CN212689354U - A ridge connection structure of thermal insulation panels with strong bearing capacity - Google Patents

Abstract

The utility model relates to a roof ridge connection structure of a thermal insulation panel with strong bearing capacity, and relates to the technical field of roof ridge joint structures. Panel, the first heat preservation panel and the second heat preservation panel are respectively installed on the two installation slopes, the second heat preservation panel is provided with a reinforcing block facing the first heat preservation panel, and the first heat preservation panel is provided with a reinforcing groove for the reinforcing block to be inserted into, The reinforcing block is adapted to the reinforcing groove; the parts of the first heat preservation panel and the second heat preservation panel located above the reinforcing block and the reinforcing groove are provided with a glue coating groove, and the glue coating groove is filled with foam expansion sealant. The utility model solves the problem of easy cracking between the two thermal insulation panels, and has the advantages of enhancing the bearing capacity between the two thermal insulation panels and reducing the foam expansion through the clamping of the reinforcing block and the reinforcing groove and the cooperation with the foam expansion sealant in the glue coating groove. Possible effect of sealant cracking.

Description

Ridge connecting structure of heat preservation panel with strong bearing capacity

Technical Field

The utility model belongs to the technical field of roof ridge connection structure's technique and specifically relates to a roof ridge connection structure of heat preservation panel that bearing capacity is strong is related to.

Background

Roof ridge refers to the roof slope or the top end line of intersection between two opposite sides.

Chinese patent with publication number CN208650372U discloses a ridge connecting structure of a structural heat-insulating roof panel, which comprises two obliquely-cut heat-insulating roof panels and screws arranged on a ridge beam, wherein the two heat-insulating roof panels are connected through an expanded foam sealant, the heat-insulating roof panels comprise an upper surface layer, a core layer and a lower surface layer which are sequentially connected, the upper surface layer and the lower surface layer are both oriented strand boards, and the core layer is a polystyrene foam layer; the screws are vertically inserted into the heat-insulating roof panels and extend into the ridge beams, and the upper layer is covered with roof asphalt felt.

In the scheme, the two oblique heat-insulation roof boards are connected through the expansion foam sealant, and the heat-insulation roof boards are fixed on the ridge beam through the screws, but the expansion foam sealant has weaker load bearing capacity, the screws are easy to age after being used for a long time, the bearing capacity is reduced, and the two heat-insulation roof boards are easy to crack after the screws are aged.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims at providing a heat preservation panel's that bearing capacity is strong ridge connection structure, its have through the joint of boss and strengthening groove and with the gluey cooperation of gluing inslot foam inflation sealed glue, promote the bearing capacity between two heat preservation panels, reduce the sealed possible effect that the condition of ftractureing appears of foam inflation.

The above utility model discloses an above-mentioned utility model purpose can realize through following technical scheme:

a roof ridge connecting structure of a heat insulation panel with strong bearing capacity comprises a cross beam, a first heat insulation panel and a second heat insulation panel, wherein installation inclined planes are symmetrically arranged on the top wall of the cross beam, the first heat insulation panel and the second heat insulation panel are obliquely arranged with each other, the first heat insulation panel and the second heat insulation panel are respectively arranged on the two installation inclined planes, the second heat insulation panel is provided with a reinforcing block facing the first heat insulation panel, a reinforcing groove for the reinforcing block to be clamped in is formed in the first heat insulation panel, and the reinforcing block is matched with the reinforcing groove;

the first heat preservation panel and the second heat preservation panel are located the boss with the rubber coating groove is established to the part of reinforcing groove top, the rubber coating inslot intussuseption is filled with the sealed glue of foam inflation.

Through adopting above-mentioned technical scheme, the cooperation of boss and strengthening groove has increased the contact between first heat preservation panel and second heat preservation panel for the ability that bears the load has been had between the two, and behind the sealed glue of packing foam inflation in the rubber coating groove, the sealed glue of foam inflation expands when solidifying, and the boss supports tightly with the strengthening groove, makes the connection between first heat preservation panel and the second heat preservation panel comparatively reliable, reduces the sealed possibility that the sealed glue of foam inflation appears the fracture condition.

The present invention may be further configured in a preferred embodiment as: the reinforcing blocks are arranged along two side walls in the vertical direction in a relatively inclined mode, and one end, close to the second heat preservation panel, of each reinforcing block is a large end.

Through adopting above-mentioned technical scheme, the bearing capacity between the boss that the cross-section is isosceles trapezoid shape and reinforcing groove is stronger, and compares in the straight flute, isosceles trapezoid's groove is difficult for the fracture.

The present invention may be further configured in a preferred embodiment as: the top ends of the two side walls of the glue coating groove are oppositely arranged in an inclined mode, and an isosceles trapezoid with the large end at the upper portion is formed.

Through adopting above-mentioned technical scheme, isosceles trapezoid's rubber coating groove for sealed glue of foam inflation is from bottom to top measured more and more greatly, and then makes sealed glue of foam inflation to the thrust on both sides, from up grow gradually down, and then cooperates better with first inclined plane and second inclined plane, promotes the connection reliability between first heat preservation panel and the second heat preservation panel.

The present invention may be further configured in a preferred embodiment as: first heat preservation panel with be equipped with respectively on the diapire of second heat preservation panel and supply two the mounting groove that installation inclined plane card was gone into, installation inclined plane with the mounting groove is laminated mutually.

Through adopting above-mentioned technical scheme, the cooperation of mounting groove and installation inclined plane makes first heat preservation panel and second heat preservation panel be difficult for breaking away from with the crossbeam, increases the stability of first heat preservation panel and second heat preservation panel, has restricted the possibility that each heat preservation panel of chain along the incline direction skew of installation inclined plane simultaneously.

The present invention may be further configured in a preferred embodiment as: the first screw and the second screw are respectively driven into the two installation inclined planes, and the first screw and the second screw are respectively vertical to the first heat-preservation panel and the second heat-preservation panel.

Through adopting above-mentioned technical scheme, two installation inclined planes are squeezed into perpendicularly respectively to first screw rod and second screw rod, have restricted two heat preservation panels along crossbeam length direction's skew.

The present invention may be further configured in a preferred embodiment as: the connecting base is embedded in the cross beam, two connecting sleeves are arranged on the connecting base, and the first screw rod and the second screw rod are respectively in threaded connection with the two connecting sleeves.

Through adopting above-mentioned technical scheme, first screw rod and second screw rod respectively with two connecting sleeve threaded connection, cooperation connecting seat for can lock each other between first screw rod and the second screw rod, and then be fixed in on the crossbeam two heat preservation panels.

The present invention may be further configured in a preferred embodiment as: first screw rod the top of second screw rod all is equipped with the pressure head, the diameter of pressure head is 46 millimeters, the diameter of first screw rod is 24 millimeters, the diameter of second screw rod is 16 millimeters, first heat preservation panel with all seted up on the second heat preservation panel and placed the counter bore of pressure head.

Through adopting above-mentioned technical scheme, the pressure head is used for increasing with the area of contact of two insulation panels, promotes insulation panel by fixed reliability, and the counter bore then sinks the pressure head in two insulation panels, reduces the pressure head protrusion and produces the possibility of interfering with other installed parts.

The present invention may be further configured in a preferred embodiment as: the first heat preservation panel and the second heat preservation panel are paved with the same asphalt felt.

By adopting the technical scheme, the asphalt felt has a waterproof effect, and the possibility of water leakage between the first heat-preservation panel and the second heat-preservation panel is reduced.

The present invention may be further configured in a preferred embodiment as: the beam is provided with a structural layer for supporting the first heat-preservation panel and the second heat-preservation panel along the two sides of the beam in the width direction.

Through adopting above-mentioned technical scheme, the structural layer can support first thermal-insulation panel and second thermal-insulation panel.

The present invention may be further configured in a preferred embodiment as: still be equipped with the screed-coat on the roof of structural layer, the screed-coat with first heat preservation panel or second heat preservation panel butt.

Through adopting above-mentioned technical scheme, the unevenness on the reducible structure layer surface of screed-coat is convenient for install first heat preservation panel and second heat preservation panel.

To sum up, the utility model discloses a following at least one useful technological effect:

1. through the arrangement of the reinforcing block, the reinforcing groove and the glue coating groove, the bearing capacity between the two heat preservation panels is improved by utilizing the clamping connection between the reinforcing block and the reinforcing groove and the matching of the reinforcing block and the foam expansion sealant in the glue coating groove, and the possibility of cracking of the foam expansion sealant is reduced;

2. through the setting of first screw rod, second screw rod, connecting sleeve and connecting seat, be fixed in two fixed panels on the crossbeam, reduce two heat preservation panels and produce the possibility of rocking.

Drawings

Fig. 1 is a schematic structural view of the whole body in this embodiment.

Fig. 2 is a sectional structure diagram for embodying the first screw and the second screw in the present embodiment.

In the figure, 1, a cross beam; 11. installing an inclined plane; 2. a first heat-insulating panel; 21. a reinforcing groove; 22. mounting grooves; 23. a first screw; 231. a fixing hole; 24. a pressure head; 241. a hexagonal groove; 3. a second insulation panel; 31. a reinforcing block; 32. gluing a slot; 33. a second screw; 34. a connecting seat; 341. a connecting sleeve; 4. a structural layer; 5. and (4) leveling layer.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Example (b):

referring to fig. 1, for the utility model discloses a roof ridge connection structure of heat preservation panel that bearing capacity is strong, including crossbeam 1, structural layer 4 has all been built along its width direction's both sides to crossbeam 1, plays the bearing effect. And a leveling layer 5 is poured on the structural layer 4, and the surface of the leveling layer 5 is relatively flat. Two installation inclined planes 11 are symmetrically arranged at the top of the cross beam 1, and the tops of the two installation inclined planes 11 are intersected. Install first heat preservation panel 2 and second heat preservation panel 3 on two installation inclined planes 11 respectively, the part of first heat preservation panel 2 and second heat preservation panel 3 and 5 laminates of screed-coat. The first heat preservation panel 2 and the second heat preservation panel 3 are arranged in a beveling way, and the angle between the two is 118 degrees. The first heat preservation panel 2 and the second heat preservation panel 3 are respectively provided with a mounting groove 22 for the mounting inclined plane 11 to be clamped in, so that the two heat preservation panels are not easy to separate from the beam 1. And the tops of the first heat preservation panel 2 and the second heat preservation panel 3 are also paved with felts for water prevention. When the asphalt felt is installed, a layer of cold bottom oil is brushed on the tops of the first heat preservation panel 2 and the second heat preservation panel 3, and the asphalt felt is bonded on the cold bottom oil after the cold bottom oil is solidified.

Referring to fig. 2, a first screw 23 and a second screw 33 are respectively inserted into top walls of the first insulation panel 2 and the second insulation panel 3, and the first screw 23 and the second screw 33 are respectively perpendicular to the first insulation panel 2 and the second insulation panel 3. A connecting seat 34 is embedded in the cross beam 1, two connecting sleeves 341 are integrally formed on the connecting seat 34, and the two connecting sleeves 341 are respectively in threaded connection with the first screw 23 and the second screw 33. Chamfers are respectively arranged at the bottoms of the first screw 23 and the second screw 33, so that the first screw 23 and the second screw 33 can be conveniently inserted into the connecting sleeve 341, when the first screw 23 and the second screw 33 are in threaded connection with the connecting sleeve 341, the first screw 23 and the second screw 33 continuously compress the first heat-preservation panel 2 and the second heat-preservation panel 3, and the first heat-preservation panel 2 and the second heat-preservation panel 3 have certain compressibility, so that the locking of the first screw 23 and the second screw 33 can be ensured to be completed through proper deformation.

The top of first screw rod 23 second screw rod 33 all is equipped with pressure head 24, and the diameter of pressure head 24 is 46 millimeters, and the diameter of first screw rod 23 is 24 millimeters, and the diameter of second screw rod 33 is 16 millimeters, all sets up the counter bore of placing pressure head 24 on first heat preservation panel 2 and the second heat preservation panel 3. The indenter 24 can maintain a large contact area with the first insulation panel 2 or the second insulation panel 3. The top wall of the pressure head 24 is further provided with a hexagonal groove 241 for facilitating the rotation of the first screw 23 and the second screw 33.

Referring to fig. 2, the side wall of the second thermal insulation panel 3 facing the first thermal insulation panel 2 is integrally formed with a reinforcing block 31, the first thermal insulation panel 2 is provided with a reinforcing groove 21 for inserting the reinforcing block 31, and the reinforcing block 31 is matched with the reinforcing groove 21. The reinforcing block 31 is arranged along two side walls in the vertical direction in a relatively inclined manner, and one end close to the second heat preservation panel 3 is a large end.

The glue coating groove 32 has been seted up to the part that first heat preservation panel 2 and second heat preservation panel 3 are located boss 31 and rib groove 21 top, and the top of two lateral walls of glue coating groove 32 inclines to set up back to the other side respectively, forms a main aspects isosceles trapezoid at last, and the glue coating groove 32 intussuseption is filled with the sealed glue of foam inflation.

The implementation process of the embodiment is as follows: when the construction method is used, the structural layer 4 is built, and then the leveling layer 5 is poured on the structural layer 4. The reinforcing block 31 is firstly inserted into the reinforcing groove 21, then the mounting grooves 22 of the first heat-insulating panel 2 and the second heat-insulating panel 3 are sleeved on the mounting inclined plane 11, and at the moment, the parts of the heat-insulating panels are attached to the leveling layer 5. Then, the first screw 23 and the second screw 33 are screwed into the two connecting sleeves 341, respectively, to lock the first thermal insulation panel 2 and the second thermal insulation panel 3. The glue slot 32 is then filled with a foam expansion sealant. And after all the heat preservation panels are paved, paving the asphalt felt on the heat preservation panels.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (10)

1. A ridge connection structure of a thermal insulation panel with a strong bearing capacity, comprising a cross beam (1), and the top wall of the cross beam (1) is symmetrically provided with an installation inclined plane (11), characterized in that: it also includes a mutually beveled setting. A first thermal insulation panel (2) and a second thermal insulation panel (3), the first thermal insulation panel (2) and the second thermal insulation panel (3) are respectively installed on the two installation slopes (11), the The second heat preservation panel (3) is provided with a reinforcing block (31) facing the first heat preservation panel (2), and the first heat preservation panel (2) is provided with a reinforcing groove into which the reinforcing block (31) is inserted. (21), the reinforcing block (31) is adapted to the reinforcing groove (21); The parts of the first heat preservation panel (2) and the second heat preservation panel (3) located above the reinforcement block (31) and the reinforcement groove (21) are provided with a glue application groove (32), and the glue application The groove (32) is filled with foam expansion sealant. 2 . The ridge connection structure of a thermal insulation panel with strong bearing capacity according to claim 1 , wherein the two side walls of the reinforcing block ( 31 ) along the vertical direction are relatively inclined and arranged close to the second thermal insulation panel. 3 . One end of the panel (3) is the big end. 3. The ridge connection structure of a thermal insulation panel with strong bearing capacity according to claim 1, characterized in that: the top ends of the two side walls of the glue coating groove (32) are arranged obliquely opposite to each other, forming a large end Isosceles trapezoid on top. 4. The ridge connection structure of a thermal insulation panel with strong bearing capacity according to claim 1, characterized in that: the bottom walls of the first thermal insulation panel (2) and the second thermal insulation panel (3) are respectively An installation groove (22) into which the two installation inclined surfaces (11) are clamped is provided, and the installation inclined surface (11) is fitted with the installation groove (22). 5. The ridge connection structure of a thermal insulation panel with strong bearing capacity according to claim 1, characterized in that: the top walls of the first thermal insulation panel (2) and the second thermal insulation panel (3) are respectively A first screw (23) and a second screw (33) are inserted, and the first screw (23) and the second screw (33) are respectively driven into the two mounting slopes (11). The first screw (23) and the second screw (33) are respectively perpendicular to the first thermal insulation panel (2) and the second thermal insulation panel (3). 6 . The ridge connection structure of a thermal insulation panel with strong bearing capacity according to claim 5 , wherein a connecting seat ( 34 ) is pre-embedded in the beam ( 1 ), and the connecting seat ( 34 ) is mounted on the connecting seat ( 34 ). 7 . Two connection sleeves (341) are provided, and the first screw rod (23) and the second screw rod (33) are respectively connected with the two connection sleeves (341) by screw thread. 7. The ridge connection structure of a thermal insulation panel with strong bearing capacity according to claim 5, wherein the top of the first screw (23) and the second screw (33) are provided with pressure heads ( 24), the diameter of the pressure head (24) is 46 mm, the diameter of the first screw (23) is 24 mm, the diameter of the second screw (33) is 16 mm, and the first thermal insulation panel (2) and the second heat preservation panel (3) are provided with countersunk holes for placing the pressure head (24). 8. The ridge connection structure of a thermal insulation panel with strong bearing capacity according to claim 1, wherein the first thermal insulation panel (2) and the second thermal insulation panel (3) are laid with the same piece Linoleum. 9 . The ridge connection structure of a thermal insulation panel with strong bearing capacity according to claim 1 , characterized in that: both sides of the beam ( 1 ) along the width direction thereof are provided with a structure for supporting the first thermal insulation panel. 10 . (2) and the structural layer (4) of the second thermal insulation panel (3). 10. The ridge connection structure of a thermal insulation panel with strong bearing capacity according to claim 9, characterized in that: a leveling layer (5) is further provided on the top wall of the structural layer (4), and the leveling layer is (5) Abutting with the first thermal insulation panel (2) or the second thermal insulation panel (3).

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