that right-angled intersection to support beam in the small round tube of oblique plastics, steel suspension cable are set In the small round tube of oblique plastics, right-angled intersection is to support beam lower part main reinforcement welded suspending hook as drawknot node under steel suspension cable；

(7) prestressed stretch-draw is carried out to the steel suspension cable of supporting construction；

Tension sequence is using as follows: using tensioning three times, first time tensioning parameter is using as follows: pretensioning arch brace model The steel suspension cable of upper drawknot node in the range between the steel suspension cable of interior upper drawknot node, then tensioning arch brace and concrete capping beam is enclosed, Then the steel suspension cable of drawknot node, range between last tensioning arch brace and concrete capping beam are descended within the scope of tensioning arch brace The steel suspension cable of interior lower drawknot node, tension stress use the 30% of total tension stress.Second of tensioning parameter is using as follows: pretensioning The steel suspension cable of upper drawknot node within the scope of arch brace, then upper drawknot node in the range between tensioning arch brace and concrete capping beam Steel suspension cable, then within the scope of tensioning arch brace lower drawknot node steel suspension cable, last tensioning arch brace bears down on one with concrete The steel suspension cable of lower drawknot node, tension stress use the 60% of total tension stress in the range between beam.Third time tensioning parameter uses It is as follows: the steel suspension cable of upper drawknot node within the scope of pretensioning arch brace, then model between tensioning arch brace and concrete capping beam The steel suspension cable of interior upper drawknot node is enclosed, the steel suspension cable of drawknot node, last tensioning arch brace are then descended within the scope of tensioning arch brace With the steel suspension cable of drawknot node lower in the range between concrete capping beam, tension stress uses the 100% of total tension stress.

(8) earthwork between arch brace and concrete capping beam is excavated to basement bottom board bottom absolute altitude；Retain annulus branch The earthwork is in support range to form central island effect；

(9) basement bottom board and sidewall of basement between arch brace and concrete capping beam are poured；In arch brace Steel plate water stopper is arranged in the basement bottom board at position；

(10) earthwork is excavated within the scope of arch brace to basement bottom board bottom absolute altitude；

(11) basement bottom board within the scope of arch brace is poured；

(12) the steel suspension cable of supporting construction is first removed, then removes arch brace and right-angled intersection to support beam concrete.

The present invention has the advantages that construction safety is reliable, at low cost.

Detailed description of the invention

Fig. 1, row's supporting construction elevational schematic view, Fig. 2, two row's supporting construction elevational schematic views, Fig. 3, row's supporting knot Structure floor map, Fig. 4, two row's supporting construction floor map, Fig. 5, right-angled intersection are to support beam bending moment envelope diagram.

In each attached drawing: 1, concrete capping beam, 2, right-angled intersection to support beam, 3, steel lattice column, 4, concrete cast-in-place slab, 5, Concrete breast beam, 6, steel pipe is to support, 7, steel suspension cable, 8, prestressed stretch-draw pier.

Specific embodiment

Embodiment one

Arch brace is arranged in the present embodiment in the middle part of basement, and arch brace area is 50m², arch brace center is ground At the centroid of lower room geometry, arch brace height is 600mm, and arch brace width is 300mm.

Right-angled intersection is arranged to support beam 2 in basement, and right-angled intersection is to shape of the crosspoint in basement geometry for supportting beam 2 At the heart.Right-angled intersection is 700mm to support 2 height of beam, and right-angled intersection is 300mm to support 2 width of beam.

Steel lattice column 3 is arranged to support 2 crossover sites of beam in arch brace and right-angled intersection, and steel lattice column 3 is inserted into engineering pile 600mm, steel lattice column 3 are higher by 1 top surface absolute altitude 0.8m of concrete capping beam, and prestressed stretch-draw pier 8 is arranged in steel lattice column 3 above.

Basement fender post uses cast-in-situ bored pile；Cement mixing pile water stopping curtain, cement is arranged in cast-in-situ bored pile periphery Stirring cement mixing pile diameter used by pile water stopping curtain is 500mm, and adjacent cement mixing pile is mutually twisted 350mm；Drilling Concrete capping beam 1 is set at the top of bored concrete pile, and it is highly 600mm that 1 width of concrete capping beam, which is 300mm,.

Basement cutting depth is 3m, and vertical plane uses row's supporting construction, in right-angled intersection to support 2 top 1/8 of beam Drawknot node on span, 1/4 span, 3/4 span and 7/8 span position setting steel suspension cable 7, in right-angled intersection to support 2 lower part 3/8 of beam Span, 1/2 span and the lower drawknot node of 5/8 span position setting steel suspension cable 7, it is according to moment of flexure that position, which is arranged, in 7 drawknot node of steel suspension cable Envelope diagram and obtain, these positions carry out prestressing force drawknot can make right-angled intersection to support 2 bending moment envelope diagram of beam it is more reasonable； So that right-angled intersection is converted to pulling force to support 2 axle power of beam by the prestressing force drawknot of steel suspension cable 7 and passes to steel lattice column 3.Steel suspension cable 7 Using prestressed stretch-draw.Concrete cast-in-place slab 4 is arranged in four corners, and 4 area of concrete cast-in-place slab is 8m², concrete cast-in-place slab 4 With a thickness of 12~15mm, arrangement of reinforcement uses diameter for 12~14mm.

Construction procedure includes:

(1) construction fender post；

(2) concrete capping beam 1 is set at the top of fender post；

(3) when the Construction of Engineering Pile of steel lattice column 3 is arranged, steel lattice column 3 is inserted into when engineering pile concrete is unhardened；

(4) arch brace and right-angled intersection are poured to support 2 concrete of beam；

(5) concrete cast-in-place slab 4 of supporting construction is poured；

(6) 7 drawknot node of steel suspension cable of supporting construction is set；Right-angled intersection is to support 2 top main reinforcement welded suspending hook conduct of beam Drawknot node on steel suspension cable 7；The lower drawknot node of steel suspension cable 7 be provided that right-angled intersection to the small round tube of oblique plastics is arranged in support beam 2, Steel suspension cable 7 is in the small round tube of oblique plastics, and right-angled intersection is to support 2 lower part main reinforcement welded suspending hook of beam as the lower drawknot of steel suspension cable 7 Point；

(7) prestressed stretch-draw is carried out to the steel suspension cable 7 of supporting construction；

Tension sequence is using as follows: using tensioning three times, first time tensioning parameter is using as follows: pretensioning arch brace model Enclose the steel suspension cable of upper drawknot node in the range between the steel suspension cable 7 of interior upper drawknot node, then tensioning arch brace and concrete capping beam 1 7, the steel suspension cable 7 of drawknot node is then descended within the scope of tensioning arch brace, between last tensioning arch brace and concrete capping beam 1 The steel suspension cable 7 of lower drawknot node, tension stress use the 30% of total tension stress in range.Second of tensioning parameter is using as follows: The steel suspension cable 7 of upper drawknot node within the scope of pretensioning arch brace, then in the range between tensioning arch brace and concrete capping beam 1 The steel suspension cable 7 of upper drawknot node, then within the scope of tensioning arch brace lower drawknot node steel suspension cable 7, last tensioning arch brace with The steel suspension cable 7 of lower drawknot node, tension stress use the 60% of total tension stress in the range between concrete capping beam 1.For the third time Tensioning parameter is using as follows: the steel suspension cable 7 of upper drawknot node within the scope of pretensioning arch brace, then tensioning arch brace and concrete Then the steel suspension cable 7 of drawknot node in the range between capping beam 1 descends the steel suspension cable 7 of drawknot node, most within the scope of tensioning arch brace The steel suspension cable 7 of lower drawknot node, tension stress are answered using total tensioning in the range between post-stretching arch brace and concrete capping beam 1 The 100% of power.Total stretching force uses 1.417MPa.

(8) earthwork between arch brace and concrete capping beam 1 is excavated to basement bottom board bottom absolute altitude；Retain annulus branch The earthwork is in support range to form central island effect；

(9) basement bottom board and sidewall of basement between arch brace and concrete capping beam 1 are poured；In arch brace Steel plate water stopper is arranged in the basement bottom board at position；

(10) earthwork is excavated within the scope of arch brace to basement bottom board bottom absolute altitude；

(11) basement bottom board within the scope of arch brace is poured；

(12) the steel suspension cable 7 of supporting construction is first removed, then removes arch brace and right-angled intersection to support 2 concrete of beam.

Embodiment two

Arch brace is arranged in the present embodiment in the middle part of basement, and arch brace area is 50m², arch brace center is ground At the centroid of lower room geometry, arch brace height is 600mm, and arch brace width is 300mm.

Right-angled intersection is arranged to support beam 2 in basement, and right-angled intersection is to shape of the crosspoint in basement geometry for supportting beam 2 At the heart.Right-angled intersection is 700mm to support 2 height of beam, and right-angled intersection is 300mm to support 2 width of beam.

Steel lattice column 3 is arranged to support 2 crossover sites of beam in arch brace and right-angled intersection, and steel lattice column 3 is inserted into engineering pile 600mm, steel lattice column 3 are higher by 1 top surface absolute altitude 0.8m of concrete capping beam, and prestressed stretch-draw pier 8 is arranged in steel lattice column 3 above.

Basement fender post uses cast-in-situ bored pile；Cement mixing pile water stopping curtain, cement is arranged in cast-in-situ bored pile periphery Stirring cement mixing pile diameter used by pile water stopping curtain is 500mm, and adjacent cement mixing pile is mutually twisted 350mm；Drilling Concrete capping beam 1 is set at the top of bored concrete pile, and it is highly 600mm that 1 width of concrete capping beam, which is 300mm,；When basement excavates When depth is more than or equal to 3.5m, concrete breast beam 5 is set, position is arranged in vertical plane in concrete breast beam 5 in the middle part of basement Be with concrete capping beam 1 it is identical, 5 width of concrete breast beam be 300mm, be highly 600mm.

When basement cutting depth is 4.8m, vertical plane is using two rows of supporting construction；First row supporting construction is in cross Cross-pair supports 2 top of beam, 1/8 span, 1/4 span, 3/4 span and 7/8 span position and drawknot node on steel suspension cable 7 is arranged, in cross It is mixed that cross-pair supports 2 lower part of beam, 3/8 span, 1/2 span and the lower drawknot node of 5/8 span position setting steel suspension cable 7, four corners setting Solidifying soil Bars In Poured Concrete Slab 4,4 area of concrete cast-in-place slab are 8m², concrete cast-in-place slab 4 with a thickness of 12~15mm, arrangement of reinforcement use diameter for 12~14mm.Second row supporting construction is arranged at the 1/2 of cutting depth, and second row supporting construction is in right-angled intersection to support beam 2 Drawknot node on 1/8 span of top, 1/4 span, 3/4 span and 7/8 span position setting steel suspension cable 7, in right-angled intersection to support beam 2 3/8 span of lower part, 1/2 span and the lower drawknot node of 5/8 span position setting steel suspension cable 7, steel suspension cable 7 use prestressed stretch-draw.? Steel pipe is set between arch brace and concrete capping beam 1 to support 6.

Construction procedure includes:

(1) construction fender post；

(2) concrete capping beam 1 is set at the top of fender post；

(3) when the Construction of Engineering Pile of steel lattice column 3 is arranged, steel lattice column 3 is inserted into when engineering pile concrete is unhardened；

(4) first row arch brace and first row right-angled intersection are poured to support 2 concrete of beam；

(5) concrete cast-in-place slab 4 of first row supporting construction is poured；

(6) 7 drawknot node of steel suspension cable of first row supporting construction is set；Support 2 top main reinforcement of beam welding is hung in right-angled intersection Hook is as drawknot node on steel suspension cable 7；The lower drawknot node of steel suspension cable 7 is provided that right-angled intersection is small to oblique plastics are arranged in support beam 2 Round tube, steel suspension cable 7 is in the small round tube of oblique plastics, and right-angled intersection is to support 2 lower part main reinforcement welded suspending hook of beam as under steel suspension cable 7 Drawknot node；

(7) prestressed stretch-draw is carried out to the steel suspension cable 7 of first row supporting construction；

Tension sequence is using as follows: using tensioning three times, first time tensioning parameter is using as follows: pretensioning arch brace model Enclose the steel suspension cable of upper drawknot node in the range between the steel suspension cable 7 of interior upper drawknot node, then tensioning arch brace and concrete capping beam 1 7, the steel suspension cable 7 of drawknot node is then descended within the scope of tensioning arch brace, between last tensioning arch brace and concrete capping beam 1 The steel suspension cable 7 of lower drawknot node, tension stress use the 30% of total tension stress in range.Second of tensioning parameter is using as follows: The steel suspension cable 7 of upper drawknot node within the scope of pretensioning arch brace, then in the range between tensioning arch brace and concrete capping beam 1 The steel suspension cable 7 of upper drawknot node, then within the scope of tensioning arch brace lower drawknot node steel suspension cable 7, last tensioning arch brace with The steel suspension cable 7 of lower drawknot node, tension stress use the 60% of total tension stress in the range between concrete capping beam 1.For the third time Tensioning parameter is using as follows: the steel suspension cable 7 of upper drawknot node within the scope of pretensioning arch brace, then tensioning arch brace and concrete Then the steel suspension cable 7 of drawknot node in the range between capping beam 1 descends the steel suspension cable 7 of drawknot node, most within the scope of tensioning arch brace The steel suspension cable 7 of lower drawknot node, tension stress are answered using total tensioning in the range between post-stretching arch brace and concrete capping beam 1 The 100% of power.Total stretching force uses 0.907MPa.

(8) 2cm below earth excavation to second row supporting construction bottom absolute altitude；

(9) casting concrete waist rail 5；

(10) second row arch brace and right-angled intersection are poured to support 2 concrete of beam；

(11) steel pipe of second row supporting construction is set to support 6；

(12) 7 drawknot node of steel suspension cable of second row supporting construction is set；Support 2 top main reinforcement of beam welding is hung in right-angled intersection Hook is as drawknot node on steel suspension cable 7；The lower drawknot node of steel suspension cable 7 is provided that right-angled intersection is small to oblique plastics are arranged in support beam 2 Round tube, for steel suspension cable 7 in the small round tube of oblique plastics, the lower drawknot node of steel suspension cable 7 is welded on right-angled intersection to the support main steel in 2 lower part of beam Muscle；

(13) prestressed stretch-draw is carried out to the steel suspension cable 7 of second row supporting construction；The steel suspension cable 7 of second row supporting construction is opened Draw parameter identical as the 7 tensioning parameter of steel suspension cable of first row supporting construction；

(14) earthwork between second row arch brace and concrete breast beam 5 is excavated to basement bottom board bottom absolute altitude；Retain The earthwork is conducive to basement and stablizes within the scope of second row arch brace to form central island effect；

(15) basement bottom board and sidewall of basement between second row arch brace and concrete breast beam 5 are poured；In circle Steel plate water stopper is arranged in the basement bottom board of ring support zone；

(16) earthwork is excavated within the scope of second row arch brace to basement bottom board bottom absolute altitude；

(17) basement bottom board within the scope of second row arch brace is poured；

(18) the steel suspension cable 7 of second row supporting construction is first removed, then removes second row arch brace and right-angled intersection to support 2 concrete of beam；

(19) the steel suspension cable 7 of first row supporting construction is first removed, then removes first row arch brace and right-angled intersection to support 2 concrete of beam.

Claims (1)

1. a kind of basement supporting construction, it is characterized in that arch brace is arranged in the middle part of basement, arch brace area is 30~ 80m², arch brace center is at the centroid of basement geometry, and arch brace height is 500~700mm, and arch brace is wide Degree is 250~300mm；

Right-angled intersection is arranged to support beam in basement, and right-angled intersection is to the crosspoint of support beam at the centroid of basement geometry； Right-angled intersection is 600~800mm to support depth of beam, and right-angled intersection is 250~300mm to support beam width；

Steel lattice column is arranged to support beam crossover sites in arch brace and right-angled intersection, steel lattice column be inserted into engineering pile 500~ 600mm, steel lattice column are higher by concrete and bear down on one top surface of the beam 0.7~0.9m of absolute altitude, and prestressed stretch-draw pier is arranged above steel lattice column；

Basement fender post uses cast-in-situ bored pile；Cement mixing pile water stopping curtain is arranged in cast-in-situ bored pile periphery；Drill-pouring Concrete capping beam is arranged in stake top portion, and it is highly 500~600mm that concrete, which bears down on one beam width as 300mm,；When basement excavates When depth is more than or equal to 3.5m, concrete breast beam is set in the middle part of basement, concrete breast beam be arranged position in vertical plane with Concrete capping beam be it is identical, concrete breast beam width be 300mm, be highly 500~600mm；

When basement cutting depth is less than or equal to 3.5m, vertical plane uses row's supporting construction, in right-angled intersection to support beam Drawknot node on 1/8 span of top, 1/4 span, 3/4 span and 7/8 span position setting steel suspension cable, in right-angled intersection under support beam Drawknot node under 3/8 span of portion, 1/2 span and 5/8 span position setting steel suspension cable；Steel suspension cable uses prestressed stretch-draw；Four angles Concrete cast-in-place slab is arranged in portion；

When basement cutting depth is greater than 3.5m, vertical plane is using two rows of supporting construction；First row supporting construction is in cross Cross-pair supports 1/8 span of beam top, 1/4 span, 3/4 span and 7/8 span position and drawknot node on steel suspension cable is arranged, and hands in cross Concrete is arranged to drawknot node under support 3/8 span of beam lower part, 1/2 span and 5/8 span position setting steel suspension cable, four corners in fork Bars In Poured Concrete Slab；Second row supporting construction is arranged at the 1/2 of cutting depth, and second row supporting construction is in right-angled intersection to support beam top Drawknot node on 1/8 span, 1/4 span, 3/4 span and 7/8 span position setting steel suspension cable, in right-angled intersection to support beam lower part 3/ Drawknot node under 8 spans, 1/2 span and 5/8 span position setting steel suspension cable, steel suspension cable use prestressed stretch-draw；In arch brace Steel pipe is set between concrete capping beam to support；

When basement cutting depth is greater than 3.5m, construction procedure includes:

(1) construction fender post；

(2) concrete capping beam is set at the top of fender post；

(3) when the Construction of Engineering Pile of steel lattice column is arranged, steel lattice column is inserted into when engineering pile concrete is unhardened；

(4) first row arch brace and first row right-angled intersection are poured to support beam concrete；

(5) concrete cast-in-place slab of first row supporting construction is poured；

(6) the steel suspension cable drawknot node of first row supporting construction is set；Right-angled intersection is to support beam top main reinforcement welded suspending hook conduct Drawknot node on steel suspension cable；Drawknot node is provided that right-angled intersection to the small round tube of oblique plastics is arranged in support beam under steel suspension cable, and steel is outstanding Rope is in the small round tube of oblique plastics, and right-angled intersection is to support beam lower part main reinforcement welded suspending hook as drawknot node under steel suspension cable；

(7) prestressed stretch-draw is carried out to the steel suspension cable of first row supporting construction；

(8) 2cm below earth excavation to second row supporting construction bottom absolute altitude；

(9) casting concrete waist rail；

(10) second row arch brace and right-angled intersection are poured to support beam concrete；

(11) steel pipe of second row supporting construction is set to support；

(12) the steel suspension cable drawknot node of second row supporting construction is set；Right-angled intersection is to support beam top main reinforcement welded suspending hook conduct Drawknot node on steel suspension cable；Drawknot node is provided that right-angled intersection to the small round tube of oblique plastics is arranged in support beam under steel suspension cable, and steel is outstanding Rope is in the small round tube of oblique plastics, and drawknot node is welded on right-angled intersection to support beam lower part main reinforcement under steel suspension cable；

(13) prestressed stretch-draw is carried out to the steel suspension cable of second row supporting construction；The steel suspension cable tensioning parameter of second row supporting construction It is identical as the steel suspension cable tensioning parameter of first row supporting construction；

(14) earthwork between second row arch brace and concrete breast beam is excavated to basement bottom board bottom absolute altitude；Retain second row The earthwork is conducive to basement and stablizes within the scope of arch brace to form central island effect；

(15) basement bottom board and sidewall of basement between second row arch brace and concrete breast beam are poured；In arch brace Steel plate water stopper is arranged in the basement bottom board at position；

(16) earthwork is excavated within the scope of second row arch brace to basement bottom board bottom absolute altitude；

(17) basement bottom board within the scope of second row arch brace is poured；

(18) the steel suspension cable of second row supporting construction is first removed, then removes second row arch brace and right-angled intersection to support beam coagulation Soil；

(19) the steel suspension cable of first row supporting construction is first removed, then removes first row arch brace and right-angled intersection to support beam coagulation Soil.