CN104652675A - Hollow slab floor adopting steel net and calcium silicate plate for combined hole formation - Google Patents

Abstract

The invention provides a hollow slab floor adopting steel nets and calcium silicate plates for combined hole formation. The hollow slab floor consists of posts, beams, flange plates and cavity components formed by the steel nets and the calcium silicate plates, wherein the beams are reinforced concrete beams or sectional steel concrete combined beams, the flange plates are I-shaped cross section plates or T-shaped cross section plates, the cavity components formed by the steel nets and the calcium silicate plates are formed by the steel nets and the calcium silicate plates through mutual action, the steel nets form tetrahedrons of top surface plates, bottom surface plates and two side walls of hexahedron cavity components, the head and tail ends of the steel nets are overlapped at any one side of the tetrahedrons, the calcium silicate plates form the other two side wall plates of the steel net cavity components and support plates between the top surface plates and the bottom surface plates of the cavity components, the calcium silicate plates are arranged in edge reinforcing rib grooves formed in the two edges of the steel nets, and the concrete is cast in site in the posts, the beams and the flange plates.

Description

A kind of steel mesh and calcium silicate board with microporous combine the hollow building cover of pore-forming

Technical field

The present invention relates to the non-hollow building cover taking out heart pore-forming of a kind of Cavity structural member, be specifically related to the hollow building cover that a kind of steel mesh and calcium silicate board with microporous combine pore-forming.

Background technology

At present in cast-in-situ reinforced concrete hollow floor technical field, the Cavity structural member pore-forming moulding by casting hollow building cover of the all-sealed or light solid formula of usual employing, as the ZL200410082381.9 " a kind of hollow floor slab with small dense ribs " that inventor declares, adopt all-sealed thin-wall box body Cavity structural member to be embedded in floor slab with small dense ribs and form " T font " stressed cross-section hollow layer, solve the problem that " T font " stressed cross section little hollow-ribbed floor top board is smooth.But do not design steel bar stress bottom all-sealed thin-wall box body Cavity structural member and between hollow building cover template, one deck cracking resistance gauze wire cloth to be applied separately, again owing to adopting all-sealed thin-wall box body as Cavity structural member to realize little hollow-ribbed floor, hermetic thin-wall box body buoyancy is large; it is long that thin-wall box body makes the setting and hardening time; mould utilization factor is low; the large matter weight of thin-wall box body density, the defects such as production and transport inconvenience and thin-wall box body globality difference cracky.

Inventor has invented again the hollow building cover (ZL201320466241.6) of the netted box component pore-forming of a kind of combined type, make full use of concrete surface tension force, changing mesh shape does not allow concrete mortar permeate in netted combination Cavity structural member, utilize the netted box component of packing less combined type to substitute prior art hermetically sealed hollow cavity component or the solid Cavity structural member of polystyrene foam, overcome the defect that existing hollow building cover non-core-drawing pore-creating Cavity structural member exists; Reach that manufacturing speed is fast, production efficiency is high, with concrete plyability is good, cost is low, transport and easy construction, buoyancy are little, light weight, zero damaged, unshift, exempt and isolate cushion block and elongated fixing reinforcing bar etc.Achieve the breakthrough of hollow building cover new technology, become hollow building cover art innovative technology; But, the netted box component of combined type will bear the concrete pressure of working load and top flange, must to doing a large amount of supports and the shutoff of port in case, adopt steel pipe to make supporter and need inner a large amount of textural association, when adopting the shutoff of similar steel Web materials as port, binding site needs a large amount of welding, and combination difficulty is larger.

For solving the problem, inventor has invented again the cast-in-place hollow building < Application Number (patent) that a kind of steel mesh and polyphenyl block combine framework pore-forming: 201410181823.9 >, utilization development is a kind of has the superior one-tenth pole of hollow building cover overall performance, both concrete surface tension force had been made full use of, changing steel lattice shape does not allow concrete mortar infiltrate steel mesh, do not produce buoyancy, good with concrete relevance, strengthen structure stress, polyphenyl block is taked again to play a supporting role to steel mesh, steel mesh is made to bear the concrete normal pressure of working load and top flange, both combine, define steel mesh and polyphenyl block to combine framework and carry out the hermetically sealed hollow cavity component hole creating technology of alternative hollow building cover, but be used for specific function containing organic matter polyphenyl block Cavity structural member and build high fire prevention existence limitation, polyphenyl block delivery volume takies greatly the defect of carrying space.

Therefore, develop and a kind ofly have the superior one-tenth pole of hollow building cover overall performance, adopt steel mesh and calcium silicate board with microporous to be combined into the Cavity structural member of the pore-forming of cast-in-situ hollow building roof, its calcium silicate board with microporous also can adopt twice laid, saving energy; Both meet the advantage of inventor's prior art, overcome fire resistance rating when Cavity structural member that prior art steel mesh and polyphenyl block organic matter combine is built for specific function limited; When polyphenyl block supports empty in steel mesh, polyphenyl block density and capacity need be strengthened, improve compression capability, reduce the sex change amount of bearing working load; Polyphenyl block, when long-distance transportation, occupies loading space, strengthens cost; Polyphenyl block must make of the expandability plastic grain of standard, can not the defect of regenerated resource development and utilization; Optimize the hollow building cover prior art of steel mesh pore-forming, become the urgent need of hollow building cover art innovation.

Summary of the invention

This application provides a kind of innovative technology of hollow building cover pore-forming, the material waste of particularly producing calcium silicate board with microporous utilizes; The combining form of calcium silicate board with microporous and steel mesh; Steel mesh advantage and calcium silicate board with microporous performance are well combined and forms hollow building cover pore-forming Cavity structural member; Utilize this hollow building cover to become the important component part of building energy conservation integration again, guarantee to realize hollow building cover multifunctional application.

The object of the invention is to guarantee hollow building cover pore-forming specification, then make full use of hollow building cover and realize building energy conservation integration; Steel mesh advantage and calcium silicate board with microporous performance organically combined, become hollow building cover pore-forming Cavity structural member, steel mesh becomes the end face of Cavity structural member, bottom surface and two sidewalls; Calcium silicate board with microporous can adopt regenerated resource development and utilization to make, and both energy conservation, reduce costs, and becomes two sides at shutoff Cavity structural member two ends and the supporter of steel mesh inwall, lays calcium silicate board with microporous stabilized steel web frame intensity in the groove of the limit reinforcing rib at steel mesh edge; Steel mesh and calcium silicate board with microporous interact, Cavity structural member overall technology level can be promoted, effectively solve existing hollow building cover hole creating technology and there is the defect that Cavity structural member surface that vertical anti-floating, horizontal movement, the reinforcing bar of superstructure and Cavity structural member blending difference cause needs isolation processing and bottom surface cushion block, Cavity structural member cracky; When particularly solving Cavity structural member inner support and two ends shutoff organic object polyphenyl block, limited in specific function building fire resistance rating, need strengthen polyphenyl block density and unit weight to improve compression capability support in steel mesh empty bear working load, transport time polyphenyl block occupy that loading space strengthens cost, polyphenyl block must make of standard expandability plastic grain can not the defect such as regenerated resource development and utilization.

Technical scheme of the present invention is as follows, and a kind of steel mesh and calcium silicate board with microporous combine the hollow building cover of pore-forming, and the Cavity structural member formed by post, beam, frange plate, steel mesh and calcium silicate board with microporous forms; Described beam is reinforced concrete beam or transfer structure for SRC beams; Described frange plate is i shaped cross section plate or T font cross sectional plates; The Cavity structural member that described steel mesh and calcium silicate board with microporous are formed is interacted by steel mesh and calcium silicate board with microporous and forms; Described steel mesh forms the tetrahedron of the top panel of hexahedron Cavity structural member, bottom panel and two sidewalls; The head and the tail two ends of described steel mesh simultaneously overlap arbitrarily at tetrahedron; Described calcium silicate board with microporous forms the another two pieces of sidewall panelings of steel mesh Cavity structural member and gripper shoe between Cavity structural member top panel and bottom panel; Described calcium silicate board with microporous is placed in the limit reinforcing rib groove of steel mesh two edges; Cast-in-place concrete in described post, beam, frange plate.

More preferred, there is the cap being greater than 500mm solid section the surrounding outer of described post; Described cap is identical with the thickness of hollow building cover.

More preferred, described steel mesh is containing reticular lamina and ribs and junction plate and limit reinforcing rib, and described reticular lamina and ribs and junction plate and limit reinforcing rib make shaping by same thin steel plate the die-cut of special purpose machinery and expansion; The regular change of its grid direction of the reticular lamina of described steel mesh; The vertical direction of described steel mesh ribs is suppressed with bending trace; The crowning of described steel mesh ribs at the external surface of Cavity structural member, the width <1000mm of described steel mesh.

More preferred, described calcium silicate board with microporous is calcium silicate board with microporous; Inorganic matter silicon raw material and the calcareous raw material of discarded object is added with in described calcium silicate board with microporous; Described calcium silicate board with microporous forms steel mesh Cavity structural member two pieces of sidewall panelings and gripper shoe between Cavity structural member top panel and bottom panel; Empty in described gripper shoe length >=Cavity structural member, direct support sidewall paneling.

More preferred, in steel mesh Cavity structural member two pieces of sidewall panelings that described calcium silicate board with microporous makes, be prefabricated with the hole that aperture is greater than 100mm.

More preferred, described steel mesh and calcium silicate board with microporous combine the hollow building cover of pore-forming and steel mesh and foamed concrete self-heat conserving wall and form building energy conservation integral system.

A kind of steel mesh of the present invention and calcium silicate board with microporous combine the hollow building cover of pore-forming, and by post, beam, frange plate, the Cavity structural member of settling steel mesh and calcium silicate board with microporous to be combined to form in frange plate, cast-in-place concrete forms hollow building cover.At the bed die lining out of hollow building cover, determine the position of girder, girt strip, the shaping girder of colligation and girt strip, in the net post that post and girder are formed, making the girt strip that intersects in length and breadth and form grid, is lay the Cavity structural member that steel mesh and calcium silicate board with microporous combine after the hollow building cover in the stressed cross section of " work " font arranges bottom flange reinforcing bar within a grid, employing is the Cavity structural member that the hollow building cover in the stressed cross section of " T " font is directly laid steel mesh and calcium silicate board with microporous within a grid and combined, the steel mesh and the calcium silicate board with microporous that first prepare batch before hollow building cover construction are combined to form the base-material of Cavity structural member, the Cavity structural member that steel mesh and calcium silicate board with microporous are formed is the steel mesh made of special purpose machinery, steel mesh is containing reticular lamina and ribs and junction plate and limit reinforcing rib, and reticular lamina and ribs and junction plate and limit reinforcing rib form special steel mesh, need the bending trace of bending part bending when the vertical direction of every block steel mesh ribs is suppressed with composition with marking press, be convenient to when scene is combined with calcium silicate board with microporous along trace bending, calcium silicate board with microporous can use plastic plate, discarded plastic cement is utilized to be made into steel mesh Cavity structural member two pieces of sidewall panelings and gripper shoe between Cavity structural member top panel and bottom panel, plastic cement sidewall paneling is prefabricated with bar shaped hole, bar shaped hole is wider than sidewall thickness of slab, described gripper shoe two ends part is protruding, in the bar shaped hole that boss inserting side wallboard is prefabricated, is combined into " II font " projecting section, calcium silicate board with microporous is available gypsum plank also, utilize gypsum stoste to be made under the effect of mould, the discarded object after gypsum stoste utilizes large-sized boiler coal desulfurization utilizes again, when desulfurated plaster liquid agitation, be added with enhancement short fiber, also can substitute with composite plate or corrugated board, during Cavity structural member assembling based on steel mesh basal surface indentation line, first roll over two side sidewalls of Cavity structural member respectively, thereafter sidewall paneling and gripper shoe is laid, right-angle bending Cavity structural member top surface plate, general steel mesh head and the tail are at the superimposed overlap joint of top surface, the double-deck anti-working load of top surface both having enhanced Cavity structural member of superimposed overlap joint, serves again the effect being suspended in Cavity structural member top surface concrete mortar anti-leakage, prevents concrete mortar forward from leaking in Cavity structural member, calcium silicate board with microporous in steel mesh as two of shutoff steel mesh ports with between the upper plate being supported on Cavity structural member steel mesh and lower shoe, sidewall paneling is placed in the limit reinforcing rib groove of steel mesh two edges, gripper shoe length between Cavity structural member top panel and bottom panel one >=Cavity structural member in headroom length, support strip point elasticity when assembling than interior headroom length, also two side wall panels is supported after gripper shoe two ends bullet type is stressed, gripper shoe is stoped to be toppled over, also solve gripper shoe location when assembling, without the need to taking overturning-preventing measure to gripper shoe simultaneously, " work " font can be placed to according to stress calcium silicate board with microporous, " II " font, " king " font, with calcium silicate board with microporous as two port side wallboards of shutoff steel mesh and gripper shoe, overcome the construction of prior art gas tube cumbersome, when particularly solving Cavity structural member inner support and two ends shutoff organic object polyphenyl block, specific function building fire resistance rating is limited, polyphenyl block density and capacity need be strengthened and support to improve compression capability the working load that in steel mesh, sky bears, during transport, the thick loading space that occupies of polyphenyl block strengthens cost, polyphenyl block must make of the expandability plastic grain of standard, can not the defect such as regenerated resource development and utilization, everyly will hollow building cover be utilized need to seal in short tube by hole reserved for adjacent Cavity structural member book plate as when the transmission passage of hot blast and fire-fighting smoke controlling pipeline, gang up girder and girt strip, form dark air channel, recycling hollow building cover is that building energy conservation plays a role, and realizes the multi-functional utilization of hollow building cover, in the grid that girt strip is formed in length and breadth, after the Cavity structural member that steel mesh and calcium silicate board with microporous are formed is laid, re-lay and colligation top flange plate reinforcing bar, the Cavity structural member position correcting steel mesh and formed with calcium silicate board with microporous, fluid concrete, shock, maintenance, tear the cast-in-situ hollow building roof that superstructure template forms the Cavity structural member pore-forming that required steel mesh and calcium silicate board with microporous are combined to form open.

Accompanying drawing explanation

Fig. 1 is the Cavity structural member steel net structure figure that the steel mesh of first embodiment of the invention and calcium silicate board with microporous are formed.

Fig. 2 is that sectional view amounted to by the Cavity structural member steel mesh that the steel mesh of second embodiment of the invention and calcium silicate board with microporous are formed.

Fig. 3 sidewall paneling periphery that to be third embodiment of the invention be in calcium silicate board with microporous and steel mesh composition graphs.

Fig. 4 gripper shoe periphery that to be fourth embodiment of the invention be in calcium silicate board with microporous and steel mesh and sidewall paneling composition graphs.

Fig. 5 gripper shoe periphery that to be fifth embodiment of the invention be in calcium silicate board with microporous and steel mesh and sidewall paneling composition graphs.

Fig. 6 is that the Cavity structural member calcium silicate board with microporous that the steel mesh of sixth embodiment of the invention and calcium silicate board with microporous are formed installs top view.

Fig. 7 is the Cavity structural member constitutional diagram that the steel mesh of seventh embodiment of the invention and calcium silicate board with microporous are formed.

Fig. 8 is the hollow building cover sectional view of the Cavity structural member pore-forming that the steel mesh of eighth embodiment of the invention and calcium silicate board with microporous are formed

Fig. 9 is the building energy conservation integrated combination figure of ninth embodiment of the invention.

Detailed description of the invention

Below in conjunction with accompanying drawing, the present invention is further described.

Fig. 1 is the Cavity structural member steel net structure figure that the steel mesh of first embodiment of the invention and calcium silicate board with microporous are formed, as shown in Figure 1, the steel mesh of the Cavity structural member 1 that steel mesh and calcium silicate board with microporous are formed is containing reticular lamina 111 and ribs 112 and junction plate 113 and limit reinforcing rib 114, and reticular lamina and ribs and junction plate and limit reinforcing rib are that same thin steel plate special purpose machinery is die-cut, stretch-draw is made; The bending trace of quantitative bending part is needed when steel mesh ribs vertical direction being suppressed with combination; Cavity structural member basal surface 11 is made, Cavity structural member sidewall 12 and Cavity structural member top surface 13 length or height by bending trace determination steel mesh.

Fig. 2 is that sectional view amounted to by the Cavity structural member steel mesh that the steel mesh of second embodiment of the invention and calcium silicate board with microporous are formed, as shown in Figure 2, the tetrahedron of two sidewalls 12 of the hexahedral top surface 13 of Cavity structural member, Cavity structural member basal surface 11 and Cavity structural member that formed of steel mesh and calcium silicate board with microporous; Steel mesh head and the tail overlapping part is when Cavity structural member top surface, and the length of amount of lap≤Cavity structural member top surface, overlaps sub-surface reinforcement by Cavity structural member top surface steel mesh head end length 13, Cavity structural member top surface tail end length 13.

Fig. 3 sidewall paneling periphery that to be third embodiment of the invention be in calcium silicate board with microporous and steel mesh composition graphs, sidewall paneling 14 periphery in calcium silicate board with microporous combines in steel mesh Edge Enhancement muscle groove 115, well secure the displacement of sidewall paneling 14, sidewall paneling 14 support again simultaneously steel mesh Cavity structural member surrounding stressed time distortion; When fluid concrete, be unlikely to the impact of sidewall paneling by concrete lateral pressure, cause sidewall paneling toward steel mesh intrinsic displacement.

Fig. 4 gripper shoe periphery that to be fourth embodiment of the invention be in calcium silicate board with microporous and steel mesh and sidewall paneling composition graphs a, gripper shoe in calcium silicate board with microporous 17 two limits respectively with empty top surface 13 in Cavity structural member 1, engage inside basal surface 11, gripper shoe 17 two ends engages with sidewall paneling 14, topple over to prevent gripper shoe 17, in gripper shoe two ends pre-erection projection 16, prefabricated bar shaped hole 15 in sidewall paneling 12, bar shaped aperture width is greater than thickness of slab, facilitate in the prefabricated protruding 16 partial insertion bar shaped holes of gripper shoe two ends, calcium silicate board with microporous was both played a supporting role, it is again the effect playing shutoff Cavity structural member.

Fig. 5 gripper shoe periphery that to be fifth embodiment of the invention be in calcium silicate board with microporous and steel mesh and sidewall paneling composition graphs b, gripper shoe 17 length in calcium silicate board with microporous is greater than the interior empty length of Cavity structural member, gripper shoe 17 two limits respectively with empty top surface 13 in Cavity structural member 1, engage inside basal surface 11, gripper shoe 17 two ends engages with sidewall paneling 14, topple over to prevent gripper shoe 14, artificially appropriate gripper shoe 17 length is greater than in Cavity structural member 1 empty, field combinations makes gripper shoe 17 produce elasticity and stressed when installing, two termination support sidewall panelings 14, do not take other measures, gripper shoe 17 also can not be toppled over, can also at the junction brush bonded adhesives cementation of gripper shoe 17 two ends and sidewall paneling 14.

Fig. 6 is that the Cavity structural member calcium silicate board with microporous that the steel mesh of sixth embodiment of the invention and calcium silicate board with microporous are formed installs top view, during the Cavity structural member that steel mesh and calcium silicate board with microporous are formed, general employing two pieces of sidewall panelings 14 are as two pieces of sidewall panelings 14 of Cavity structural member 1, and sidewall paneling 14 periphery is placed in the groove 115 of steel mesh limit reinforcing rib 114; When the width of Cavity structural member is greater than 500mm, best employing two pieces of gripper shoes 17, form II font structure, when being beneficial to again hollow building cover as silent air channel, and reserved ventilation stack connecting hole in the middle of the sidewall paneling 14 of II character form structure.

Fig. 7 is the Cavity structural member constitutional diagram that the steel mesh of seventh embodiment of the invention and calcium silicate board with microporous are formed, the tetrahedron becoming two sidewalls 12 of Cavity structural member top surface 13, Cavity structural member basal surface 11 and Cavity structural member of the Cavity structural member that steel mesh is formed with calcium silicate board with microporous, gripper shoe 17 and sidewall paneling 14, gripper shoe 17 is supported between Cavity structural member top surface 13 and Cavity structural member basal surface 11; Sidewall paneling 14 periphery in calcium silicate board with microporous combines in steel mesh limit reinforcing rib 114 groove 115, secure very well the displacement of sidewall paneling, sidewall paneling 14 support again simultaneously steel mesh Cavity structural member 1 surrounding stressed time distortion; Steel mesh head and the tail overlapping part is when Cavity structural member top surface 13, and amount of lap is less than the surface area of Cavity structural member top surface, after gripper shoe and sidewall paneling 14 being in place, by steel mesh ribs and the superimposed position welding or fixing of limit reinforcing rib head and the tail; If when need use hollow building cover as dark air delivery duct function, in the middle of sidewall paneling 14, before assembling, first bore the hole lingering on adapter.

Fig. 8 is the hollow building cover sectional view of the Cavity structural member pore-forming that the steel mesh of eighth embodiment of the invention and thin plate are formed, steel mesh and thin plate combine the hollow building cover of pore-forming, by post 30, girder 21, girt strip 22, top flange plate 23, bottom wing listrium 24, reinforcing bar 25, the Cavity structural member 1 that steel mesh and thin plate are formed forms; Every using when utilizing hollow building cover as the transmission passage of hot blast and fire-fighting smoke controlling pipeline, short tube 26 need be sealed in by hole reserved for adjacent Cavity structural member book plate, gang up girder and girt strip, form dark air channel, recycling hollow building cover is that building energy conservation plays a role, and realizes the multi-functional utilization of hollow building cover; Cast-in-place concrete 28 in post, beam, frange plate.

Fig. 9 is the building energy conservation integrated combination figure of ninth embodiment of the invention, the Self-insulation wall plate 32 that the hollow building cover 31 of the Cavity structural member pore-forming that building energy conservation integration is formed by steel mesh and the thin plate of horizontal direction and vertical direction are combined to form by steel mesh and foamed concrete, two boards is at level and vertical engagement mate, stop cold bridge 33, realize self-heat conserving yarn system, highlight insulation, heat insulation, the comprehensive function of sound insulation, the wallboard 32 that the hollow building cover 31 reaching the Cavity structural member pore-forming that steel mesh and thin plate are formed and steel mesh and foamed concrete are combined to form combines, realize building energy conservation integration.

Finally should be noted that: above embodiment is only in order to illustrate that technical scheme of the present invention is not intended to limit, although with reference to above-described embodiment to invention has been detailed description, those of ordinary skill in the field are to be understood that, still can modify to the specific embodiment of the present invention or equivalent replacement, and end departs from any amendment of spirit and scope of the invention or equivalent replacement, it all should be encompassed in the middle of right of the present invention.

Claims (6)

1. combine a hollow building cover for pore-forming with steel mesh and calcium silicate board with microporous, the Cavity structural member formed by post, beam, frange plate, steel mesh and calcium silicate board with microporous forms; Described beam is reinforced concrete beam or transfer structure for SRC beams; Described frange plate is i shaped cross section plate or T font cross sectional plates; The Cavity structural member that described steel mesh and calcium silicate board with microporous are formed is interacted by steel mesh and calcium silicate board with microporous and forms; Described steel mesh forms the tetrahedron of the top panel of hexahedron Cavity structural member, bottom panel and two sidewalls; The head and the tail two ends of described steel mesh simultaneously overlap arbitrarily at tetrahedron; Described calcium silicate board with microporous forms the another two pieces of sidewall panelings of steel mesh Cavity structural member and gripper shoe between Cavity structural member top panel and bottom panel; Described calcium silicate board with microporous is placed in the limit reinforcing rib groove of steel mesh two edges; Cast-in-place concrete in described post, beam, frange plate.

2. a kind of steel mesh as claimed in claim 1 and calcium silicate board with microporous combine the hollow building cover of pore-forming, it is characterized in that there is the cap being greater than 500mm solid section the surrounding outer of described post; Described cap is identical with the thickness of hollow building cover.

3. a kind of steel mesh as claimed in claim 1 and calcium silicate board with microporous combine the hollow building cover of pore-forming, it is characterized in that described steel mesh is containing reticular lamina and ribs and junction plate and limit reinforcing rib, described reticular lamina and ribs and junction plate and limit reinforcing rib make shaping by same thin steel plate the die-cut of special purpose machinery and expansion; The regular change of its grid direction of the reticular lamina of described steel mesh; The vertical direction of described steel mesh ribs is suppressed with bending trace; The crowning of described steel mesh ribs at the external surface of Cavity structural member, the width <1000mm of described steel mesh.

4. a kind of steel mesh as claimed in claim 1 and calcium silicate board with microporous combine the hollow building cover of pore-forming, it is characterized in that the inorganic matter silicon raw material and the calcareous raw material that are added with discarded object in described calcium silicate board with microporous; Described calcium silicate board with microporous forms steel mesh Cavity structural member two pieces of sidewall panelings and gripper shoe between Cavity structural member top panel and bottom panel; Empty in described gripper shoe length >=Cavity structural member, direct support sidewall paneling.

5. a kind of steel mesh as claimed in claim 1 and calcium silicate board with microporous combine the hollow building cover of pore-forming, it is characterized in that, in steel mesh Cavity structural member two pieces of sidewall panelings that described calcium silicate board with microporous makes, being prefabricated with the hole that aperture is greater than 100mm.

6. a kind of steel mesh as claimed in claim 1 and calcium silicate board with microporous combine the hollow building cover of pore-forming, it is characterized in that described steel mesh and calcium silicate board with microporous combine the hollow building cover of pore-forming and steel mesh and foamed concrete self-heat conserving wall and form building energy conservation integral system.