CN116927508B - Keel structure and radian roof sunlight plate installation method - Google Patents

Abstract

The application provides a keel structure and a method for installing a radian roof sunlight plate, wherein the vertically adjacent sunlight plates are overlapped in an up-down staggered way through the keel structure, the plate surface of the sunlight plate is connected with a bidirectional sliding support, the problem that a glue joint is cracked due to different temperature changes and shrinkage of the sunlight plate is effectively solved, the hidden danger of water leakage caused by the infiltration of rainwater from a stainless steel waterproof self-tapping screw pulling crack is avoided, the possibility of roof water leakage is reduced, the method comprises a plurality of vertical secondary keels, and the vertical secondary keels are longitudinally arranged on the roof structure in parallel front and back and form slopes along the length direction of the vertical secondary keels; the transverse secondary keels are multiple, and are transversely fixed on the vertical secondary keels from left to right; a plurality of bidirectional sliding supports are fixed on the transverse secondary joists; the lap joint keels are transversely fixed on the vertical secondary keels from left to right, the front side surfaces of the lap joint keels are provided with front grooves, the rear side surfaces of the lap joint keels are provided with rear grooves, and the positions of the front grooves are higher than those of the rear grooves.

Description

Keel structure and radian roof sunlight plate installation method

Technical Field

The application relates to the technical field of roof engineering of building roofs, in particular to a keel structure and a method for installing a radian roof sunlight plate.

Background

The new technology of the building material industry in China is rapidly developed, new materials and new processes are continuously emerging, and building roofing material patterns are changed in a changeable way and are different. The polycarbonate solid plate (sunlight plate), color steel tile, glass plate, stainless steel plate and the like are building materials which appear in recent years, and have the advantages of water resistance, energy conservation, strong impact resistance, ultraviolet resistance, good sound insulation performance and the like. In the selection of arch roofing of big radian, sunshine board is with printing opacity, bendability good, and simple to operate is swift as the preferred material, during the installation, fixes sunshine board on the keel frame through waterproof self-tapping screw and technique such as sticky, forms the roof.

However, the sunlight plate is a polycarbonate endurance plate, the thermal deformation rate under the influence of temperature is 5% -10%, the expansion amount is up to 10cm in the installation and subsequent use processes, the sealing waterproof adhesive tape is often cracked, and the water leakage phenomenon can occur after a period of use; meanwhile, relative displacement is generated between the sunlight plate and the stainless steel waterproof self-tapping screw in the telescoping process, so that the plate is pulled apart, gaps are generated, hidden danger of water leakage is caused, the main steel structure and the keels are corroded, the subsequent maintenance cost is increased, and pedestrian passing experience is affected.

Disclosure of Invention

The application provides a keel structure and a method for installing a radian roof sunlight plate, wherein the vertically adjacent sunlight plates are overlapped in an up-down staggered way through the keel structure, the plate surfaces of the sunlight plates are connected with a bidirectional sliding support, the problem that glue joints are cracked due to different temperature changes and shrinkage of the sunlight plates is effectively solved, the hidden danger of water leakage caused by rainwater infiltration from a stainless steel waterproof self-tapping screw pulling crack is avoided, and the possibility of roof water leakage is reduced.

The application is realized by the following technical scheme:

a keel structure, which comprises a keel body,

the vertical secondary keels are arranged in parallel, longitudinally arranged on the roof structure front and back, and form slopes along the length direction of the vertical secondary keels;

the transverse secondary keels are multiple, and are transversely fixed on the vertical secondary keels from left to right; a plurality of bidirectional sliding supports are fixed on the transverse secondary joists;

the lap joint keels are transversely fixed on the vertical secondary keels from left to right, the front side surfaces of the lap joint keels are provided with front grooves, the rear side surfaces of the lap joint keels are provided with rear grooves, and the positions of the front grooves are higher than those of the rear grooves.

Further, the bidirectional sliding support comprises a bottom support, a middle support and a top support, wherein the front side surface and the rear side surface of the bottom support are provided with first sliding grooves, and the lower parts of the front side surface and the rear side surface of the middle support are provided with first sliding blocks which are in sliding fit with the first sliding grooves;

the upper parts of the left side surface and the right side surface of the middle support are provided with second sliding grooves, and the left side surface and the right side surface of the top support are provided with second sliding blocks which are in sliding fit with the second sliding grooves.

Further, a plurality of water discharge holes are formed in the back face of the front groove.

Furthermore, the lap joint keels are formed by splicing an S-shaped frame and square tubes up and down.

The application relates to a method for installing a radian roof sunlight plate, which adopts a keel structure to install the radian roof sunlight plate and comprises the following steps:

s1, firstly, building a vertical secondary keel on a roof structure, wherein the vertical secondary keel forms a gradient along the length direction of the vertical secondary keel; then installing a transverse secondary keel and a lap joint keel on the vertical secondary keel to form a keel supporting structure;

s2, paving the sunlight plate on the keel supporting structure along the gradient direction;

s3, connecting the vertically adjacent sunlight plates into a whole through the lap joint keels;

the rear end of the upper sunlight plate is inserted into the front groove of the lap joint keel, and the bottom of the sunlight plate is sealed by embedding the ethylene-propylene-diene rubber strip into the front groove,

the front end of the sunlight plate below is inserted into the rear groove of the lap joint keel and is fixed in the rear groove through a screw, then the bottom sealing of the sunlight plate is realized by embedding an ethylene propylene diene monomer rubber strip into the rear groove,

s4, fixing the sunlight plate on the top surface of the bidirectional sliding support through screws, wherein the bidirectional sliding support can slide in four directions, namely front, back, left and right.

Further, in step S3,

the rear end of the upper sunlight plate is inserted into the front groove of the lap joint keel and a 20-35mm expansion gap is reserved, and the front end of the lower sunlight plate is inserted into the rear groove of the lap joint keel and a 10-15mm expansion gap is reserved.

Further, in step S4, an EPDM waterproof gasket is installed between the screw and the outer surface of the solar panel.

Further, the top surface of overlap joint fossil fragments is the aluminum alloy buckle, and the rear end joint of aluminum alloy buckle is fixed on the sunshine board through the sealant at the top surface of overlap joint fossil fragments, front end.

Further, the distance between the two-way sliding supports on the transverse secondary joists is 300-400mm.

Compared with the prior art, the application has the following beneficial effects:

1. the application provides a keel structure which comprises a vertical secondary keel, a horizontal secondary keel and a lap joint keel, wherein a plurality of bidirectional sliding supports are fixed on the horizontal secondary keel; the whole keel system is safe and firm in structure and convenient to operate, the physical properties of the sunlight plates are comprehensively considered, and the lap joint keels are used, so that the plates of the adjacent sunlight plates are lapped, and the bidirectional sliding support can buffer the deformation of the sunlight plates;

according to the method for installing the radian roof sunlight plate, the radian roof sunlight plate is installed by adopting the keel structure, the vertically adjacent sunlight plates are overlapped in an up-down staggered manner by the keel structure, the plate surfaces of the sunlight plates are connected with the two-way sliding support, the problem that the sunlight plates leak water due to cracking of glue joints caused by temperature change, shrinkage difference and the like is effectively solved, the hidden danger of water leakage caused by infiltration of rainwater from the cracking positions of stainless steel waterproof self-tapping nails is avoided, and the possibility of roof water leakage is reduced;

2. the bidirectional sliding support comprises a bottom support, a middle support and a top support, so that the bidirectional sliding support can move in the front-back direction and the left-right direction, the thermal expansion and contraction effects of the sunlight plate are counteracted, the deformation caused by stress is effectively reduced, the quality common diseases such as crack leakage and water leakage of the sunlight plate on the roof are pre-controlled, the service life of the plate is prolonged, the damage probability of the sunlight plate is reduced, the maintenance cost caused by the breakage of the sunlight plate in the use process is reduced, the use and the attractiveness are ensured to be integrated, the cost is greatly saved, and the construction period is shortened;

3. the application effectively solves the problem that the glue line is pulled apart due to temperature change, shrinkage difference and the like of the sunlight plate, prevents rainwater from penetrating from the pulled apart position and avoids hidden danger of water leakage;

4. the back of the front groove is provided with a plurality of water discharge holes, when water is accumulated, the water can be rapidly discharged to the surface of the next sunlight plate, and the water is prevented from leaking below the roof;

5. through the novel keel structure, the original structure is prevented from being damaged, the plate installation efficiency is improved, the use and the attractiveness are ensured to be integrated, the subsequent maintenance and operation cost is reduced, and a large amount of construction period is saved.

Drawings

Figure 1 is a top view of a keel structure according to the application;

fig. 2 is a schematic view of the cooperation of the lap joint keels and the sunlight plates according to the application;

FIG. 3 is a schematic front view of the bi-directional sliding support of the present application mated with a solar panel;

FIG. 4 is a schematic side view of the bi-directional sliding support of the present application mated with a solar panel;

FIG. 5 is a schematic view of the overall construction of the keel structure and solar panel of the present application;

in the figure: 1. vertical secondary joist, 2, overlap joint joist, 3, horizontal secondary joist, 4, two-way sliding support, 41, bottom support, 42, middle support, 43, top support, 44, first spout, 45, first slider, 46, second spout, 47, second slider, 5, front groove, 6, back groove, 7, ethylene propylene diene monomer rubber strip, 8, aluminum alloy buckle, 9, EPDM waterproof gasket, 10, sunshine board, 11, set screw, 12, water drain hole.

Detailed Description

The present embodiment is described below in detail only with reference to the preferred embodiments of the present application and is not intended to limit the scope of the present application, but rather to limit the scope of the present application as defined in the appended claims without departing from the spirit of the present application.

In the description of the present application, it should be understood that the directions or positional relationships indicated by the terms "front", "rear", "upper", "lower", "left", "right", etc., are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present application and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application.

As shown in fig. 1, this embodiment discloses a keel structure, mainly including a plurality of vertical cross runners 1, horizontal cross runner 3 and overlap joint fossil fragments 2 of aluminum alloy material, vertical cross runner 1 is installed on roof structure longitudinally around side by side to form the slope along its length direction. The transverse cross runners 3 are laterally fixed on the vertical cross runners 1 from side to side, and a plurality of bidirectional sliding supports 4 are fixed on the transverse cross runners 3, and in this embodiment, the bidirectional sliding supports 4 are arranged at intervals of 300 mm.

As shown in fig. 2, the overlapping keels 2 are laterally fixed on the vertical secondary keels 1 from side to side, the distance between adjacent overlapping keels 2 is the length of a sunlight plate, and the overlapping keels 2 are formed by splicing an S-shaped frame and square tubes up and down. So that the front side of the overlap keel 2 is provided with a front groove 5 and the rear side is provided with a rear groove 6, and the front groove 5 is positioned higher than the rear groove 6. In order to facilitate drainage, a plurality of water discharge holes 12 are formed in the rear back surface of the front groove 5, the bottoms of the water discharge holes 12 are aligned with the bottoms of the front groove 5, and water can be timely discharged in the front groove 5. The whole keel structure is rectangular, all keel components are connected through bolts, and after installation is completed, the keel components are glued and sealed, so that water leakage is prevented.

As shown in fig. 3-4, the bidirectional sliding support 4 comprises a bottom support 41, a middle support 42 and a top support 43, wherein a first sliding groove 44 is formed on the front side and the rear side of the bottom support 41, and a first sliding block 45 in sliding fit with the first sliding groove 44 is formed on the lower part of the front side and the rear side of the middle support 42; second slide grooves 46 are formed in upper portions of left and right side surfaces of the middle support 42, and second slide blocks 47 slidably fitted with the second slide grooves 46 are formed in left and right side surfaces of the top support 43. By matching the sliding blocks with the corresponding sliding grooves, the middle support 42 can move left and right relative to the bottom support 41, and the top support 43 moves back and forth relative to the middle support 42, and the movement amount is 1.5-5mm.

As shown in fig. 5, the application also discloses a method for installing the radian roof sunlight plate, which adopts the keel structure to install the radian roof sunlight plate and comprises the following steps:

s1, firstly building a vertical secondary keel 1 on a roof structure, wherein the vertical secondary keel 1 forms a gradient along the length direction of the vertical secondary keel; then, installing a transverse secondary keel 3 and a lap joint keel 2 on the vertical secondary keel 1 to form a keel supporting structure;

s2, paving the sunlight plate 10 on the keel supporting structure along the gradient direction;

s3, vertically adjacent sunlight plates 10 are connected into a whole through a lap joint keel 2;

the rear end of the upper sunlight plate 10 is inserted into the front groove 5 of the lap joint keel 2, a 33mm expansion gap is reserved, the bottom sealing of the sunlight plate is realized by embedding the ethylene propylene diene monomer rubber strip 7 into the front groove 5,

the front end of the sunlight plate below is inserted into the rear groove 6 of the lap joint keel 2, a 10mm expansion gap is reserved, the front end of the sunlight plate is fixed in the rear groove 6 through a stainless steel positioning screw 11, then the bottom sealing of the sunlight plate is realized through embedding an ethylene propylene diene monomer strip 7 into the rear groove 6,

in the step, the top surface of the lap joint keel 2 can be a split aluminum alloy buckle plate 8, the rear end of the aluminum alloy buckle plate 8 is clamped on the top surface of the lap joint keel 2, the front end of the aluminum alloy buckle plate is fixed on a sunlight plate through sealant, the sealing is used for fixing the aluminum alloy buckle plate 8, when the sunlight plate 10 stretches under the influence of temperature, the bidirectional sliding support 4 prevents the sealant from cracking, even if a very small part of glue lines crack, part of rainwater enters the lap joint keel 2 and is discharged from a drain hole 12 below, and the rainwater is prevented from dripping into the ground along the keel;

s4, fixing the sunlight plate on the top surface of the top support 43 of the bidirectional sliding support 4 through screws, and installing an EPDM waterproof gasket 9 between the screws and the outer surface of the sunlight plate, wherein the bidirectional sliding support 4 can slide in four directions, namely front, back, left and right.

The method for installing the radian roof sunlight plate has the advantages of simple construction process, good roof waterproof effect and high construction speed, and can effectively prevent water leakage of the roof. When the former adjacent sunlight plates are spliced, the adjacent sunlight plates are directly abutted and connected through sealant, when the sunlight plates stretch out and draw back, the adjacent sunlight plates are mutually extruded to cause the glue joint at the joint to crack, rainwater easily falls into a house through the crack joint after cracking, the upper and lower adjacent sunlight plates are overlapped in a staggered way up and down through the splicing keels, the sunlight plates cannot mutually extrude when stretching and deforming, and enough stretching amount gaps are reserved in the front groove 5 and the rear groove 6, so that the problem that the glue joint cracks and leaks due to temperature change, shrinkage difference and the like of the former adjacent sunlight plate butt joint is effectively solved; even though the sealant of the aluminum alloy buckle plate 8 and the sunlight plate is deformed and cracked due to the expansion and contraction of the current sunlight plate, rainwater permeates into the front groove 5, and can be timely discharged to the next sunlight plate to be discharged due to the existence of the water discharge hole 12.

The plate body of the traditional sunlight plate is directly connected with the keel through a waterproof self-tapping screw, the sunlight plate and the stainless steel waterproof self-tapping screw produce relative displacement in the telescoping process of the sunlight plate, the plate is pulled to crack, gaps are produced, and hidden danger of water leakage is caused. The bidirectional sliding support 4 additionally arranged on the sunlight plate can offset the thermal expansion and contraction effects of the sunlight plate, effectively reduce deformation caused by stress, avoid cracks, pre-control quality common problems such as roof water leakage and the like, prolong the service life of the plate, and reduce the damage probability of the sunlight plate, thereby reducing the maintenance cost caused by the breakage of the sunlight plate in the use process, ensuring the use and the beautiful appearance to be integrated, greatly saving the cost and shortening the construction period.

Claims (6)

1. A keel structure is characterized by comprising,

the vertical secondary keels are arranged in parallel, longitudinally arranged on the roof structure front and back, and form slopes along the length direction of the vertical secondary keels;

the transverse secondary keels are multiple, and are transversely fixed on the vertical secondary keels from left to right; a plurality of bidirectional sliding supports are fixed on the transverse secondary joists;

the lap joint keels are transversely fixed on the vertical secondary keels left and right, the front side surfaces of the lap joint keels are provided with front grooves, the rear side surfaces of the lap joint keels are provided with rear grooves, and the positions of the front grooves are higher than those of the rear grooves;

the bidirectional sliding support comprises a bottom support, a middle support and a top support, wherein the front side surface and the rear side surface of the bottom support are provided with first sliding grooves, and the lower parts of the front side surface and the rear side surface of the middle support are provided with first sliding blocks which are in sliding fit with the first sliding grooves;

the upper parts of the left side surface and the right side surface of the middle support are provided with second sliding grooves, and the left side surface and the right side surface of the top support are provided with second sliding blocks which are in sliding fit with the second sliding grooves;

the back of the front groove is provided with a plurality of water discharge holes;

the lap joint keels are formed by splicing an S-shaped frame and square tubes up and down;

the upper and lower adjacent sunlight plates are overlapped in an up-and-down staggered way through the keel structure, and the plate surfaces of the sunlight plates are connected with the bidirectional sliding support.

2. The method for installing the radian roof sunlight plate is characterized by adopting the keel structure of claim 1 to install the radian roof sunlight plate, and comprises the following steps:

s1, firstly, building a vertical secondary keel on a roof structure, wherein the vertical secondary keel forms a gradient along the length direction of the vertical secondary keel; then installing a transverse secondary keel and a lap joint keel on the vertical secondary keel to form a keel supporting structure;

s2, paving the sunlight plate on the keel supporting structure along the gradient direction;

s3, connecting the vertically adjacent sunlight plates into a whole through the lap joint keels;

the rear end of the upper sunlight plate is inserted into the front groove of the lap joint keel, and the bottom of the sunlight plate is sealed by embedding the ethylene-propylene-diene rubber strip into the front groove,

the front end of the sunlight plate below is inserted into the rear groove of the lap joint keel and is fixed in the rear groove through a screw, then the bottom sealing of the sunlight plate is realized by embedding an ethylene propylene diene monomer rubber strip into the rear groove,

s4, fixing the sunlight plate on the top surface of the bidirectional sliding support through screws, wherein the bidirectional sliding support can slide in four directions, namely front, back, left and right.

3. The method of installing an arc roofing solar panel according to claim 2, wherein, in step S3,

the rear end of the upper sunlight plate is inserted into the front groove of the lap joint keel and a 20-35mm expansion gap is reserved, and the front end of the lower sunlight plate is inserted into the rear groove of the lap joint keel and a 10-15mm expansion gap is reserved.

4. The method of installing an arc roofing solar panel according to claim 2, wherein in step S4, EPDM waterproof gasket is installed between the screw and the outer surface of the solar panel.

5. The method for installing the radian roof sunlight panel according to claim 2, wherein the top surface of the lap joint keel is an aluminum alloy buckle plate, the rear end of the aluminum alloy buckle plate is clamped on the top surface of the lap joint keel, and the front end of the aluminum alloy buckle plate is fixed on the sunlight panel through sealant.

6. A method of installing an arcuate roof solar panel according to any one of claims 2 to 5 wherein the bi-directional sliding support spacing on the transverse cross runners is 300 to 400mm.