CN214996414U - Energy-saving assembly type steel structure factory building - Google Patents

Abstract

The utility model relates to an energy-conserving assembled steel construction factory building relates to the technical field of steel construction building, and it includes support body and first panel layer, first panel layer includes roof boarding under daylighting board and the polylith, the roof boarding is fixed in the support body down, the daylighting board is located between two adjacent roof boarding down, the border slope orientation of roof boarding is turned over towards one side that deviates from the support body down and is rolled over and form connecting portion down to the daylighting board, the border of roof boarding is connected with the flashing board down, the flashing board covers the up end in connecting portion, and the flashing board is connected in connecting portion. This application has the effect that improves the waterproof performance on the roof of assembled steel construction factory building.

Description

Energy-saving assembly type steel structure factory building

Technical Field

The application relates to the technical field of steel structure buildings, in particular to an energy-saving assembly type steel structure factory building.

Background

In recent years, with the rapid development of the assembly type steel structure building technology, the assembly type steel structure is often used for building in the building of a factory building, so that the effect of saving building materials is achieved, and meanwhile, a light-transmitting plate can be laid on a steel structure roof to increase a light source, so that the effect of saving energy is achieved.

The patent document with the application number of 201520025540.5 discloses a steel structure factory building which is formed by connecting a frame body, a roof panel and a transparent daylighting panel; the frame body consists of a plurality of supporting beams, a plurality of cross beams, a plurality of supporting inclined rods and a plurality of connecting bolts; the steel structure factory building comprises a roof and a plurality of wall surfaces; the roof is formed by mounting a supporting diagonal rod, a cross beam and a transparent daylighting panel through a connecting bolt; the wall surface is formed by mounting a supporting beam, a cross beam, a roof panel and a transparent daylighting panel through a connecting bolt, and the roof panel and the transparent daylighting panel on the wall surface are arranged at intervals.

In view of the above-mentioned related art, the inventor thinks that the roof of the steel structure factory building is relatively poor in waterproof effect because the roof is spliced or bolted.

SUMMERY OF THE UTILITY MODEL

In order to improve the water-proof effects on the roof of the assembly type steel structure factory building, the application provides an energy-saving assembly type steel structure factory building.

The application provides a pair of energy-conserving assembled steel construction factory building adopts following technical scheme:

the utility model provides an energy-conserving assembled steel construction factory building, includes support body and first panel layer, first panel layer includes roof boarding under daylighting board and the polylith, the roof boarding is fixed in the support body down, the daylighting board is located between two adjacent roof boarding down, the border slope orientation of the roof boarding is turned over towards one side that deviates from the support body down and is rolled over a formation connecting portion down, the border of roof boarding is connected with the flashing board down, the flashing board approximately fits the up end of connecting portion, and the flashing board is connected in connecting portion.

Through adopting above-mentioned technical scheme, roof boarding and the crisscross setting of lower plane skylight can improve the daylighting area on first panel layer for the daylighting effect of factory building is better relatively, and the both sides border of plane skylight is formed with the obliquely connecting portion down, and is provided with flashing board and closes connecting portion lid, blocks and the drainage to the rainwater, thereby makes the rainwater be difficult for in the gap infiltration factory building between following down plane skylight and the lower roof boarding, improves the waterproof performance on factory building roof.

Optionally, the roof boarding includes flat plate portion and uplift portion down, the uplift portion is connected in the border of flat plate portion daylighting board down, the uplift portion bending roll shaping has the buckling parts, the border of buckling parts is located the book mouth of self buckling, one side border card of flashing board is located in the buckling parts.

Through adopting above-mentioned technical scheme, the uplift can be so that the lock position is located the eminence, makes the difficult interior diffuse infiltration of rainwater, and the side of flashing board is located in the lock portion of crook along the card to the route extension that makes the rainwater infiltration makes in the difficult infiltration factory building of rainwater.

Optionally, the first panel layer further includes a heat insulation layer, the heat insulation layer is disposed between the lower panel and the frame body, and the heat insulation layer is connected to the frame body.

Through adopting above-mentioned technical scheme, the heat preservation can keep warm to the factory building to reduce scattering and disappearing of temperature in the factory building or the influence of ambient temperature in to the factory building.

Optionally, the uplift portion is provided with fixed unit, fixed unit includes fixed block and joint board, the fixed block is connected in the heat preservation, the joint board is connected in the fixed block, joint board one side border is by the centre gripping between buckling parts and flashing board.

Through adopting above-mentioned technical scheme, the fixed block can be used to fixed joint board, and joint board can block and locate between buckling parts and the flashing board, makes the joint between buckling parts and the flashing board inseparabler relatively, the difficult condition that breaks away from that takes place.

Optionally, a side face, facing the fixed block, of the connecting portion is connected with a butting block, and the butting block butts against the fixed block.

Through adopting above-mentioned technical scheme, connecting portion take place deformation easily when the plane skylight atress, and the butt joint piece can conduct the atress of connecting portion to the fixed block to support connecting portion, reduce connecting portion and take place deformation and lead to breaking away from the condition of flashing board.

Optionally, the frame body comprises a cross beam and a stand column, the cross beam is connected to the stand column, one side, facing the first panel layer, of the cross beam is connected with a plurality of purlines, the heat preservation layer is connected to the purlines, one side, facing away from the lower roof panel, of each purline is connected with an inner roof panel, and an inner lighting panel is arranged between every two adjacent inner roof panels.

Through adopting above-mentioned technical scheme, interior roof boarding and interior plane skylight that terminal surface set up under the purlin can be formed with the cavity with between the first panel layer, and the cavity that forms can play heat retaining effect to in coordination with the heat preservation, make the heat preservation effect of factory building better relatively.

Optionally, the first panel layer is divided into two parts and symmetrically arranged along the ridge, the ridge is arranged above the first panel layer and comprises a ridge beam frame and a second panel layer, the ridge beam frame is connected to the frame body, the second panel layer comprises an upper roof panel and an upper daylighting panel, the upper daylighting panel is pressed on the edge of the upper roof panel, the upper daylighting panel is connected to the upper roof panel, and the upper roof panel is connected to the ridge beam frame.

Through adopting above-mentioned technical scheme, the last plane skylight of just ridge setting and the light-transmitting area of last roof boarding multiplicable factory building ridge department for the printing opacity effect of factory building ridge department is better.

Optionally, the barricade is all provided with at ridge length direction's both ends, the barricade is connected with waterproof folded plate, waterproof folded plate is located the top of roof boarding down, and waterproof folded plate slant sets up, the high-end barricade of keeping to the waterproof folded plate, the low end of waterproof folded plate is connected in roof boarding down.

Through adopting above-mentioned technical scheme, during rainy season, the barricade can block the rainwater that the offside was blown to the factory building, makes in the rainwater is difficult for flowing into the factory building from the lateral part of factory building, and waterproof folded plate can cover the gap between barricade and the first panel layer, reduces the rainwater and follows the condition of the gap infiltration between barricade and the first panel layer.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the lower roof board and the lower daylighting board are arranged in a staggered manner, so that the daylighting area of the first panel layer can be increased, the daylighting effect of a factory building is relatively better, oblique connecting parts are formed at the edges of two sides of the lower daylighting board, and the flashing board is arranged to cover the connecting parts and block and guide rainwater, so that the rainwater is not easy to permeate into the factory building from a gap between the lower daylighting board and the lower roof board, and the waterproof performance of the roof of the factory building is improved;

2. during rainy season, the barricade can block the rainwater that the lateral surface blows to the factory building, makes in the rainwater is difficult for flowing into the factory building from the lateral part of factory building, and waterproof folded plate can cover the gap between barricade and the first panel layer, reduces the rainwater and follows the condition of the gap infiltration between barricade and the first panel layer.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of the present application;

FIG. 2 is a partial cross-sectional view of an assembled steel structural factory building frame according to an embodiment of the present application;

fig. 3 is a schematic cross-sectional view of a first panel layer of an embodiment of the present application.

Description of reference numerals: 1. a frame body; 11. a cross beam; 111. a purlin; 12. a column; 2. a first panel layer; 21. a lower daylighting panel; 211. a connecting portion; 212. a butting block; 22. a lower roof panel; 221. a flashing plate; 222. a flat plate portion; 223. a raised portion; 2231. a fastening part; 224. a fixing unit; 2241. a fixed block; 2242. a clamping and connecting plate; 23. a heat-insulating layer; 24. an inner roof panel; 25. an inner plane skylight; 3. correcting the spine; 31. a ridge beam frame; 311. a beam column; 312. a beam bone; 313. a fixed seat; 314. a vapor barrier; 32. a second panel layer; 321. an upper roof panel; 322. an upper plane skylight; 4. retaining walls; 41. a waterproof folded plate.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses energy-conserving assembled steel construction factory building. Referring to fig. 1 and 2, the energy-saving assembly type steel structure factory building includes a frame body 1, a first panel layer 2, and a regular ridge 3. Support body 1 is used for fixed first panel layer 2, and support body 1 includes crossbeam 11 and the stand 12 of a plurality of vertical settings, and stand 12 sets up in ground, and crossbeam 11 fixed connection is in the upper end of stand 12, and crossbeam 11 has a plurality of purlins 111 towards bolted connection for one side of first panel layer 2.

Referring to fig. 2 and 3, the first panel layer 2 includes a lower daylighting panel 21, a lower roof panel 22, and an insulating layer 23. The heat preservation layer 23 is fixedly connected to the upper end face of the purline 111, the lower roof panels 22 are located right above the heat preservation layer 23, the lower light collecting plate 21 is located between two adjacent lower roof panels 22, each lower roof panel 22 comprises a flat plate portion 222 and a raised portion 223, the raised portions 223 and the flat plate portions 222 are integrally formed, the raised portions 223 are located on one side edge, facing the lower light collecting plate 21, of the flat plate portions 222, openings of the raised portions 223 face the purline 111, and the flat plate portions 222 are fixedly connected to the heat preservation layer 23.

The bulge 223 has buckling part 2231 towards the curved roll shaping of one side edge of the lower lighting panel 21, buckling part 2231 is around flowing column structure and the winding opening of buckling part 2231 towards purlin 111, the edge that the buckling part 2231 was rolled up is located the winding opening of self buckling, buckling part 2231 is connected with flashing 221, flashing 221 one side edge forms similar around flowing column structure with the curved roll of buckling part 2231, and this side edge card of buckling part 2231 is located in the buckling part 2231.

One side edge of the lower light board 21 facing the lower roof board 22 inclines towards one side deviating from the purlin 111, and is turned over and formed to be provided with a connecting part 211, so that the lower light board 21 is of an arc-shaped plate-shaped structure, and the arc-shaped opening of the lower light board 21 faces back to the purlin 111. One side plate surface of the flashing plate 221 far away from the buckling part 2231 is obliquely arranged, the flashing plate 221 is covered and connected on the upper end surface of the connecting part 211, and bolts are arranged in a penetrating manner to fix the flashing plate 221 and the connecting part 211.

Therefore, the lower daylighting plate 21 and the lower roof plate 22 are arranged in a staggered mode, so that the daylighting effect in a factory building is relatively better, the use of electric energy daylighting equipment is reduced, and the energy-saving effect is achieved. And the flashing board 221 that sets up can cover the junction of daylighting panel 21 and lower roof boarding 22 down, makes inside the difficult infiltration factory building of rainwater to flashing board 221 passes through buckling parts 2231 with the border of lower roof boarding 22 and winds the roll joint, and the route of extension rainwater from buckling parts 2231 infiltration makes waterproof effect better.

One side of the purline 111, which faces away from the lower roof panel 22, is fixedly connected with an inner roof panel 24, an inner daylighting panel 25 is arranged between two adjacent inner roof panels 24, the inner roof panel 24 is positioned below the lower roof panel 22, and the inner daylighting panel 25 is positioned below the lower daylighting panel 21. Interior plane skylight 25 and interior roof boarding 24 fixed connection to interior plane skylight 25, interior roof boarding 24 and heat preservation 23 enclose and establish the cavity that is used for the heat preservation, make the heat of factory building difficult for giving off, reduce the energy consumption.

Referring to fig. 2 and 3, in order to make the pressure resistance of the swelling portion 223 relatively higher, it is not easily separated from the flashing 221. One side that the uplift 223 was provided with fixed unit 224 towards heat preservation 23, and fixed unit 224 includes fixed block 2241 and joint board 2242, and fixed block 2241 is Z type steel, and the bolt is worn to be equipped with in heat preservation 23 and fixed block 2241 along the butt in fixed block 2241 one side, and fixed block 2241 passes through bolt fixed connection in heat preservation 23, and the face butt in flashing board 221 on the fixed block 2241 for support flashing board 221. The clamping plate 2242 and the fixing block 2241 are provided with a plurality of bolts, the clamping plate 2242 and the fixing block 2241 are fixedly connected through the bolts, the upper end edge of the clamping plate 2242 is bent and clamped and fixed by the buckling part 2231 and the flashing plate 221, so that a gap between the buckling part 2231 and the flashing plate 221 is filled, and clamping between the flashing plate 221 and the buckling part 2231 is relatively stable.

Meanwhile, one side of the connecting portion 211 facing the fixing block 2241 is provided with a butting block 212, and bolts for fixing the connecting portion 211 and the flashing plate 221 penetrate through the butting block 212, and fixedly connect the butting block 212 to the connecting portion 211. The abutting block 212 is an angle steel bar, one side corner side surface of the abutting block 212 abuts against the connecting portion 211, and one side corner edge of the abutting block 212 abuts against the fixing block 2241. When the lower lighting plate 21 bears the weight, the lower lighting plate 21 is driven to be pressed downwards and deformed, and the abutting block 212 can abut against the fixing block 2241, so that the deformation of the connecting part 211 is reduced.

Referring to fig. 2 and 3, the first panel layer 2 is divided into two parts and symmetrically arranged along the ridge respectively, the positive ridge 3 is arranged above the first panel layer 2, and the positive ridge 3 is used for increasing the lighting effect of the roof of the factory building. The spine 3 comprises a spine frame 31 and a second panel layer 32, the spine frame 31 comprises a beam column 311 and a beam bone 312 fixedly connected to the upper end of the beam column 311, and the lower end of the beam column 311 is fixedly connected to the cross beam 11. Roof beam bone 312 sets up along the roof slant, and its high-end is located roof department, and second panel layer 32 includes roof boarding 321 and last plane skylight 322, goes up the plane skylight 322 and constitutes for the light-passing board integrated into one piece of two slant settings to form the ridge structure, last plane skylight 322 in the embodiment of this application, lower plane skylight 21 and interior plane skylight 25 all use the plastic slab that light transmission performance is high.

The lower lighting panel 21 is located at the two side edges of the lower end and is pressed on the edge of the upper roof panel 321, and the upper lighting panel 322 is fixedly connected to the upper panel surface of the upper roof panel 321. Go up roof boarding 321's the same fixedly connected with heat preservation 23 of lower terminal surface, the welding of beam bone 312 towards one side of heat preservation 23 has fixing base 313, fixing base 313's upper end fixed connection in last roof boarding 321's the lower terminal surface of heat preservation 23 to beam bone 312 has laid vapour barrier 314 towards one side of last roof boarding 321, and vapour barrier 314 of this application embodiment chooses for use transparent plastic film. Therefore, the positive ridge 3 can keep a larger light transmission area, and the condition that the light transmission effect at the ridge is not good for waterproofing in the traditional ridge laying process is avoided. The steam-isolating layer can reduce the emission of water vapor in the plant, so that the plant keeps better moisture-keeping performance.

Referring to fig. 1 and 3, in order to solve the problem that rainwater is easy to splash into a factory building from two sides of a factory building ridge in rainy season. The both ends of roof ridge are pour and are built barricade 4, and the upper end of barricade 4 is higher than first panel layer 2, and barricade 4 towards the waterproof folded plate 41 of one side fixedly connected with of positive ridge 3, and waterproof folded plate 41 slant sets up and waterproof folded plate 41's high-end border is towards barricade 4, and the low end border of waterproof folded plate 41 is set up in the uplift 223 of roof boarding 22 down, and through the bolt fastening at uplift 223, fill sealed glue in the gap between waterproof folded plate 41 and uplift 223 and seal. The retaining wall 4 can block rainwater on the side, and the waterproof folded plate 41 can block the gap between the lower roof panel 22 and the retaining wall 4, so that rainwater is not easy to infiltrate into the room from the gap.

The front and the back of the factory building are provided with wallboards, the peripheral sides of the front ridges 3 are also provided with wallboards, the wallboards are used for enabling the factory building to realize totally-enclosed quality in the factory building, and a plurality of windows and gates are arranged on the wallboards, and the windows are used for increasing light sources in the factory building. The upper end edges of the lower roof panel 22 and the lower lighting panel 21 are fixedly connected to the wall plate of the main ridge 3, the lower end edge of the lower roof panel 22 is provided with a drainage groove, the drainage groove is fixedly connected with a drainage pipe, and the drainage pipe is vertically arranged and communicated with the drainage groove. The rainwater that first panel layer 2 flowed down can be collected to the escape canal groove to discharge from the drain pipe, reduce the condition that eave rainwater splashes.

The implementation principle of the energy-saving assembly type steel structure factory building in the embodiment of the application is as follows: roof board 22 and the interval of lower plane skylight 21 set up the light transmission performance of multiplicable roofing to setting up through buckling part 2231 and flashing board 221 can shelter from the gap between roof board 22 and the lower plane skylight 21 down, makes in the difficult infiltration factory building of rainwater, and is formed with the cavity between heat preservation 23, interior plane skylight 25 and the interior roof board 24, can make the heat preservation effect promote, reduces the energy consumption in the factory building. And set up in the positive ridge 3 of first panel layer 2, used the roof ridge panel of the factory building of last plane skylight 322 of great light transmission area, increase the roof ridge printing opacity effect of factory building.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides an energy-conserving assembled steel construction factory building, includes support body (1) and first panel layer (2), its characterized in that: first panel layer (2) are roof boarding (22) under light board (21) and the polylith down including, down roof boarding (22) are fixed in support body (1), light board (21) are located two adjacent down between roof boarding (22) down, light board (21) down incline towards one side that deviates from support body (1) along the border slope of roof boarding (22) down and turn over a formation connecting portion (211), the border of roof boarding (22) is connected with flashing board (221) down, flashing board (221) approximately fits the up end of connecting portion (211), and flashing board (221) connect in connecting portion (211).

2. The energy efficient assembled steel structural plant of claim 1, wherein: the lower roof panel (22) comprises a flat plate portion (222) and a raised portion (223), the raised portion (223) is connected to the edge of the flat plate portion (222) facing the lower light collecting plate (21), the raised portion (223) is bent and formed to be provided with a buckling portion (2231), the edge of the buckling portion (2231) is located in a rolling opening bent by the buckling portion, and one side edge of the flashing plate (221) is clamped in the buckling portion (2231).

3. The energy efficient assembled steel structural plant of claim 2, wherein: the first panel layer (2) further comprises a heat insulation layer (23), the heat insulation layer (23) is arranged between the lower panel (22) and the frame body (1), and the heat insulation layer (23) is connected to the frame body (1).

4. The energy efficient assembled steel structural plant of claim 3, wherein: bump (223) are provided with fixed unit (224), fixed unit (224) include fixed block (2241) and joint board (2242), fixed block (2241) is connected in heat preservation (23), joint board (2242) is connected in fixed block (2241), joint board (2242) one side border is by the centre gripping between buckling parts (2231) and flashing board (221).

5. The energy efficient assembled steel structural plant of claim 4, wherein: connecting portion (211) are connected with butt piece (212) towards the side of fixed block (2241), butt piece (212) butt in fixed block (2241).

6. The energy efficient assembled steel structural plant of claim 5, wherein: the frame body (1) comprises a cross beam (11) and a vertical column (12), the cross beam (11) is connected to the vertical column (12), one side, facing the first panel layer (2), of the cross beam (11) is connected with a plurality of purlines (111), the heat insulation layer (23) is connected to the purlines (111), one side, facing away from the lower roof panel (22), of each purline (111) is connected with an inner roof panel (24), and two adjacent inner roof panels (25) are arranged between the inner roof panels (24).

7. The energy efficient assembled steel structural plant of claim 1 or 6, wherein: the roof board structure is characterized in that the first panel layer (2) is divided into two parts and symmetrically arranged along a ridge, a ridge correcting part (3) is arranged above the first panel layer (2), the ridge correcting part (3) comprises a ridge beam frame (31) and a second panel layer (32), the ridge beam frame (31) is connected to the frame body (1), the second panel layer (32) comprises an upper roof panel (321) and an upper daylighting panel (322), the upper daylighting panel (322) is pressed on the edge of the upper roof panel (321), the upper daylighting panel (322) is connected to the upper roof panel (321), and the upper roof panel (321) is connected to the ridge beam frame (31).

8. The energy efficient assembled steel structural plant of claim 7, wherein: roof length direction's both ends all are provided with barricade (4), barricade (4) are connected with waterproof folded plate (41), waterproof folded plate (41) are located the top of roof boarding (22) down, and waterproof folded plate (41) slant sets up, the high-end of waterproof folded plate (41) is towards barricade (4), the low-end of waterproof folded plate (41) is connected in roof boarding (22) down.

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