CN203373889U - Mesh box-shaped component for cast-in-place hollow floor hole-forming - Google Patents

Abstract

The utility model provides a mesh box-shaped component for cast-in-place hollow floor hole-forming. The mesh box-shaped component is composed of a box top, a box body (a side wall) and a box bottom, and the box top is provided with cement mortar or a polyfoam board or a plate in a compositing mode. The box body and the box bottom are made of mesh-shaped bodies, each mesh-shaped body comprises a mesh-shaped plate, a reinforcing rib and a connecting net, the mesh-shaped plates, the reinforcing ribs and connecting nets form integral structures which act on one another, and the area of a grid in the mesh-shaped plate is smaller than 120mm<2>. The reinforcing rib is in a V shape, the height of the reinforcing ribs is larger than 3mm, and the distance of the reinforcing ribs in the mesh-shaped body is larger than 30mm. The mesh box-shaped component is composed of at least two mesh-shaped bodies. At least two construction oblique faces are arranged on the corner portion of the box bottom and the box body of the mesh box-shaped component. The unsealed mesh box-shaped component is used for replacing an existing cast-in-place floor, a full-sealing hollow filling body and a solid filling body hole-forming technology are used, and the defect in an existing hollow floor is effectively overcome.

Description

The netted box component of a kind of cast-in-situ hollow building roof pore-forming

Technical field

The utility model relates to the non-heart component for hole of taking out of a kind of cast-in-situ hollow building roof, is specifically related to a kind of for the netted box component of cast-in-situ hollow building roof pore-forming.

Background technology

At present in the cast-in-situ reinforced concrete hollow floor technical field, usually adopt hermetic obturator member moulding by casting hollow building cover, the ZL98231113.3 structural member for concrete thin-wall cylinder of declaring as the inventor, be made into the tubular obturator of sealing, for realizing that cast-in-situ hollow building roof provides the tubular, hollow obturator, solved the non-technique difficult problem of taking out heart pore-forming of cast-in-situ hollow building roof.But due to sealed tubular hollow filling body, exist, fixedly difficulty is large, buoyancy is large, the large matter weight of density, production, transportation and site operation are all inconvenient, can not form the large-scale industrial production line.

The ZL200410082381.9 " a kind of hollow floor slab with small dense ribs " declared as the inventor, the hollow filling body is embedded in floor slab with small dense ribs and forms " T font " stressed cross section voided layer, has solved the smooth problem of the little hollow-ribbed floor top board in " T font " stressed cross section.But do not design steel bar stress between obturator bottom and hollow building cover template, to apply separately one deck cracking resistance gauze wire cloth, again owing to adopting pure inorganic hollow obturator to realize little hollow-ribbed floor, sealing hollow filling body buoyancy is large, the hollow filling body setting and hardening time is long, the mould utilization rate is low, the large matter weight of hollow filling bulk density, the defects such as production and transport inconvenience and the poor cracky of obturator globality.

Meanwhile, the applicant has invented again a kind of mode (ZL201110258028.1) of utilizing mechanical mold system to make Cavity structural member, has realized that the mechanized production hollow building cover becomes pole; Solved the problem of obturator quality, production, transportation and the breakage of obturator globality; The applicant has also invented a kind of hollow floor system (ZL201110332999.6) that adopts reinforced foam combination obturator to make, and this technology solved displacement that current cast-in-situ hollow building roof prior art exists, isolation, cushion block, by elongated reinforcing bar fixedly obturator, cracky, matter method of double differences shortcoming; Also have that manufacturing speed is fast, production efficiency is high, cost is low simultaneously, easy construction, can stop reinforcing bar and be absorbed in the hidden dangers in project that brings in the plastic foam noggin piece.But, because the plastic foam noggin piece is organic material, large, the overall buoyancy increase of the binding site control accuracy that organic material and inorganic material have occurred again and the hollow building cover formed are in fact solid, because superstructure is not hollow, impact is as the defect that dark anti-smoke discharging pipe is multi-functional and the building energy conservation integrated synthesis utilizes that stores solar thermal energy and heat air delivery and can or form ventilating duct and fire-fighting.

Therefore; develop a kind of comprehensive function characteristics with prior art; take full advantage of concrete surface tension force; substitute the hole creating technology of existing hermetically sealed hollow filling body or polystyrene foam hatching solid body with packing less netted box component, overcome the defect that existing hollow building cover non-core-drawing pore-creating exists with obturator; Reach that manufacturing speed is fast, production efficiency is high, with the concrete plyability, well do not produce that superimposed layer, cost are low, transportation and easy construction, do not produce buoyancy, light weight, without damaged, unshift, exempt the functional netted box component of isolating cushion block and elongated fixedly reinforcing bar, meeting the multi-functional and integrated utilization of building energy conservation of floor framing.Realize the breakthrough of cast-in-situ hollow building roof new technology, become the urgent need of hollow building cover technical field innovation.

Summary of the invention

The purpose of this utility model is to provide that manufacturing speed is fast, production efficiency is high, good with the concrete plyability, exempt isolation and fix, improve quality, fall bottom application work supplementary costs, the transportation easy construction, do not produce buoyancy, meet design and guarantee workmanship, be of value to the netted box component of realizing the integrated and multi-functional utilization of superstructure of building energy conservation.Adopt netted box component to realize the cast-in-situ hollow building roof hole creating technology, utilize packing less netted box component to substitute existing hermetically sealed hollow filling body or polystyrene foam hatching solid body, optimize existing cast-in-situ hollow building roof hole creating technology, overcome the defect that existing hollow building cover hole creating technology exists.

The technical solution of the utility model is as follows, the netted box component of a kind of cast-in-situ hollow building roof pore-forming, described netted box component by case top, case body (sidewall), case at the bottom of combination, described case top is compounded with cement mortar or foamed glue or sheet material.At the bottom of described case body and case, of reticulate body, make, described reticulate body comprises reticular lamina and reinforcing rib and connection network, and described reticular lamina and reinforcing rib and connection network form the interaction overall structure, and in described reticular lamina, the grid area is less than 120mm2.The V-shaped shape of described reinforcing rib, the reinforcing rib height is greater than 3mm, and the spacing of reinforcing rib in reticulate body is greater than 30mm.Two reticulate body combinations of the minimum use of described netted box component.Have two structure inclined-planes at least with the rotation angle position of case body at the bottom of the case of described netted box component.

More preferred, when described case pushes up independent composite cement mortar, the case top edge has liner muscle and limit for height to control limit.

More preferred, be compounded with cement mortar or foamed glue or sheet material on the grid on described case top, grid or the sheet material barrier case top grid on the incomplete closely knit case of the closely knit case of described cement mortar top grid or foamed glue expansion top.

More preferred, be compounded with micro-foamed glue on the side mesh body of described case body, the grid of the incomplete closely knit case body side mesh body of described foamed glue expansion.

More preferred, in described two reticulate bodies, at the bottom of a case that forms netted box component is arranged and two sides of case body.At the bottom of described case, with case body rotation angle position, adopt the structure inclined-plane to form.The triangle height H that Yu Xiangdi supplementary angle, described structure inclined-plane forms ₁≤ 100mm, structure chamfer length L ₅≤ 150mm.

More preferred, case top and the middle part at the bottom of case of described netted box component are provided with support member, and described support member is hollow body or support bar.Described V-arrangement reinforcing rib height position in the outside of netted box component or V-arrangement reinforcing rib height position in the inboard of netted box component.

More preferred, have the air-supply through hole that two diameters are greater than 100mm on described case body reticulate body.

More preferred, compound with the concrete of infiltration at the bottom of the case of described reticulate body, directly form the thin base plate in bottom flange of cast-in-situ hollow building roof, in the thin base plate in described cast-in-situ hollow building roof bottom flange containing the reticulate body at the bottom of netted box component case, the thin base plate thickness≤20mm in described cast-in-situ hollow building roof bottom flange.

More preferred, compound with bottom flange steel concrete at the bottom of the case of described reticulate body, directly form the bottom wing listrium of cast-in-situ hollow building roof.

More preferred, described netted box component and formed steel construction and reinforced concrete structure are combined to form formed steel construction and guiding principle reinforced concrete combination cast-in-situ hollow building roof.Girder adopts shaped steel, and girt strip or secondary beam adopt reinforced concrete structure; Lay netted box component between described girder and girt strip and between girt strip and girt strip, after fluid concrete, superstructure forms " T font " or " I-shaped " stressed cross section.

The netted box component of a kind of cast-in-situ hollow building roof pore-forming of the present utility model, the reticulate body A2 that utilizes special mechanical equipment and Mold Making to comprise reticular lamina A21 and reinforcing rib A22 and connection network A23, reinforcing rib in reticulate body is made along the length direction, with the mould positioning blade, die-cut or rotary cutting steel sheet both sides stretching otch form the reticulate body of typing width, and reticulate body is cut into to Len req.Scheme is, cuts out three reticulate body A2, length L 5 and two side height L4 sums of case body, that is: L=2L5 ten L3 ten 2L4 of two structure inclined-plane A5 of rotation angle position between A3 and case body A4 at the bottom of the width L3 that wherein length L of is A3 at the bottom of case and case; The U-shaped polyhedrons of A3, two structure inclined-plane A5 and two case body A4 at the bottom of reticulate body A2 making formation case.Another two reticulate body A2 are made into to the specification piece of two case body A4, specification piece by two case body A4, adopt the modes such as welding, colligation to be placed in respectively the polyhedral two ends of U-shaped, formation only has the netted member of square polyhedron of an opening, the netted member opening of the square polyhedron physical dimension of opening is greater than the physical dimension of A3 at the bottom of case, is convenient to superimposed transportation.The case top A1 that will make with composite material again covers on the opening of the netted member of square polyhedron, forms netted box component.When netted box component case top minor face is grown up in 600mm, case top and middle part at the bottom of case are put into to be communicated with and support hollow body, in case top and the midpoint perforate that is communicated with the hollow body binding site, bore dia is hollow body 2/3.The case top A1 that composite material is made generally makes in batch of special-purpose machinery, can also on reticulate body, apply compound adhesive, after the compound adhesive foaming, not exclusively seal the grid of all casees top reticulate body, sealing network degree is that concrete surface tension force is greater than the seepage power of concrete in the grid of case top, can be also composite board at reticulate body.

The accompanying drawing explanation

The netted box component A structure chart that Fig. 1 is the utility model the first embodiment;

The netted box component A structure chart that Fig. 2 is the utility model the second embodiment;

The netted box component A structure chart that Fig. 3 is the utility model the 3rd embodiment;

One of exploded view that Fig. 3-1 is the netted box component A of Fig. 3;

Two of the exploded view that Fig. 3-2 are the netted box component A of Fig. 3;

Three of the exploded view that Fig. 3-3 are the netted box component A of Fig. 3;

The netted box component A structure chart that Fig. 4 is the utility model the 4th embodiment;

The case roof construction sectional drawing that the composite material that Fig. 5 is the utility model the 5th embodiment is made;

The case roof construction plan view that make for the composite material of the utility model the 5th embodiment Fig. 5-1;

The netted box component mesh structure plan view that Fig. 6 is the utility model the 6th embodiment;

The stressed sectional view of hollow building cover " I-shaped " that Fig. 7-1 is the netted box component A of the utility model pore-forming;

The stressed sectional view of the hollow building cover that Fig. 7-2 are the netted box component A of the utility model pore-forming " T font ";

The steel work that Fig. 7-3 are the netted box component A of the utility model pore-forming and Combined concrete hollow floor structure sectional view;

One of " multi-functional " hollow floor structure sectional view that Fig. 8-1 is the netted box component A of the utility model pore-forming;

Two of " multi-functional " hollow floor structure sectional view that Fig. 8-2 are the netted box component A of the utility model pore-forming;

Three of " multi-functional " hollow floor structure sectional view that Fig. 8-3 are the netted box component A of the utility model pore-forming.

The specific embodiment

Below in conjunction with accompanying drawing the utility model, be further described.

The netted box component of a kind of cast-in-situ hollow building roof pore-forming of the present utility model, as shown in Fig. 1, Fig. 6, the reticulate body A2 that utilizes special mechanical equipment and Mold Making to comprise reticular lamina A21 and reinforcing rib A22 and connection network A23, reinforcing rib in reticulate body is made along the length direction, with the mould positioning blade, die-cut or rotary cutting steel sheet both sides stretching otch form the reticulate body of typing width, and reticulate body is cut into to Len req.Scheme is, cuts out three reticulate body A2, length L 5 and two side height L4 sums of case body, that is: L=2L5 ten L3 ten 2L4 of two structure inclined-plane A5 of rotation angle position between A3 and case body A4 at the bottom of the width L3 that wherein length L of is A3 at the bottom of case and case; The U-shaped polyhedrons of A3, two structure inclined-plane A5 and two case body A4 at the bottom of reticulate body A2 making formation case.Another two reticulate body A2 are made into to the specification piece of two case body A4, specification piece by two case body A4, adopt the modes such as welding, colligation to be placed in respectively the polyhedral two ends of U-shaped, formation only has the netted member of square polyhedron of an opening, the netted member opening of the square polyhedron physical dimension of opening is greater than the physical dimension of A3 at the bottom of case, is convenient to superimposed suit transportation.The case top A1 that will make with composite material again covers on the opening of the netted member of square polyhedron, forms netted box component.Fig. 2-1 is netted box component exploded view

The netted box component A structure chart that Fig. 2 is the utility model the second embodiment, as shown in Figure 2, netted box component forms with reticulate body A2 entirely.The side that netted box component A comprises A3 and case body A4 at the bottom of case top A1, case.Cut out three reticulate body A2 and form netted box component; the width L1 that wherein the length L C of is case top A1; length L 5 and two the side length L4 sums of case body A4 of two structure inclined-plane A5 at the bottom of case at the bottom of the width L3 of A3 and case and between the case body, that is: LC=L1+2L5 ten L3 ten 2L4; Length is that LC reticulate body A2 make to form A3 at the bottom of case top A1, case, the length L 5 of two structure inclined-plane A5 and the square polyhedron of two case body A4 side height L4.Another two reticulate body A2 are made into to another two case body A4, two case body A4 are adopted the modes such as welding, colligation be placed in respectively square polyhedral two ends, form the netted box component of square polyhedron.Concrete is in the little seepage power that causes of case top plane strain, in order to prevent the seepage of concrete on plane, case top, at upper surface or the composite foamed glue of soffit of case top A1.

The netted box component A structure chart that Fig. 3 is the utility model the 3rd embodiment; as shown in Figure 3; netted box component A is made by two reticulate body A2 combinations, Fig. 3-1 width L1 and case body A4 two side height L2 sums, that is: LB=L1 ten 2L2 that wherein the length L B of is case top A1; Length L B reticulate body A2 is made to the U-shaped polyhedron that forms case top A1 and two case body A4 sides.Length L 5 and two side height L4 sums of case body A4, that is: LA=2L5 ten L3 ten 2L4 of two structure inclined-plane A5 at the bottom of the width L3 that the length L A of another piece of Fig. 3-2 is A3 at the bottom of case and case; U-shaped polyhedrons by A3, two structure inclined-plane A5 and two case body A4 sides at the bottom of length L A reticulate body A2 making formation case.Two reverse combined crosswise of U-shaped polyhedron that Fig. 3-3 make LA and LB by two reticulate body A2 reticulate A3 and structure inclined-plane A5 at the bottom of the case top A1 of box component and case body A4 and case.Concrete is in the little seepage that causes of case top plane strain, in order to prevent the seepage of concrete on plane, case top, be compounded with foamed glue or cement mortar on the A1 of case top, described foamed glue the expand grid of closely knit case top reticulate body or the grid of the closely knit case of cement mortar top reticulate body.Consider to meet design bottom flange thickness requirement, on the height L4 basis, two sides of case body A4 on LB, add again bottom flange thickness H2, allow two side end points of case body A4 be placed directly on the template of hollow building cover.The distance of bottom flange thickness H2 at the bottom of fixed case and between the hollow building cover template, replace cushion block.Fig. 3-1, Fig. 3-2, the exploded view that Fig. 3-3 are the netted box component A of Fig. 3.

The netted box component A structure chart that Fig. 4 is the utility model the 4th embodiment, netted box component A shown in Fig. 1, Fig. 2, Fig. 3, when the minor face width of case top A1 is greater than 600mm, must push up at the bottom of A1 and case support bar 5 is installed between A3 at case, support bar is generally hollow section, by case top and the midpoint perforate C that is communicated with support hollow section binding site at the bottom of case, bore dia is 2/3 of hollow section diameter.When the side mesh volume mesh of case body is bigger than normal, on case body A4, be compounded with micro-foamed glue, the grid of incomplete closely knit case body side mesh body after described foamed glue expands.Other partial contents are directly understood with reference to the detailed description of Fig. 1, Fig. 2, Fig. 3, here just repeat no more.

The case roof construction sectional drawing that the composite material that Fig. 5 is the utility model the 5th embodiment is made, Fig. 5-1 is plan view.The case top A1 that composite material is made adopts concrete mortar and reinforced materials to make under the effect of mould; Being provided with the protruding 9a of hole C, discontinuous isolating bar 9 or arc piece, structure A5, edge, inclined-plane for cast in the A1 of case top has liner muscle 6 and limit for height to control limit 7; Cast has the enhancing rib 10 with void shape with inboard, hole C edge, and enhancing rib outer rim is equipped with case top A1 and is communicated with hollow section support member 5 with A3 middle part at the bottom of case.Structure inclined-plane A5 and supplementary angle, A1 plane, case top form leg-of-mutton height H 1≤100mm, length L 5≤150mm.。

The netted box component mesh structure plan view that Fig. 6 is the utility model the 6th embodiment.As shown in Figure 6, netted box component reticulate body A2, reticulate body A2 comprises reticular lamina A21 and reinforcing rib A22 and connection network A23, reticular lamina A21 and reinforcing rib A22 and connection network A23 form an integral body, in reticular lamina A2, the grid area is less than 120mm2, reinforcing rib is generally " v shape ", and reticulate body A2 connection network A23 thickness is 0.5mm.When reticulate body A2 is used for case body A4, reinforcing rib A22 should erect.

The stressed sectional view of hollow building cover " I-shaped " that Fig. 7-1 is the netted box component A of the utility model pore-forming.

The stressed sectional view of hollow building cover " I-shaped " that Fig. 7-1 is the netted box component A of the utility model pore-forming, when netted box component is applied to cast-in-situ hollow building roof, lay baseplate reinforcing bar 13 on hollow building cover template 12, the good rib reinforcement 14 of colligation, form by the building structure required space, lay the netted box component by building structure requirement specification in space, then lay top board reinforcing bar 15, check after set aside pre-embedded cast-in-place concrete again.During cast-in-situ concrete, because the reticulated cell area of reticulate body A2 surpasses the infiltrating area due to concrete surface tension force, so concrete can not penetrate in the netted box component body of combination from the reticulated cell of reticulate body A2, fluid concrete and base plate muscle 13 form the bottom flange 26 of hollow building cover, girt strip 23 with rib reinforcement 14 formation hollow building covers, the concrete pushed up for 24. casees on A1 with the top flange of top board reinforcing bar 15 formation hollow building covers passes through cast hole C, through A3 bottom at the bottom of hollow connected component support member 5 inflow casees, the support column of bottom flange in formation, strengthen the superstructure punching resistance.

Fig. 7-2 are the stressed cross section of the netted box component A of the utility model " T " font hollow floor structure sectional view.It is compared with the sectional view shown in Fig. 6, difference only is on template 12 not lay baseplate reinforcing bar 13, but the spacing distance H2 of A3 at the bottom of the case of netted box component and hollow building cover soffit formwork 12 is less than to 20mm, namely by the basis of the reinforcing rib A22 length L 4 of length L B reticulate body A2, adding H2, highly be supported on the hollow building cover soffit formwork, control the thickness of bottom flange 26 with the H2 lengthened.At the bottom of case body A4 and case, the A3 rotation angle position forms structure inclined-plane A5, is conducive to concrete mobile formation.After completing other steps, cast-in-place concrete, at the bottom of cast-in-place pouring concrete and case, the A3 reticulate body is compounded to form the bottom flange 26 of hollow building cover.The thickness of bottom flange 26 thin base plates is exactly the height of H2; Support bar hollow section also corresponding prolongation H2 is high, and hollow section extends part and forms zigzag 35, and the sawtooth string is crossed A3 reticulate body grid at the bottom of case, stands on the superstructure template.The netted case body 3 of netted box component simultaneously is exuded to A3 at the bottom of case by concrete unnecessary mixing water in girt strip and top flange plate from grid 19, has improved the concrete label of girt strip and top flange plate and intensity.Unnecessary mixing water oozes out emerging of the rear bubble produced while having reduced top flange concrete initial set aquation reflection, has improved top flange plate compactness and intensity.Unnecessary mixing water with mortar oozes to bottom flange, and complex superposition at the bottom of mortar and netted case, further improved bottom flange rigidity.Other partial contents are directly understood with reference to the detailed description of Fig. 7-1, here also just repeat no more.

The steel work that Fig. 7-3 are the netted box component A of the utility model pore-forming and Combined concrete hollow floor structure sectional view.Netted box component and formed steel construction and reinforced concrete structure are combined to form formed steel construction and guiding principle reinforced concrete combination cast-in-situ hollow building roof.Girder adopts shaped steel, and girt strip adopts reinforced concrete structure; Lay netted box component between girder and girt strip and between girt strip and girt strip, after fluid concrete, superstructure forms the stressed cross section of " T " font.At processing steel main beam pair, be reserved with the through hole passed through for girt strip lower rebar 20 on girder web plate 30, girt strip 23 upper reinforcements are by 31 tops, shaped steel top flange and form intersection, girt strip 23 lower rebar 20 were gone here and there steel main beam web 30, colligation 22 forms the girt strip reinforcing bar, girt strip intersects in length and breadth and forms the grid of laying netted box component with girt strip, and the top flange 31 of steel main beam, web 30 and girder bottom flange 32 inwalls are wrapped up by concrete, have solved the fire prevention of steel main beam, antirust problem.The particular manufacturing craft 34 of parcel steel main beam lower end, adopt two blocks of L-type steel plates to form, and the stack joint of two L-type punching blocks is taked respectively movable snapping.A die body of steel-mixed combined hollow building cover structure is by forming with template 12 and particular manufacturing craft 34 on pole and movable Contraband steel, and top, pole upper end Contraband steel, put the superstructure template, particular manufacturing craft 34 for the girder both sides on the Contraband steel.Other partial contents are directly understood with reference to the detailed description of Fig. 7-1 and Fig. 7-2, here also just repeat no more.

" multi-functional " hollow floor structure sectional view that Fig. 8-1, Fig. 8-2 and Fig. 8-3 are the netted box component A of the utility model pore-forming.It is compared with the sectional view shown in Fig. 7-3 with Fig. 7-2 with Fig. 7-1, and difference is that the natural axis place of cast-in-situ hollow building roof girder and girt strip 23 is provided with the short tube that is communicated with netted box component, short tube G diameter D >=100mm.Short tube G can extend into reticulate body A2 the inside.The size of the quantity of default short tube G and straight warp is pressed the required air output setting of integrated multi-functional superstructure; Another difference is by additionally arranging the cable type heating element 11 that complementary energy is used in pre-buried short tube G.Another difference is that the cable type heating element 11 that complementary energy is used is placed on the structure inclined-plane A5 of the functional precast plate A1 of netted box component A again; Convert solar energy into hot blast and can be transported in netted box component A, by the netted box component A of the required utilization of pre-buried short tube G feed-through, reach the purpose of hot blast energy circulation; Realize energy-saving heating.When dusk heat energy is repeatedly put, when temperature drops to rated value, automatically connect preset cable type heating element 11 complementary energy.Other partial contents are directly understood with reference to the detailed description of Fig. 7-1 and Fig. 7-2 Fig. 7-3, here also just repeat no more.

When the utility model is implemented, according to architectural design require specification, functional performance high accuracy to make multiple unit tube top A1 and reticulate body A2 is crucial, multiple unit tube top A1 and reticulate body A2 will make of special mechanical equipment, again itself and hollow strutting piece are combined into to the netted box component of different size and model, can be completed a kind made from netted box component for the cast-in-situ hollow building roof pore-forming of the utility model.

Finally should be noted that: above embodiment is only in order to illustrate that the technical solution of the utility model is not intended to limit, although with reference to above-described embodiment, the utility model is had been described in detail, those of ordinary skill in the field are to be understood that, still can modify or be equal to replacement the specific embodiment of the present utility model, and end breaks away from any modification of the utility model spirit and scope or is equal to replacement, it all should be encompassed in the middle of claim scope of the present utility model.

Claims (10)

1. the netted box component of cast-in-situ hollow building roof pore-forming is characterized in that: described netted box component by case top, case body and case at the bottom of combination, described case top is compounded with cement mortar or foamed glue or sheet material;

At the bottom of described case body and case, of reticulate body, make, described reticulate body comprises reticular lamina, reinforcing rib and connection network, and described reticular lamina, reinforcing rib and connection network form the interaction overall structure, and in described reticular lamina, the grid area is less than 120mm ²;

The V-shaped shape of described reinforcing rib, the reinforcing rib height is greater than 3mm, and the spacing of reinforcing rib in reticulate body is greater than 30mm;

Two reticulate body combinations of the minimum use of described netted box component;

Have two structure inclined-planes at least with the rotation angle position of case body at the bottom of the case of described netted box component.

2. the netted box component of a kind of cast-in-situ hollow building roof pore-forming as claimed in claim 1, while it is characterized in that described case pushes up independent composite cement mortar, the case top edge has liner muscle and limit for height to control limit.

3. the netted box component of a kind of cast-in-situ hollow building roof pore-forming as claimed in claim 1, it is characterized in that being compounded with cement mortar or foamed glue or sheet material on the grid on described case top the closely knit case of described cement mortar top grid or foamed glue expand grid or the sheet material barrier case top grid on incomplete closely knit case top.

4. the netted box component of a kind of cast-in-situ hollow building roof pore-forming as claimed in claim 1, is characterized in that being compounded with foamed glue on the side mesh body of described case body, the expand grid of incomplete closely knit case body side mesh body of described foamed glue.

5. the netted box component of a kind of cast-in-situ hollow building roof pore-forming as claimed in claim 1, is characterized in that in described reticulate body, at the bottom of a case that forms netted box component is arranged and two sides of case body; At the bottom of described case, with case body rotation angle position, adopt the structure inclined-plane to form; The triangle height H that Yu Xiangdi supplementary angle, described structure inclined-plane forms ₁≤ 100mm, structure chamfer length L ₅≤ 150mm.

6. the netted box component of a kind of cast-in-situ hollow building roof pore-forming as claimed in claim 1, is characterized in that the case top of described netted box component is provided with support member with middle part at the bottom of case, and described support member is hollow body or support bar; Described V-arrangement reinforcing rib height position in the outside of netted box component or V-arrangement reinforcing rib height position in the inboard of netted box component.

7. the netted box component of a kind of cast-in-situ hollow building roof pore-forming as claimed in claim 1, is characterized in that described case has the air-supply through hole that two diameters are greater than 100mm with it.

8. the netted box component of a kind of cast-in-situ hollow building roof pore-forming as claimed in claim 1, it is characterized in that at the bottom of the case of described reticulate body compound with the concrete of infiltration, directly form the thin base plate in bottom flange of cast-in-situ hollow building roof, in the thin base plate in described cast-in-situ hollow building roof bottom flange containing the reticulate body at the bottom of netted box component case, the thin base plate thickness≤20mm in described cast-in-situ hollow building roof bottom flange.

9. the netted box component of a kind of cast-in-situ hollow building roof pore-forming as claimed in claim 1, is characterized in that at the bottom of the case of described reticulate body compoundly with bottom flange steel concrete, directly forms the bottom wing listrium of cast-in-situ hollow building roof.

10. the netted box component of a kind of cast-in-situ hollow building roof pore-forming as claimed in claim 1; it is characterized in that described netted box component and formed steel construction and reinforced concrete structure are combined to form formed steel construction and guiding principle reinforced concrete combination cast-in-situ hollow building roof, girder adopts shaped steel, girt strip or secondary beam to adopt reinforced concrete structure; Lay netted box component between described girder and girt strip and between girt strip and girt strip, after fluid concrete, superstructure forms " T font " or " I-shaped " stressed cross section.

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