CN216075585U - Cantilever broken bridge connecting piece based on double rows of C-shaped steel keel composite walls - Google Patents

Abstract

The utility model discloses an overhanging broken bridge connecting piece in a double-row C-shaped steel keel-based composite wall, which comprises a fourth supporting block, wherein fourth clamping blocks are fixedly arranged on two sides of the fourth supporting block respectively, the fourth clamping blocks are clamped in C-shaped steel, and the fourth supporting block comprises two groups of fourth supporting plates arranged in parallel and a plurality of groups of isolation plates fixedly arranged between the two groups of supporting plates; the angle steel mounting groove has been seted up to infrabasal plate outside bottom, and the C template is at angle steel mounting groove department fixedly connected with mounting panel. According to the cantilever broken bridge connecting piece, the two groups of fourth clamping blocks are supported by the two groups of fourth supporting plates which are arranged in parallel and the plurality of groups of isolation plates which are fixedly arranged between the two groups of supporting plates, and the bottom plate in each fourth clamping block is directly connected with the two groups of supporting plates, so that the overall strength of the cantilever broken bridge connecting piece is improved, the stand column assembly and the cross beam assembly can bear larger loads, the supporting and bearing capacity of the cantilever broken bridge connecting piece is improved, and meanwhile, the energy loss caused by the bottom connecting piece is reduced.

Description

Cantilever broken bridge connecting piece based on double rows of C-shaped steel keel composite walls

Technical Field

The utility model relates to the technical field of composite wall connecting pieces, in particular to a cantilever broken bridge connecting piece based on a double-row C-shaped steel keel composite wall.

Background

With the development trend of the construction industry and the guidance of national policies, fabricated buildings are in a vigorous development stage. The fabricated building is a building which is formed by transferring a large amount of field operation work in the traditional construction mode to a factory, processing and manufacturing building components and accessories such as floor slabs, wall slabs, stairs, balconies and the like in the factory, transporting the components and accessories to a building construction site, and assembling and installing the components and the accessories on the site in a reliable connection mode.

The original building wall is generally built by adopting a single material, such as a brick wall, a hollow block wall, an aerated concrete wall and the like. Because of the requirement of building energy conservation, many single-material walls have too large heat conductivity coefficients and cannot meet the requirements of heat preservation and heat insulation, the composite walls are often formed by compounding bearing materials and high-efficiency heat preservation materials. The existing assembled wall body mostly consists of an inner wall plate, an outer wall plate, a framework layer between the inner wall plate and the outer wall plate and a heat insulation material between the inner wall plate and the outer wall plate, wherein the inner wall plate and the outer wall plate, the framework layer and the heat insulation material are connected through connecting pieces, the connecting pieces are mostly prefabricated bolts, long bolts or reinforcing steel bars and the like, so that more heat bridges are generated, the heat loss is increased, the bottom of the framework layer needs to be fixed with a bottom beam or a floor plate besides bearing larger load, and therefore more situations are that a thickened plate is fixed below the framework layer to improve the bearing capacity of the framework layer, and the heat loss is large.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an overhanging broken bridge connecting piece based on a double-row C-shaped steel keel composite wall, and aims to solve the problems in the prior art.

In order to achieve the purpose, the utility model provides the following scheme: the utility model provides an overhanging broken bridge connecting piece in a double-row C-shaped steel keel-based composite wall, which comprises a fourth supporting block, wherein fourth clamping blocks are fixedly arranged on two sides of the fourth supporting block respectively, the fourth clamping blocks are clamped in C-shaped steel, and the fourth clamping blocks are matched with the inner cavity of the C-shaped steel;

the fourth supporting block comprises two groups of fourth supporting plates which are arranged in parallel and a plurality of groups of isolation plates which are fixedly arranged between the two groups of supporting plates;

the fourth joint piece includes the C template with C shaped steel inner chamber looks adaptation, and is two sets of the fourth backup pad respectively with the tip fixed connection of C template, and two sets of the fourth backup pad with the interior bottom plate fixed connection of C template, the angle steel mounting groove has been seted up to interior bottom plate outside bottom, the C template is at angle steel mounting groove fixedly connected with mounting panel.

Preferably, a fourth arc-shaped mounting groove is formed in the outer side of the inner bottom plate of the C-shaped plate, and the C-shaped plate is fixedly connected with the C-shaped steel through screws.

Preferably, two groups of fourth fixing plates are fixedly connected between the two groups of fourth supporting plates, and the two groups of fourth fixing plates are respectively arranged between the end parts of the two groups of C-shaped plates.

Preferably, the fourth support plate and the isolation plate are provided with a fourth bridge cut-off hole.

Preferably, a plurality of groups of the isolation plates are parallel to each other, and the isolation plates are parallel to the fourth fixing plate.

Preferably, the bottom surfaces of the fourth supporting block and the two groups of fourth clamping blocks are located on the same horizontal plane, the heights of the two groups of fourth clamping blocks are different, and the upper top surfaces of the relatively lower group of fourth clamping blocks and the upper top surface of the fourth supporting block are located on the same inclined plane.

The utility model discloses the following technical effects: according to the cantilever broken bridge connecting piece, the two groups of fourth clamping blocks are supported by the two groups of fourth supporting plates which are arranged in parallel and the plurality of groups of isolation plates which are fixedly arranged between the two groups of supporting plates, and the bottom plate in each fourth clamping block is directly connected with the two groups of supporting plates, so that the overall strength of the cantilever broken bridge connecting piece is improved, the stand column assembly and the cross beam assembly can bear larger loads, the supporting and bearing capacity of the cantilever broken bridge connecting piece is improved, and meanwhile, the energy loss caused by the bottom connecting piece is reduced. The angle steel mounting groove has been seted up to bottom plate outside bottom simultaneously to at this fixedly connected with fourth fixed plate, install the angle steel in the angle steel mounting groove, prevent that the angle steel from protruding, influence the wholeness of assembled composite wall. And the fourth bridge-cut-off holes are formed in the fourth supporting plate and the isolation plate to reduce energy loss generated by the thermal bridge.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic structural view of a cantilever bridge-cut-off connector according to the present invention;

FIG. 2 is a front view of an overhanging bridge-cutoff connector of the present invention;

FIG. 3 is a top view of an overhanging bridge-cutoff connector of the present invention;

FIG. 4 is a side view of the cantilever bridge-cut-off connector of the present invention

FIG. 5 is a schematic view of the assembled composite wall structure of the present invention;

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

FIG. 7 is a schematic view of a windowless skeletal layer structure of the present invention;

FIG. 8 is a schematic view of a windowed framework layer structure of the present invention;

FIG. 9 is a schematic view of a column assembly according to the present invention;

FIG. 10 is a schematic view of a lower node structure of a window frame according to the present invention;

FIG. 11 is a schematic view of a left node structure of a window frame according to the present invention;

FIG. 12 is a schematic view of the top connector of the C-shaped steel of the present invention;

FIG. 13 is a top view of another construction of the C-section top connector of the present invention;

FIG. 14 is a schematic view of the installation structure of the C-shaped steel top connecting piece of the utility model;

FIG. 15 is a schematic structural view of a C-shaped steel connecting member according to the present invention;

FIG. 16 is a side view of a C-section steel coupler of the present invention;

FIG. 17 is another schematic structural view of a C-shaped steel connecting member according to the present invention;

FIG. 18 is a schematic view of the installation structure of the C-shaped steel connecting piece of the present invention;

FIG. 19 is a schematic view showing the structure of a C-shaped sash connector according to the present invention;

FIG. 20 is a top view of the C-shaped sash connector of the present invention;

FIG. 21 is another structural view of the C-shaped sash connector of the present invention;

FIG. 22 is a schematic view showing an installation structure of the C-shaped sash coupling member according to the present invention.

Wherein, 1, C-shaped steel top connecting piece; 101. a first support plate; 102. a first clamping connection plate; 103. a first through hole; 104. a first arc groove; 105. a first mounting hole; 2. c-shaped steel connecting pieces; 201. a second support plate; 202. a second clamping block; 203. a second through hole; 204. a first mounting plate; 205. a second separator; 206. a second side plate; 207. a first reinforcing plate; 208. a second arc-shaped mounting groove; 209. a second reinforcing plate; 210. a second mounting plate; 212. a third reinforcing plate; 213. a second isolation hole; 3. c-shaped steel window frame connecting pieces; 301. a third support plate; 302. a third clamping block; 303. a window frame mounting block; 304. a base plate; 305. a laminate; 306. a third mounting plate; 307. a third fixing plate; 308. a third through hole; 309. a third arc-shaped mounting groove; 310. a third side plate; 311. a third accommodating groove; 312. a third isolation hole; 313. a transition section; 314. a first fixing plate; 4. a cantilever bridge-cutoff connector; 401. a fourth support block; 402. a fourth clamping block; 403. a fourth support plate; 404. a separator plate; 405. c-shaped plates; 406. an inner bottom plate; 407. an angle steel mounting groove; 408. mounting a plate; 409. a fourth arc-shaped mounting groove; 410. a fourth fixing plate; 411. a fourth bridge opening; 5. a column assembly; 501. c-shaped steel; 6. a beam assembly; 601. angle steel; 7. an external wall panel; 8. an inner wall panel; 9. a filling layer; 901. a first insulating layer; 902. a vertical-filament rock wool layer; 10. a window frame; 11. a window sash; 12. an upper fixed beam; 13. a lower fixed cross beam; 14. an upper column assembly; 15. a lower column assembly; 16. a transverse stiffener; 17. inclining the steel belt; 18. a floor slab; 19. i-shaped steel; 20. a first mounting angle steel; 21. a second mounting angle steel; 22. a composite heat-insulating layer; 23. a cement pressure plate; 24. a third mounting angle steel; 25. embedding parts; 26. a second insulating layer; 27. and fourthly, installing angle steel.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the 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.

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in further detail below.

Referring to fig. 1-4, the utility model provides an overhanging broken bridge connector in a double-row C-shaped steel keel composite wall, wherein the overhanging broken bridge connector 4 comprises a fourth supporting block 401, both sides of the fourth supporting block 401 are respectively and fixedly provided with a fourth clamping block 402, the fourth clamping block 402 is clamped in C-shaped steel 501, and the fourth clamping block 402 is matched with the inner cavity of the C-shaped steel 501; the fourth supporting block 401 comprises two groups of fourth supporting plates 403 arranged in parallel and a plurality of groups of isolation plates 404 fixedly arranged between the two groups of supporting plates; fourth joint piece 402 includes the C type board 405 with C shaped steel 501 inner chamber looks adaptation, and two sets of fourth backup pads 403 respectively with the tip fixed connection of C type board 405, and the interior bottom plate 406 fixed connection of two sets of fourth backup pads 403 and C type board 405, angle steel mounting groove 407 has been seted up to interior bottom plate 406 outside bottom, and C type board 405 is at angle steel mounting groove 407 fixedly connected with mounting panel 408. Two sets of fourth fixing plates 410 are fixedly connected between the two sets of fourth supporting plates 403, and the two sets of fourth fixing plates 410 are respectively arranged between the ends of the two sets of C-shaped plates 405.

Because the broken bridge connecting piece 4 of encorbelmenting is fixed to be set up in stand subassembly below, and it carries out fixed connection with stand subassembly and beam assembly respectively, stand subassembly and beam assembly at this place need bear bigger load, so need improve the support bearing capacity of the broken bridge connecting piece 4 of encorbelmenting, support two sets of fourth joint pieces 402 through two sets of parallel arrangement's fourth backup pad 403 and fixed a plurality of groups ' division boards 404 that set up between two sets of backup pads, furthest's improvement encorbelments the whole intensity of broken bridge connecting piece 4. Simultaneously at the bottom of the outside of inner bottom plate 406, angle steel mounting groove 407 has been seted up to fixedly connected with fourth fixed plate 410 here, installs angle steel 601 in angle steel mounting groove 407, prevents that the angle steel from protruding out, influences the wholeness of assembled composite wall.

A fourth arc-shaped mounting groove 409 is formed in the outer side of the inner bottom plate 406 of the C-shaped plate 405, and the C-shaped plate 405 and the C-shaped steel 501 are fixedly connected through screws. A fourth bridge opening 411 is formed on the fourth supporting plate 403 and the isolation plate 404. The plurality of sets of the isolation plates 404 are parallel to each other, and the isolation plates 404 are parallel to the fourth fixing plate 410. The fourth bridge opening 411 is provided in the fourth support plate 403 and the partition plate 404, so that energy transfer caused by a thermal bridge is reduced, and thermal loss is reduced.

The bottom surfaces of the fourth supporting block and the two groups of fourth clamping blocks are located on the same horizontal plane, the heights of the two groups of fourth clamping blocks are different, the upper top surfaces of the relatively low group of fourth clamping blocks and the upper top surfaces of the fourth supporting block are located on the same inclined plane, the size of the fourth supporting block is reduced, and the connection strength of the cantilever broken bridge connecting piece is guaranteed not to be suddenly reduced while the heat loss generated by a heat bridge is reduced.

Referring to fig. 5-22, the overhanging broken bridge connecting piece in the double-row C-shaped steel keel-based composite wall disclosed by the utility model is applied to an assembly type composite wall based on C-shaped steel, and the assembly type composite wall comprises a framework layer, an outer wallboard 7 and an inner wallboard 8 which are arranged at two sides of the framework layer, and a filling layer 9 filled in the framework layer; when assembled composite wall when being the outer wall facade, the unsettled setting of side fascia 7 is in the outside of ground, saves indoor space, carries out fixed connection through the casing ply to the side fascia 7 and the interior wallboard 8 of its inside filling layer and both sides simultaneously to form the support to side fascia 7.

The framework layer comprises a plurality of groups of vertical column assemblies 5 which are longitudinally arranged in parallel, each group of vertical column assembly 5 comprises two groups of C-shaped steel 501 with opposite openings, and a C-shaped steel connecting piece 2, a C-shaped steel top connecting piece 1 and an overhanging broken bridge connecting piece 4 are fixedly connected between the two groups of C-shaped steel 501 in the vertical column assemblies 5; the upper end and the lower end of the C-shaped steel 501 on the same side in different upright post assemblies 5 are respectively and fixedly connected with angle steel 601, and two groups of angle steel 601 on the same end form a beam assembly 6; c shaped steel top connecting piece 1 fixed connection is between two sets of C shaped steel 501 top and two sets of angle steel 601, and the bridge cut-off connecting piece 4 fixed connection that encorbelments is between two sets of C shaped steel 501 bottom and two sets of angle steel 601. Through C shaped steel connecting piece 2 with the inside two sets of C shaped steel 501 fixed connection of stand subassembly, the joint strength of stand subassembly is improved, and through 1 pair 5 tops of stand subassembly and 6 fixed connection of crossbeam subassembly of C shaped steel top connecting piece, through encorbelmenting broken bridge connecting piece 4 with 5 bottoms of stand subassembly and 6 fixed connection of crossbeam subassembly, through multiunit C shaped steel connecting piece 2, C shaped steel top connecting piece 1 and encorbelmenting broken bridge connecting piece 4 with crossbeam subassembly 6 and 5 fixed connection of stand subassembly, when guaranteeing that the casing ply is stable, divide into the casing ply two-layerly again, fill filling layer 9 between two-layer and guarantee the thermal insulation performance of assembled composite wall body.

Further optimization scheme, still include window frame 10 and set up at the inside casement 11 of window frame 10, window frame 10 is fixed to be set up between two sets of adjacent stand subassembly 5, the upper and lower both ends of window frame 10 are provided with upper fixed crossbeam 12 and lower fixed crossbeam 13 respectively, upper fixed crossbeam 12 and lower fixed crossbeam 13 are all fixed to be set up between two sets of stand subassemblies 5 adjacent with window frame 10, upper fixed crossbeam 12 and lower fixed crossbeam 13 are provided with stand subassembly 14 and lower stand subassembly 15 respectively rather than between the adjacent crossbeam subassembly 6, it is provided with a plurality of groups of C shaped steel window frame connecting pieces 3 to fix between two C shaped steel 501 in the stand subassembly 5 adjacent with window frame 10, window frame 10 and C shaped steel window frame connecting piece 3 fixed connection. Go up fixed cross beam 12 and fixed cross beam 13 down through last stand subassembly 14 and stand subassembly 15 respectively and fix and support, thereby it forms the lateral wall support of window frame 10 to set up multiunit C shaped steel window frame connecting piece 3 at two sets of stand subassembly internal fixation adjacent with it, fixes window frame 10 through multiunit C shaped steel window frame connecting piece 3, last fixed cross beam 12 and fixed cross beam 13 down to guarantee window frame 10's stability.

Further optimize the scheme, filling layer 9 is including arranging first heat preservation 901 in the middle and setting up the perpendicular silk rock wool layer 902 in first heat preservation 901 both sides, and perpendicular silk rock wool layer 902 sets up between relative two sets of angle steel 601 from top to bottom, and graphite plate can be chooseed for use in first heat preservation 901, improves the thermal insulation performance of filling layer, also can improve its mechanical strength when perpendicular silk rock wool layer 902 improves the filling layer thermal insulation performance, guarantees the mechanical strength of filling layer.

According to the further optimized scheme, the external wall panel 7 is a cement-based fiberboard, the external wall panel 7 is arranged on the outer side of the angle steel 601, and the external wall panel 7 is fixedly connected with the vertical-filament rock wool layer 902 and the angle steel 601 through fixing nails respectively; interior wallboard 8 is the fine cement board of glass, and the fine cement board of glass bonds with erecting silk rock wool layer 902, wraps up the casing ply through side fascia 7 and interior wallboard 8, when heightening composite wall body aesthetic property, has improved composite wall body's whole mechanical strength.

According to a further optimization scheme, the vertical column assembly further comprises a first reinforcing assembly, the first reinforcing assembly comprises a plurality of groups of transverse reinforcing rods 16 and/or inclined steel strips 17, the transverse reinforcing rods 16 and/or the inclined steel strips 17 are fixedly connected with a plurality of groups of C-shaped steel 501 on the same side in different vertical column assemblies 5, and the inclined steel strips 17 are obliquely arranged on the opening side of the C-shaped steel 501 and fixedly connected with side plates at two ends of the opening side; horizontal stiffener 16 level is arranged and is deviated from opening side's one end and fixed connection with it at C shaped steel 501, transversely fixes the stand subassembly more than two sets of through horizontal stiffener 16, improves the stability of casing ply, through at the inside fixed inclined steel strip 17 that sets up of casing ply, inclined steel strip 17 and C shaped steel 501's flange board fixed connection, when guaranteeing C shaped steel 501's stability, improve whole casing ply's stability

In a further optimized scheme, a floor slab 18 is arranged between the upper and lower adjacent composite walls, and an assembly connecting mechanism is arranged between the floor slab 18 and the lower composite wall; the assembly connection mechanism comprises an I-shaped steel 19 fixedly connected with the floor slab 18, an upper wing plate of the I-shaped steel 19 is fixedly connected with the floor slab 18, a lower wing plate of the I-shaped steel 19 is fixedly connected with a first installation angle steel 20, an angle steel 601 at the upper end of the lower composite wall is fixedly connected with a second installation angle steel 21, and the first installation angle steel 20 and the second installation angle steel 21 are fixedly connected through bolts; a second heat-insulating layer 26 is arranged between the upper wing plate and the lower wing plate of the I-shaped steel 19, and a polyurethane foam plate or a graphite plate is filled between the lower wing plate and the composite wall; a composite heat-insulating layer 22 is arranged on one outdoor side of the I-shaped steel 19 and the floor slab 18, the composite heat-insulating layer 22 is fixedly connected with an upper composite wall and a lower composite wall respectively, a vertical-wire rock wool and a cement pressure plate 23 are fixedly connected to one indoor side of the I-shaped steel 19, and the cement pressure plate 23 is fixedly connected with the floor slab 18 through a third mounting angle steel 24; an embedded part 25 is fixedly arranged in the floor slab 18, and the embedded part 25 is fixedly connected with the upper composite wall through a fourth mounting angle steel 27. In this case, the assembled composite wall is used as an outer wall facade, the outer wall panel 7 and the C-shaped steel 501 on the outdoor side of the framework layer are both suspended on the outer side, and the composite heat-insulating layer 22 isolates structures such as the floor slab 18 from the outdoor space, so that the integrity of the outer wall facade is ensured, and the energy loss generated by a heat bridge formed by the floor slab and the I-shaped steel beam is reduced.

When the assembled composite wall is used as an indoor wallboard, the I-shaped steel 19 can be directly arranged between the floor slab 18 and the composite wall, and the I-shaped steel 19 internally comprises a heat insulation material, a sound insulation material and the like for heat insulation and sound insulation; meanwhile, the composite wall can be directly installed between two adjacent floor slabs 18 and fixed through fixed angle steel.

According to a further optimized scheme, the C-shaped steel top connecting piece 1 comprises a first supporting plate 101 and first clamping plates 102 fixedly arranged on two sides of the first supporting plate 101, and the first supporting plate 101 and the first clamping plates 102 are located in the same plane; the first clamping and connecting plate 102 is clamped in the C-shaped steel 501, and the first clamping and connecting plate 102 is matched with the cross section of the inner cavity of the C-shaped steel 501, so that the C-shaped steel top connecting piece 1 is clamped between the two groups of C-shaped steel 501; a plurality of groups of first through holes 103 are formed in the first support plate 101, so that a thermal bridge formed by the first support plate 101 is blocked, and energy loss is reduced. C shaped steel top connecting piece 1 joint is between two sets of C shaped steel 501 that the opening is relative, and the tip of every group C shaped steel 501 all overlaps and has connect angle steel 601, and angle steel 601 and first joint board 102 pass through bolted connection, and angle steel 601 passes through screw fixed connection with C shaped steel 501.

A first arc groove 104 is symmetrically arranged on one side of each first clamping plate 102, which is far away from the first supporting plate 101, so that the first arc grooves are matched with inward bulges on the bottom plate of the C-shaped steel 501.

Two rows and two columns of four first mounting holes 105 are formed in each first clamping plate 102, so that the angle steel 601 can be fixedly connected with the first clamping plate 102 through screws while thermal bridges are blocked.

The plurality of groups of first through holes 103 are arranged on the same line, the diameter of each first through hole 103 is 14mm, the distance between every two adjacent groups of first through holes 103 is larger than 22mm, heat conduction of a heat bridge is reduced, and meanwhile the strength of the C-shaped steel top connecting piece 1 is guaranteed.

The first clamping plate 102 and the first supporting plate 101 are the same in thickness, the thickness is 5-7mm, the strength of the C-shaped steel top connecting piece 1 is guaranteed, and meanwhile the phenomenon that the heat conductivity of the C-shaped steel top connecting piece 1 is increased suddenly due to the fact that the C-shaped steel top connecting piece 1 is too thick is avoided. The C-shaped steel top connecting piece 1 is an aluminum-zinc-plated steel plate and has better corrosion resistance.

A plurality of groups of the first through holes 103 are arranged in three rows and a plurality of columns, and the upper row and the lower row of the first through holes 103 are symmetrically arranged with the middle row of the first through holes 103; the first through holes 103 in the middle row and the first through holes 103 in the upper row and the lower row are arranged in a staggered mode, the number of the first through holes 103 is increased, a heat bridge formed by the first supporting plate 101 is blocked for multiple times, and energy loss is reduced.

In a further optimized scheme, the C-shaped steel connecting member 2 comprises a second supporting plate 201 and second clamping blocks 202 fixedly arranged at two ends of the second supporting plate 201; the second clamping block 202 is clamped in the C-shaped steel 501, and the second clamping block 202 is matched with the inner cavity of the C-shaped steel 501; the second clamping block 202 comprises a first mounting plate 204 and a second mounting plate 210 which are arranged in parallel, and a second side plate 206 fixedly arranged on two sides of the first mounting plate 204 and the second mounting plate 210, wherein the second side plate 206 is arranged perpendicular to the first mounting plate 204; the second mounting plate 210 is vertically and fixedly connected with the second support plate 201. A second partition plate 205 is fixedly connected between the first mounting plate 204 and the second mounting plate 210, and the second partition plate 205 is respectively and fixedly connected with the two groups of side plates; the second partition 205 is provided with a second isolation hole 213. Two groups of first reinforcing plates 207 are vertically and fixedly connected between the first mounting plate 204 and the second mounting plate 210, and the two groups of first reinforcing plates 207 are respectively arranged on two sides of the second partition plate 205. The second clamping blocks 202 surrounded by the first mounting plate 204, the two sets of second side plates 206 and the second mounting plate 210 contact with the inner cavity wall of the C-shaped steel 501, and support the two sets of C-shaped steel 501 through the two second clamping blocks 202. Four groups of lateral walls of second joint piece 202 all contact with C shaped steel 501, when improving the installation accuracy, because frictional force in the installation, need not artificially fix and can fix a position the installation to it and reduce the installation degree of difficulty.

When only one group of second supporting plates 201 is arranged, the upper and lower sides of the second supporting plates 201 are fixedly connected with second reinforcing plates 209 respectively, and each group of second reinforcing plates 209 is fixedly connected with the first reinforcing plates 207 on the two sides respectively; the second supporting plate 201 and the second reinforcing plate 209 are both provided with a plurality of second through holes 203. The second through hole 203 blocks the generation of a thermal bridge of the C-shaped steel connecting member 2, reducing energy loss. The mechanical strength of the second supporting plate 201 is improved through the two sets of second reinforcing plates 209, and the stability of the C-shaped steel connecting piece 2 is improved.

When the second supporting plates 201 are arranged in parallel, a plurality of groups of third reinforcing plates 212 are fixedly connected between the two groups of second supporting plates 201, and the two groups of second supporting plates 201 are clamped at the opening of the C-shaped steel 501. The overall strength of the C-shaped steel connecting piece is improved through two groups of second supporting plates 201 and a plurality of groups of third reinforcing plates 212 between the two groups of second supporting plates.

In a further optimized scheme, a second arc-shaped mounting groove 208 is formed in the outer side of the first mounting plate 204, and the first mounting plate 204 is fixedly connected with the inner surface of the C-shaped steel 501 through screws.

In a further optimized scheme, the C-shaped steel window frame connecting member 3 comprises a third support plate 301, third clamping blocks 302 fixedly arranged at two ends of the third support plate 301, and a window frame mounting block 303 fixedly connected to the side surface of the third support plate 301;

the third clamping block 302 is clamped in the C-shaped steel 501, and the third clamping block 302 is matched with the inner cavity of the C-shaped steel 501; the third clamping block 302 comprises a bottom plate 304 fixedly connected with the third supporting plate 301, a layered plate 305 is fixedly connected to the middle of the bottom plate 304, third side plates 310 are vertically and fixedly connected to two sides of the layered plate 305, and the third side plates 310 are vertically arranged and fixedly connected with the bottom plate 304; the outer side of the bottom plate 304 is provided with a third arc-shaped mounting groove 309, and the bottom plate 304 is fixedly connected with the inner surface of the C-shaped steel 501 through screws.

The window frame mounting block 303 includes a third mounting plate 306 disposed parallel to the third support plate 301, and a plurality of sets of third fixing plates 307 fixedly connected between the third mounting plate 306 and the third support plate 301, two ends of the third mounting plate 306 are inclined plates, and an opening of the third mounting plate 306 faces the third support plate 301.

The third supporting plate 301 and the third side plate 310 are arranged in parallel, a third receiving groove 311 for receiving the layered plate 305 is formed in the third supporting plate 301, the layered plate 305 is inserted into the third receiving groove 311 and is fixedly connected with the third supporting plate 301, the third supporting plate 301 is fixedly connected with the bottom plate 304, and any two of the bottom plate 304, the third supporting plate 301 and the layered plate 305 are arranged in a mutually perpendicular manner. The third supporting plate 301 is provided with a plurality of third through holes 308.

Two transition sections 313 are symmetrically arranged in the middle of one side of the layered plate 305 departing from the bottom plate 304, the tops of the two transition sections 313 are fixedly connected with the third accommodating groove 311, the two transition sections 313 are arranged at the opening of the C-shaped steel, and the third clamping block 302 is prevented from influencing the C-shaped steel 501 and parts in the installation process. Because the third mounting plate 306 needs to bear load, the overall strength of the C-shaped steel window frame connecting piece 3 needs to be improved, any two of the bottom plate 304, the third supporting plate 301 and the layered plate 305 are vertically and fixedly connected, and the third supporting plate 301 and the layered plate 305 are fixedly clamped, so that the stability of the third supporting plate 301 is improved, and the load of the window frame 10 on the third supporting plate is met. The layered plate 305 has a plurality of third isolation holes 312 to reduce heat loss.

Alternatively, a first fixing plate 314 is fixedly connected between two sets of third side plates 310 in the third clamping block 302, the first fixing plate 314 is arranged in parallel with the bottom plate 304, and the first fixing plate 314 is fixedly connected with the layered plate 305; the two ends of the third support plate 301 and the third mounting plate 306 are respectively fixedly connected with the first fixing plates 314 on the two sets of third clamping blocks 302, the two ends of the third mounting plate 306 are directly fixed on the first fixing plates 314 on the two sets of third clamping blocks 302, the third mounting plate 306 and the third support plate 301 are separated, and the mechanical strength and the stability of the third support plate 301 and the third mounting plate 306 are improved. The layered plate 305 has a plurality of third isolation holes 312.

As shown in fig. 11, the third mounting plate 306 on the mounting block 303 is fixedly connected to the window frame 10 through the mounting bracket, and the periphery of the window frame 10 is not directly fixed to the pillar and beam assemblies, but the window frame 10 is fixed to the pillar assembly through the plurality of C-shaped steel window frame connecting members 3, so as to avoid the thermal bridge generated by directly mounting the window frame 10 on the pillar, thereby generating a greater energy loss. Meanwhile, in the process of installing the window, the window frame 10 is directly fixed with the upright post assemblies and the beam assemblies through the plurality of groups of C-shaped steel window frame connecting pieces 3, the operation is simple, the auxiliary frame is omitted, the installation procedure is simplified, and the efficiency is greatly improved.

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, are merely for convenience of description of the present invention, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present invention.

The above-described embodiments are merely illustrative of the preferred embodiments of the present invention, and do not limit the scope of the present invention, and various modifications and improvements of the technical solutions of the present invention can be made by those skilled in the art without departing from the spirit of the present invention, and the technical solutions of the present invention are within the scope of the present invention defined by the claims.

Claims (6)

1. The utility model provides a broken bridge connecting piece encorbelments based on in double C shaped steel fossil fragments composite wall which characterized in that: the clamping device comprises a fourth supporting block (401), wherein fourth clamping blocks (402) are fixedly arranged on two sides of the fourth supporting block (401) respectively, the fourth clamping blocks (402) are clamped in C-shaped steel (501), and the fourth clamping blocks (402) are matched with the inner cavity of the C-shaped steel (501);

the fourth supporting block (401) comprises two groups of fourth supporting plates (403) which are arranged in parallel and a plurality of groups of isolation plates (404) which are fixedly arranged between the two groups of supporting plates;

fourth joint piece (402) include with C template (405) of C shaped steel inner chamber looks adaptation, two sets of fourth backup pad (403) respectively with the tip fixed connection of C template (405), and two sets of fourth backup pad (403) with interior bottom plate (406) fixed connection of C template (405), angle steel mounting groove (407) have been seted up to interior bottom plate (406) outside bottom, C template (405) locate fixedly connected with mounting panel (408) in angle steel mounting groove (407).

2. The cantilever broken bridge connecting piece based on the double-row C-shaped steel keel composite wall as claimed in claim 1, is characterized in that: a fourth arc-shaped mounting groove (409) is formed in the outer side of an inner bottom plate (406) of the C-shaped plate (405), and the C-shaped plate (405) is fixedly connected with the C-shaped steel (501) through screws.

3. The cantilever broken bridge connecting piece based on the double-row C-shaped steel keel composite wall as claimed in claim 1, is characterized in that: two groups of fourth fixing plates (410) are fixedly connected between the two groups of fourth supporting plates (403), and the two groups of fourth fixing plates (410) are respectively arranged between the end parts of the two groups of C-shaped plates (405).

4. The cantilever broken bridge connecting piece based on the double-row C-shaped steel keel composite wall as claimed in claim 3, is characterized in that: and a fourth bridge opening (411) is formed in the fourth supporting plate (403) and the isolation plate (404).

5. The cantilever broken bridge connecting piece based on double-row C-shaped steel keel composite wall as claimed in claim 4, is characterized in that: the isolation plates (404) are parallel to each other, and the isolation plates (404) and the fourth fixing plate (410) are arranged in parallel.

6. The cantilever broken bridge connecting piece based on the double-row C-shaped steel keel composite wall as claimed in claim 1, is characterized in that: the bottom surfaces of the fourth supporting block (401) and the two groups of fourth clamping blocks (402) are located on the same horizontal plane, the heights of the two groups of fourth clamping blocks (402) are different, and the upper top surfaces of the relatively lower group of fourth clamping blocks (402) and the fourth supporting block (401) are located on the same inclined plane.

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