CN113565271A

CN113565271A - Energy-saving metal roof construction system based on energy-saving steel structure and construction method thereof

Info

Publication number: CN113565271A
Application number: CN202110685120.XA
Authority: CN
Inventors: 沙学勇; 陈建其; 高权泽; 周军; 余传波; 刘晓刚; 徐素芳; 项建祥
Original assignee: Zhejiang Southeast Steel Structure Co ltd
Current assignee: Zhejiang Southeast Steel Structure Co ltd
Priority date: 2021-06-21
Filing date: 2021-06-21
Publication date: 2021-10-29
Anticipated expiration: 2041-06-21
Also published as: CN113565271B

Abstract

The invention discloses a metal energy-saving roof construction system based on an energy-saving steel structure and a construction method thereof. This energy-conserving roofing construction system of metal based on energy-conserving formula steel construction and construction method thereof solves metal roofing system in the installation, need overlap metal decking's one end and the other end each other, but both ends are all thinner, make its long-time use, can cause the deformation at panel both ends to and the both ends that overlap each other can lead to the problem that the rainwater infiltration can appear in the clearance owing to do not have mutual buckle.

Description

Energy-saving metal roof construction system based on energy-saving steel structure and construction method thereof

Technical Field

The invention relates to the technical field of metal roof systems, in particular to a metal energy-saving roof construction system based on an energy-saving steel structure and a construction method thereof.

Background

The metal roofing system is also called advanced metal roofing system (the metal curtain wall system can be referred to and selected for use), is a building roofing system which takes metal sheets such as titanium zinc, copper, titanium, aluminum-zinc-plated color plates and the like, aluminum alloy and stainless steel sheets as surface materials, wherein the building roofing system has self-protective anti-corrosion capability, light weight, high strength and durability, and can be divided into the following parts according to the system: a vertical edge occlusion system, a vertical edge locking system, a classical buckle cover system, a flat buckle system, a planar strip system, a contour plate system, and a unit plate system.

When the existing steel structure forms a metal panel in a metal roof system, one end of the metal panel needs to be sleeved at the other end, but both ends of the metal panel are thinner, so that the metal panel can be used for a long time, the two ends of the panel can be deformed, and the two ends sleeved with each other can cause the rainwater to permeate into gaps because of no mutual buckle.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides a metal energy-saving roof construction system based on an energy-saving steel structure and a construction method thereof, which solve the problems that when a metal panel in a metal roof system is installed, one end of the metal panel needs to be sleeved on the other end, but both ends of the metal panel are thinner, so that the metal panel is used for a long time, both ends of the panel are deformed, and the sleeved two ends are not mutually buckled, so that rainwater can infiltrate into gaps.

(II) technical scheme

In order to achieve the purpose, the invention is realized by the following technical scheme: energy-conserving roofing construction system of metal based on energy-conserving formula steel construction, including energy-conserving roofing panel of metal, the fixed latch device that is provided with in right side of energy-conserving roofing panel of metal, the fixed buckle device that is provided with in left side of energy-conserving roofing panel of metal, the equal symmetrical fixed recess of seting up in the left back of energy-conserving roofing panel of metal, the equal symmetrical fixed automatic fastening device that is provided with in surface on energy-conserving roofing panel of metal right side.

The locking device comprises a second arc corner, one end of the second arc corner is fixedly connected with a resisting oblique angle, arc chutes are symmetrically and fixedly formed in the surface of the second arc corner, and fixing mechanisms are symmetrically sleeved between the arc chutes and the top of the second arc corner in a sliding mode.

The clamping device comprises a first arc corner, and a clamping angle is fixedly connected to the bottom of the first arc corner.

The fixing mechanism comprises a straight plate, the surface of the bottom of the straight plate is fixedly connected with a mounting plate, the top of the straight plate is fixedly connected with a third arc corner, and the bottom of the third arc corner is symmetrically and fixedly connected with an arc sliding strip.

Preferably, the automatic fastening device includes the recess board, the equal symmetrical fixedly connected with telescopic machanism of inner chamber of recess board, the dwang has been cup jointed in the inner chamber rotation of recess board, the equal fixedly connected with telescopic plate in telescopic machanism's the top, the top fixedly connected with extrusion arc piece of telescopic plate, the one end fixedly connected with hexagonal screw head of dwang, the equal symmetrical fixedly connected with fixture block mechanism in surface of dwang.

Preferably, telescopic machanism includes the sleeve pipe, the telescopic link has been cup jointed in the sheathed tube inner chamber slip, fixedly connected with spring between the bottom of telescopic link and the bottom of sleeve pipe inner chamber, logical groove has been seted up to the fixed surface of telescopic link, the shrinkage pool has been seted up to the equal symmetry of inner wall in logical groove.

Preferably, the rotating rod penetrates through the inner cavity of the through groove and is located in the center of the inner cavity of the through groove.

Preferably, the end opening of the clamping block mechanism and the inner cavity of the concave hole slide mutually, and the hexagonal screw head is rotatably sleeved in the inner cavity on one side of the groove plate.

Preferably, the bottoms of the sleeves are symmetrically fixed on the bottom of the groove plate, and the tops of the telescopic rods are symmetrically and fixedly connected to the bottom of the telescopic plate.

Preferably, the surface of the expansion plate is matched with the inner cavity of the groove plate, the radian of the top of the extrusion arc block is identical to that of the bottom of the second arc corner, and the top of the extrusion arc block is extruded on the bottom of the second arc corner.

Preferably, the arc-shaped sliding strips are symmetrically sleeved in the inner cavity of the arc chute in a sliding manner, the bottom of the third arc corner and the top of the first arc corner have the same radian, and the third arc corner and the first arc corner are attached to the top of the second arc corner in a sliding manner.

Preferably, the bottom of the first arc corner and the top of the second arc corner have the same radian, and the clamping angle and the retaining oblique angle are mutually clamped and connected.

The invention also discloses a metal energy-saving roof system based on the energy-saving steel structure, and an energy absorption method comprises the following steps:

s1, mounting the metal panel, firstly placing the metal energy-saving roof panel on one side along with the sequence of the building, then holding the straight plate by hand, then enabling the third arc corner to slightly slide along the surface of the second arc corner by the sliding of the arc sliding strip in the arc sliding groove, enabling the straight plate to be attached to the surface of the second arc corner, enabling the bottom of the mounting plate to be attached to the roof, fixing the mounting plate by a bolt, then sleeving the first arc corner at the other end of the metal energy-saving roof panel on the surface of the third arc corner, pressing downwards, enabling the clamping angle to be extruded on the surface of the resisting oblique angle along one end of the second arc corner, enabling the resisting oblique angle to shift inwards along with the extrusion of the clamping angle, enabling the clamping angle to be clamped on the surface of the resisting oblique angle, and enabling the radian in the first arc corner to be mutually matched with the radian of the top of the third arc corner at the same time, through the groove on the back surface of the metal energy-saving roof panel, when the first arc corner is attached to the top of the third arc corner, the third arc corner can be covered, so that the bottoms of the metal energy-saving roof panel and the metal energy-saving roof panel are all parallel and level to each other;

s2, support fixed installation, after mutually block locking device and buckle device again, put into the hexagonal screw head through the hexagonal spanner, and rotate through the hexagonal spanner, make the dwang of recess inboard chamber also rotate, thereby drive the fixture block mechanism on dwang surface and rotate, make fixture block mechanism along with the extruded power, stretch out and draw back in the shrinkage pool inner chamber, and carry out the roll-off in the inner chamber from the shrinkage pool, in the time of the roll-off again, the spring can lose the power of fastening, thereby make the spring drive telescopic link stretch out in sheathed tube inner chamber, the top of telescopic link can drive the expansion plate and stretch out in the inner chamber of recess board simultaneously, the extrusion arc piece that drives the expansion plate top supports in the inner chamber of second circular arc turning bottom, the completion is to the support at second circular arc turning.

Advantageous effects

The invention provides a metal energy-saving roof construction system based on an energy-saving steel structure and a construction method thereof. Compared with the prior art, the method has the following beneficial effects:

1. the energy-saving metal roof construction system based on the energy-saving steel structure and the construction method thereof are characterized in that a first arc corner at the other end of a metal energy-saving roof panel is sleeved on the surface of a third arc corner and is pressed downwards, so that a clamping angle is extruded on the surface of a resisting oblique angle along one end of a second arc corner, the resisting oblique angle can be shifted inwards along with the extrusion of the clamping angle, the clamping angle is clamped on the surface of the resisting oblique angle, meanwhile, the radian in the first arc corner is matched with the radian at the top of the third arc corner, and the third arc corner can be covered when the first arc corner is attached to the top of the third arc corner through a groove on the back of the metal energy-saving roof panel, so that the bottoms between the metal energy-saving roof panel and the metal energy-saving roof panel are flush with each other, and the problem that the metal panel in the metal roof system is formed by the existing steel structure when the metal panel is installed is solved, need overlap the one end of metal decking on the other end, the both ends that overlap each other can lead to the problem of rainwater infiltration to appear in the clearance owing to do not have mutual buckle.

2. This energy-conserving roofing construction system of metal based on energy-conserving formula steel construction and construction method thereof, through handheld straight board, then through the slip of circular arc draw runner at the circular arc spout, make the surface that third circular arc turning is pasting second circular arc turning carry out slight slip, make the straight board laminating on the surface at second circular arc turning, make the bottom laminating of mounting panel on the roof, and make the mounting panel fix through the bolt, can avoid the tradition to need to punch fixedly on the surface of energy-conserving roofing panel of metal, also can prevent to punch and cause the seepage of rainwater.

3. After the locking device and the buckle device are mutually clamped, the hexagonal screw head is put in by the hexagonal wrench and the hexagonal wrench rotates, so that the rotating rod in the inner cavity of the groove plate also rotates, the fixture block mechanism on the surface of the rotating rod is driven to rotate, the fixture block mechanism is made to extend and retract in the inner cavity of the concave hole along with the extrusion force and slide out of the inner cavity of the concave hole, and then the spring loses the fastening force while sliding out, so that the spring drives the telescopic rod to extend out in the inner cavity of the sleeve, meanwhile, the top of the telescopic rod drives the telescopic plate to extend out in the inner cavity of the groove plate, the extrusion arc block at the top of the telescopic plate is driven to abut against the inner cavity at the bottom of the second arc corner, the support of the second arc corner is completed, and the problem that the existing steel structure forms a metal panel in a metal roof system when being installed is solved, one end of the metal panel needs to be sleeved on the other end of the metal panel, but both ends of the metal panel are relatively thin, so that the deformation problem of both ends of the panel can be caused when the metal panel is used for a long time.

4. According to the energy-saving metal roof construction system based on the energy-saving steel structure and the construction method thereof, the fixing mechanism is directly installed on the top of the second arc corner through the mutual sliding sleeve connection between the arc sliding strip and the arc sliding groove, the distance between the surfaces of the second arc corner of the fixing mechanism can be directly determined, and the problem of poor installation in the later period is avoided.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a partial top view of a structural metal energy saving roof panel of the present invention;

FIG. 3 is an enlarged view of a portion of the structure of FIG. 1;

FIG. 4 is an enlarged view of a portion of the structure of FIG. 1 at B;

FIG. 5 is an enlarged view of a portion of the invention shown at C in FIG. 1;

FIG. 6 is a schematic view of a structural attachment mechanism of the present invention;

FIG. 7 is a schematic view of an automatic fastening device of the present invention;

FIG. 8 is a disassembled view of the automatic fastening device of the present invention;

FIG. 9 is an enlarged view of a portion of FIG. 8 showing the structure of the present invention at D;

fig. 10 is a schematic view of the telescoping mechanism of the present invention.

In the figure: 1. a metal energy-saving roof panel; 2. a buckle device; 21. a first arc corner; 22. a snap-in angle; 3. a locking device; 31. a second arc corner; 32. resisting the bevel; 33. a circular arc chute; 34. a fixing mechanism; 341. a straight plate; 342. mounting a plate; 343. a third arc corner; 344. a circular arc slide bar; 4. an automatic fastening device; 41. a groove plate; 42. a hexagonal screw head; 43. a retractable plate; 44. extruding the circular arc block; 45. rotating the rod; 46. a clamping block mechanism; 47. a telescoping mechanism; 471. a sleeve; 472. a telescopic rod; 473. a through groove; 474. concave holes; 475. a spring; 5. and (4) a groove.

Detailed Description

The technical solutions in the embodiments of the present invention are clearly and completely described, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-3, an embodiment of the present invention provides a technical solution: energy-conserving roofing construction system of metal based on energy-conserving formula steel construction, including energy-conserving roofing panel 1 of metal, energy-conserving roofing panel 1's the fixed locking device 3 that is provided with in right side, the fixed buckle device 2 that is provided with in left side of energy-conserving roofing panel 1 of metal, the equal symmetrical fixed recess 5 of seting up in the left back of energy-conserving roofing panel 1 of metal, the equal symmetrical fixed automatic fastener 4 that is provided with in surface on energy-conserving roofing panel 1 right side of metal.

Referring to fig. 4, the locking device 3 includes a second arc corner 31, one end of the second arc corner 31 is fixedly connected with a resisting bevel 32, the surfaces of the second arc corner 31 are symmetrically and fixedly provided with arc chutes 33, and fixing mechanisms 34 are symmetrically slidably sleeved between the arc chutes 33 and the top of the second arc corner 31;

referring to fig. 5, the fastening device 2 includes a first arc corner 21, a fastening angle 22 is fixedly connected to a bottom of the first arc corner 21, radians of the bottom of the first arc corner 21 and a top of the second arc corner 31 are the same, and the fastening angle 22 and the stop bevel 32 are fastened to each other.

Referring to fig. 6, the fixing mechanism 34 includes a straight plate 341, a mounting plate 342 is fixedly connected to a surface of a bottom of the straight plate 341, a third arc corner 343 is fixedly connected to a top of the straight plate 341, arc slider bars 344 are symmetrically and fixedly connected to bottoms of the third arc corner 343, the arc slider bars 344 are symmetrically slidably sleeved in an inner cavity of the arc chute 33, and radians of the bottom of the third arc corner 343 and the top of the first arc corner 21 are the same and are slidably attached to a top of the second arc corner 31.

Referring to fig. 7-9, the automatic fastening device 4 includes a groove plate 41, the inner cavity of the groove plate 41 is symmetrically and fixedly connected with a telescopic mechanism 47, the inner cavity of the groove plate 41 is rotatably sleeved with a rotating rod 45, the top of the telescopic mechanism 47 is fixedly connected with a telescopic plate 43, the top of the telescopic plate 43 is fixedly connected with an extrusion arc block 44, one end of the rotating rod 45 is fixedly connected with a hexagonal screw head 42, the surface of the rotating rod 45 is symmetrically and fixedly connected with a clamping block mechanism 46, the rotating rod 45 passes through the inner cavity of the through groove 473 and is located at the center of the inner cavity of the through groove 473, the port of the clamping block mechanism 46 and the inner cavity of the concave hole 474 slide each other, the hexagonal screw head 42 is rotatably sleeved in the inner cavity of one side of the groove plate 41, the surface of the telescopic plate 43 and the inner cavity of the groove plate 41 are matched each other, the radian of the top of the extrusion arc block 44 is identical to the radian of the bottom of the second arc corner 31, and the top of the pressing arc block 44 presses on the bottom of the second arc corner 31.

In addition, the fixture block mechanism 46 and the telescopic mechanism 47 adopt the same components, and are composed of a sleeve, a telescopic rod and a spring, the only difference is that the port of the telescopic rod is arc-shaped, and when the telescopic rod rotates, the arc-shaped telescopic rod can be stressed by extrusion force, so that the telescopic rod and the spring retract in the inner cavity of the sleeve.

Referring to fig. 10, the telescoping mechanism 47 includes a sleeve 471, a telescopic rod 472 is slidably sleeved in an inner cavity of the sleeve 471, a spring 475 is fixedly connected between a bottom of the telescopic rod 472 and a bottom of the inner cavity of the sleeve 471, a through groove 473 is fixedly formed in a surface of the telescopic rod 472, recessed holes 474 are symmetrically and fixedly formed in inner walls of the through groove 473, bottoms of the sleeve 471 are symmetrically and fixedly fixed on the bottom of the groove plate 41, and tops of the telescopic rods 472 are symmetrically and fixedly connected to the bottom of the telescopic plate 43.

The embodiment of the invention provides a technical scheme that: the energy-saving metal roof system based on the energy-saving steel structure and the energy absorption method comprise the following steps:

s1, mounting the metal panel, firstly placing the metal energy-saving roof panel 1 on one side along with the sequence of the building, then holding the straight plate 341 by hand, then enabling the third arc corner 343 to slightly slide along the surface of the second arc corner 31 by the sliding of the arc-shaped sliding strip 344 in the arc sliding groove 33, enabling the straight plate 341 to be attached to the surface of the second arc corner 31, enabling the bottom of the mounting plate 342 to be attached to the roof, fixing the mounting plate 342 by a bolt, then sleeving the first arc corner 21 at the other end of the metal energy-saving roof panel 1 on the surface of the third arc corner 343, pressing downwards, enabling the clamping angle 22 to be extruded on the surface of the resisting oblique angle 32 along with one end of the second arc corner 31, enabling the resisting oblique angle 32 to be shifted inwards along with the extrusion of the clamping angle 22, enabling the clamping angle 22 to be clamped on the surface of the resisting oblique angle 32, meanwhile, the radian in the first arc corner 21 is matched with the radian at the top of the third arc corner 343, and the third arc corner 343 can be covered when the first arc corner 21 is attached to the top of the third arc corner 343 through the groove 5 on the back of the metal energy-saving roof panel 1, so that the bottoms of the metal energy-saving roof panel 1 and the metal energy-saving roof panel 1 are flush with each other;

s2, support fixed installation, after mutually block locking device 3 and buckle device 2 again, put into hexagonal screw head 42 through the hexagonal spanner, and rotate through the hexagonal spanner, make the dwang 45 of recess board 41 inner chamber also rotate, thereby drive the fixture block mechanism 46 on dwang 45 surface and rotate, make fixture block mechanism 46 along with extruded power, stretch out and draw back in the recess 474 inner chamber, and slide out from the inner chamber of recess 474, when the roll-off again, spring 475 can lose the power of fastening, thereby make spring 475 drive telescopic link 472 stretch out in the inner chamber of sleeve 471, the top of telescopic link 472 can drive expansion plate 43 and stretch out in the inner chamber of recess board 41 simultaneously, the extrusion arc piece 44 that drives expansion plate 43 top supports in the inner chamber of second circular arc turning 31 bottom, accomplish the support to second circular arc turning 31.

And those not described in detail in this specification are well within the skill of those in the art.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. Energy-conserving roofing construction system based on energy-conserving formula steel construction, including energy-conserving roofing panel of metal (1), its characterized in that: a locking device (3) is fixedly arranged on the right side of the metal energy-saving roof panel (1), a buckling device (2) is fixedly arranged on the left side of the metal energy-saving roof panel (1), grooves (5) are symmetrically and fixedly formed in the back face of the left side of the metal energy-saving roof panel (1), and automatic fastening devices (4) are symmetrically and fixedly arranged on the surface of the right side of the metal energy-saving roof panel (1);

the locking device (3) comprises a second arc corner (31), one end of the second arc corner (31) is fixedly connected with a resisting oblique angle (32), arc chutes (33) are symmetrically and fixedly formed in the surface of the second arc corner (31), and fixing mechanisms (34) are symmetrically sleeved between the arc chutes (33) and the top of the second arc corner (31) in a sliding manner;

the buckle device (2) comprises a first arc corner (21), and the bottom of the first arc corner (21) is fixedly connected with a clamping angle (22);

the fixing mechanism (34) comprises a straight plate (341), a mounting plate (342) is fixedly connected to the surface of the bottom of the straight plate (341), a third arc corner (343) is fixedly connected to the top of the straight plate (341), and arc sliding strips (344) are symmetrically and fixedly connected to the bottom of the third arc corner (343).

2. The energy-saving metal roof construction system based on the energy-saving steel structure is characterized in that: automatic fastener (4) are including recess board (41), the equal symmetrical fixedly connected with telescopic machanism (47) in inner chamber of recess board (41), dwang (45) have been cup jointed in the inner chamber rotation of recess board (41), the equal fixedly connected with expansion plate (43) in top of telescopic machanism (47), the top fixedly connected with extrusion arc piece (44) of expansion plate (43), the one end fixedly connected with hexagonal screw head (42) of dwang (45), the equal symmetrical fixedly connected with fixture block mechanism (46) in surface of dwang (45).

3. The energy-saving metal roof construction system based on an energy-saving steel structure is characterized in that: telescopic machanism (47) are including sleeve pipe (471), telescopic link (472) have been cup jointed in the inner chamber slip of sleeve pipe (471), fixedly connected with spring (475) between the bottom of telescopic link (472) and the bottom of sleeve pipe (471) inner chamber, through groove (473) has been seted up to the fixed surface of telescopic link (472), shrinkage pool (474) have been seted up to the equal symmetry of inner wall that leads to groove (473).

4. The energy-saving metal roof construction system based on an energy-saving steel structure is characterized in that: the rotating rod (45) penetrates through the inner cavity of the through groove (473) and is located in the center of the inner cavity of the through groove (473).

5. The energy-saving metal roof construction system based on an energy-saving steel structure is characterized in that: the port of the fixture block mechanism (46) and the inner cavity of the concave hole (474) slide mutually, and the hexagonal screw head (42) is rotatably sleeved in the inner cavity on one side of the groove plate (41).

6. The energy-saving metal roof construction system based on an energy-saving steel structure is characterized in that: the bottoms of the sleeves (471) are symmetrically fixed on the bottom of the groove plate (41), and the tops of the telescopic rods (472) are symmetrically and fixedly connected to the bottom of the telescopic plate (43).

7. The energy-saving metal roof construction system based on an energy-saving steel structure is characterized in that: the surface of the telescopic plate (43) is matched with the inner cavity of the groove plate (41), the radian of the top of the extrusion arc block (44) is identical to that of the bottom of the second arc corner (31), and the top of the extrusion arc block (44) is extruded on the bottom of the second arc corner (31).

8. The energy-saving metal roof construction system based on the energy-saving steel structure is characterized in that: the arc sliding strips (344) are symmetrically sleeved in the inner cavity of the arc sliding groove (33) in a sliding mode, the radians of the bottom of the third arc corner (343) and the top of the first arc corner (21) are identical to each other, and the third arc corner and the first arc corner are attached to the top of the second arc corner (31) in a sliding mode.

9. The energy-saving metal roof construction system based on the energy-saving steel structure is characterized in that: the bottom of the first arc corner (21) and the top of the second arc corner (31) are identical in radian, and the clamping angle (22) and the resisting bevel angle (32) are mutually clamped and connected.

10. The energy-saving metal roof construction system based on an energy-saving steel structure according to any one of claims 1 to 9, wherein: and the energy absorption method comprises the following steps:

s1, mounting the metal panels, firstly placing the metal energy-saving roof panel (1) on one side along with the sequence of the building, then holding the straight plate (341) by hand, then enabling the third arc corner (343) to slightly slide along the surface of the second arc corner (31) by the sliding of the arc sliding strip (344) in the arc sliding chute (33), enabling the straight plate (341) to be attached to the surface of the second arc corner (31), enabling the bottom of the mounting plate (342) to be attached to the roof, enabling the mounting plate (342) to be fixed by bolts, then sleeving the first arc corner (21) at the other end of the metal energy-saving roof panel (1) on the surface of the third arc corner (343) and pressing downwards, enabling the clamping angle (22) to be extruded on the surface of the abutting oblique angle (32) along one end of the second arc corner (31) so as to be extruded along with the clamping angle (22), the blocking bevel (32) can be shifted inwards, so that the clamping angle (22) is clamped on the surface of the blocking bevel (32), the radian of the inner part of the first arc corner (21) is matched with the radian of the top of the third arc corner (343), and the third arc corner (343) can be covered when the first arc corner (21) is attached to the top of the third arc corner (343) through the groove (5) on the back of the metal energy-saving roof panel (1), so that the bottoms of the metal energy-saving roof panel (1) and the metal energy-saving roof panel (1) are flush with each other;

s2, supporting fixed installation, after the locking device (3) and the buckle device (2) are clamped with each other, putting in a hexagonal screw head (42) through a hexagonal wrench, rotating through the hexagonal wrench, enabling a rotating rod (45) of an inner cavity of the groove plate (41) to also rotate, thereby driving a fixture block mechanism (46) on the surface of the rotating rod (45) to rotate, enabling the fixture block mechanism (46) to stretch in the inner cavity of the concave hole (474) along with the extrusion force, sliding out from the inner cavity of the concave hole (474), and enabling a spring (475) to lose fastening force while sliding out, thereby enabling the spring (475) to drive a telescopic rod (472) to stretch out in the inner cavity of a sleeve (471), meanwhile, the top of the telescopic rod (472) can drive a telescopic plate (43) to stretch out in the inner cavity of the groove plate (41), and an extrusion arc block (44) at the top of the telescopic plate (43) is driven to abut against an inner cavity at the bottom of a second arc corner (31), and completing the support of the second arc corner (31).