CN111648492A - Construction method of concealed stone-built wall body with embedded assembly type H-shaped steel framework - Google Patents

Construction method of concealed stone-built wall body with embedded assembly type H-shaped steel framework Download PDF

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CN111648492A
CN111648492A CN202010553925.4A CN202010553925A CN111648492A CN 111648492 A CN111648492 A CN 111648492A CN 202010553925 A CN202010553925 A CN 202010553925A CN 111648492 A CN111648492 A CN 111648492A
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shaped steel
steel
stone
wall body
vertical
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张春涛
朱立
黄春霖
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Southwest University of Science and Technology
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Southwest University of Science and Technology
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    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04BGENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
    • E04B2/00Walls, e.g. partitions, for buildings; Wall construction with regard to insulation; Connections specially adapted to walls
    • E04B2/02Walls, e.g. partitions, for buildings; Wall construction with regard to insulation; Connections specially adapted to walls built-up from layers of building elements
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04BGENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
    • E04B1/00Constructions in general; Structures which are not restricted either to walls, e.g. partitions, or floors or ceilings or roofs
    • E04B1/62Insulation or other protection; Elements or use of specified material therefor
    • E04B1/92Protection against other undesired influences or dangers
    • E04B1/98Protection against other undesired influences or dangers against vibrations or shocks; against mechanical destruction, e.g. by air-raids
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04BGENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
    • E04B2/00Walls, e.g. partitions, for buildings; Wall construction with regard to insulation; Connections specially adapted to walls
    • E04B2/56Load-bearing walls of framework or pillarwork; Walls incorporating load-bearing elongated members
    • E04B2/58Load-bearing walls of framework or pillarwork; Walls incorporating load-bearing elongated members with elongated members of metal
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04HBUILDINGS OR LIKE STRUCTURES FOR PARTICULAR PURPOSES; SWIMMING OR SPLASH BATHS OR POOLS; MASTS; FENCING; TENTS OR CANOPIES, IN GENERAL
    • E04H9/00Buildings, groups of buildings or shelters adapted to withstand or provide protection against abnormal external influences, e.g. war-like action, earthquake or extreme climate
    • E04H9/02Buildings, groups of buildings or shelters adapted to withstand or provide protection against abnormal external influences, e.g. war-like action, earthquake or extreme climate withstanding earthquake or sinking of ground
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04BGENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
    • E04B2/00Walls, e.g. partitions, for buildings; Wall construction with regard to insulation; Connections specially adapted to walls
    • E04B2/02Walls, e.g. partitions, for buildings; Wall construction with regard to insulation; Connections specially adapted to walls built-up from layers of building elements
    • E04B2002/0202Details of connections
    • EFIXED CONSTRUCTIONS
    • E04BUILDING
    • E04BGENERAL BUILDING CONSTRUCTIONS; WALLS, e.g. PARTITIONS; ROOFS; FLOORS; CEILINGS; INSULATION OR OTHER PROTECTION OF BUILDINGS
    • E04B2/00Walls, e.g. partitions, for buildings; Wall construction with regard to insulation; Connections specially adapted to walls
    • E04B2/02Walls, e.g. partitions, for buildings; Wall construction with regard to insulation; Connections specially adapted to walls built-up from layers of building elements
    • E04B2002/0202Details of connections
    • E04B2002/0243Separate connectors or inserts, e.g. pegs, pins or keys

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  • Engineering & Computer Science (AREA)
  • Architecture (AREA)
  • Civil Engineering (AREA)
  • Structural Engineering (AREA)
  • Environmental & Geological Engineering (AREA)
  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Business, Economics & Management (AREA)
  • Emergency Management (AREA)
  • Revetment (AREA)

Abstract

The invention discloses a building method of a hidden stone-built wall body with an embedded assembly type H-shaped steel framework, which comprises the steps of connecting embedded connecting pieces through anchor bolts when the stone wall body is built, vertically placing H-shaped steel A into the embedded connecting pieces and connecting the H-shaped steel A through bolts; then adopting yellow mud to alternately build various stones around the H-shaped steel A to form effective connection with the wall body; meanwhile, the H-shaped steel B is transversely placed at a preset position on the wall body, and the H-shaped steel connecting piece and the vertical H-shaped steel A are connected to form an H-shaped steel framework whole body; and finally, sequentially building the stone wall body to wrap the H-shaped steel member framework in the wall body, and forming the assembled steel framework hidden stone masonry structure house embedded with the H-shaped steel. According to the invention, the ring beam and the constructional column are replaced by the vertical H-shaped steel A and the horizontal H-shaped steel B, so that the construction process of integrally casting the ring beam and the constructional column in situ is omitted, the construction progress is greatly accelerated, the construction period is shortened, the construction quality is ensured, and the overall stability and the anti-seismic performance of the Tibetan stone wall are improved.

Description

Construction method of concealed stone-built wall body with embedded assembly type H-shaped steel framework
Technical Field
The invention belongs to the technical field of building structures, and particularly relates to a construction method of a hidden type stone-built wall body with an embedded assembly type H-shaped steel framework.
Background
The masonry structure is used as a traditional and old building structure form, and is still largely used by village and town residents at present due to the fact that local materials are easily obtained, transportation is convenient, construction is simple and the like. Masonry structures mainly include common sintered brick masonry structures, masonry structures and block masonry structures of other materials. The sintered brick is mainly made of clay, shale and the like by firing, natural rubble blocks or boulders are the main raw materials of the masonry structure, and other block masonry structures can be made of industrial waste materials (slag and the like). Obviously, the masonry structure has a wide material source for a long time and is easy to use locally; meanwhile, the brick, stone or block masonry has good durability, fire resistance and chemical stability, and also has good heat insulation performance; secondly, compared with the reinforced concrete structure, the masonry does not need a template and special mechanical equipment during the building, the template can be saved, the construction period is shortened, and the manufacturing cost is low. Therefore, the masonry structure wall is a good bearing structure and a good enclosure structure, and still occupies an important position in civil building construction of vast rural areas, villages and towns, and even county cities at present. Particularly, a large number of Tibetan rubble masonry structure houses still exist in western Sichuan plateaus and Qinghai-Tibet plateaus, and the Tibetan rubble masonry structure houses are wide in application and long-lasting in history on the Qinghai-Tibet plateaus due to the advantages that the Qinghai-Tibet plateaus are rich in stones, local materials are easy to obtain, severe cold climate in plateau regions is resisted, and the like. The bearing wall body of the Tibetan stone-built building is formed by dry-building of rubble and clay, a plurality of gravel pieces are mixed in the middle of the bearing wall body, yellow mud caulking is adopted, the strength is low, the thickness difference of the caulking is large, and the ring beam and the constructional column adopted by the masonry structure design specification (GB50003-2011) are not adopted for integral reinforcement during building. Meanwhile, the floor system of the Tibetan stone-built building is formed by ramming wood, clay and the like, the integrity of the building is poor, and the stone wall body cannot be effectively horizontally supported during earthquake, so that the out-of-plane damage of the wall body can occur. Although under the action of small earthquake and short-period earthquake, the hidden stone wall dissipates earthquake energy due to the closing and the pulling of the gaps among the blocks, and has certain energy dissipation and shock absorption functions; however, under the action of strong earthquake and long-period earthquake, the hidden stone wall has poor integrity and is easy to damage outside the plane of the wall, so that the wall collapses, and personnel and property loss is caused. Civil buildings collapse in earthquakes occurring in recent years, and the main reason is that the building with the masonry structure is lack of members for restraining excessive deformation of the wall, and the failure of a single wall easily causes the overall collapse. In particular, the Tibetan masonry walls in earthquakes are subject to failure, partial collapse and general collapse due to lack of effective restraint. In recent years, the earthquake resistance of the hidden stone-built building is gradually concerned, and through investigation and structural analysis on earthquake damage of the hidden stone-built building after an earthquake, the improvement of the earthquake resistance of the hidden stone-built building is found to mainly solve the earthquake resistance of the hidden rubble wall, limit overlarge out-of-plane space displacement of rubble blocks of the wall in the earthquake, restrain the generation of out-of-plane dislocation among the rubble blocks, improve the shearing resistance of the rubble wall and the overall stability of a house, and further improve the earthquake resistance of the hidden stone-built building. Meanwhile, the green building and the building industrialization greatly promote the reform of urban building industry, aim at the requirement of novel urbanization construction, and greatly improve or develop a batch of novel construction technologies with land conservation, water conservation, energy conservation, material conservation and environmental protection on the premise of keeping the regional characteristics and national characteristics of the civil building, so that the technical system and product equipment of the civil building in key links of green energy conservation, environmental quality improvement, engineering construction efficiency, quality safety and the like reach the international advanced level; finally, the quality, the energy efficiency and the construction efficiency of civil buildings in various regions are improved, so that large-scale, high-benefit and sustainable development are realized. Meanwhile, the maintenance, the reinforcement, the transformation and other work are carried out on the traditional Tibetan type stone-made house, and the safety and the comfort level of the traditional Tibetan type stone-made building are improved on the premise that the national features and the high-altitude area features of the traditional Tibetan type stone-made building are kept. Therefore, the earthquake-resistant improvement technology and the earthquake-resistant design theory research are developed on the Tibetan plateau rubble masonry structure, the novel earthquake-resistant design technology or theory which is more economical and applicable is provided, and the requirement of novel highland urbanization construction can be well met.
Obviously, the adoption of the ring beam constructional column is the most effective earthquake fortification measure for improving the earthquake resistance of the stone building structure; however, the cast-in-place ring beam constructional column is not beneficial to storing national characteristics and regional features of the Tibetan stone-built building, and meanwhile, the cast-in-place ring beam constructional column can cause serious damage to the ecological environment of a plateau area due to the procedures of on-site formwork erecting, pouring, maintenance and the like. Meanwhile, in view of the overall anti-seismic performance of civil buildings in the Tibetan region, the existing house building process is simple, the farmer and herd living houses in most regions are designed and built according to local house building customs, building materials are made according to local conditions and local materials, raw soil, stone materials and wood materials are used mostly, and the anti-seismic performance is relatively weak. Therefore, on the premise of considering the national characteristics and regional features of the Tibetan region building, the steel structure assembly type building technology is utilized to develop the local industrialized earthquake-resistant technical research aiming at the Tibetan region rubble masonry house, the novel Tibetan rubble wall body building technology is formed, the important significance and the good application prospect are achieved, and the novel Tibetan region rubble wall body building method has great economic value and social benefit for building, reinforcing and maintaining the Tibetan region rubble masonry structure house.
The H-shaped steel is selected to carry out the improvement on the earthquake-resistant construction technology of the Tibetan rubble wall body, because the section shape of the H-shaped steel is similar to that of an H-shaped economic section profile, which is also called universal steel beam, wide-edge (side) I-shaped steel or parallel-flange I-shaped steel and the like, the H-shaped steel can be suitable for different steel structures, and H-shaped steel members show excellent performance no matter bear bending moment, or bear loads such as tension, compression or shearing force. Compared with the common I-shaped steel, the H-shaped steel greatly improves the bearing capacity and saves the steel consumption by 10 to 40 percent. The steel consumption can be saved by 15-20% when the H-shaped steel is used for building the steel truss. Meanwhile, the planes of the inner side and the outer side of the flange of the H-shaped steel are parallel, and the end part of the flange and the joint of the flange and the web are right-angled, so that the H-shaped steel is convenient to assemble and combine into steel members in various shapes, the assembly type construction is convenient, and the construction period is obviously shortened. Therefore, the H-shaped steel combination is selected and applied to the hidden rubble wall to form the assembled integral steel skeleton, and in the rubble wall building, the application of the H-shaped steel avoids the complex procedures of binding a reinforcement cage, manufacturing a template, pouring vibrating concrete and the like in a construction site. The method not only realizes convenient and quick production, transportation and construction and short construction period, but also meets the development strategy requirement of 'novel urban and rural construction in plateau' provided by a Tibetan region for keeping the national characteristics and the landscape of the traditional Tibetan stone-built building, and accords with the sustainable development strategy of green buildings.
Disclosure of Invention
An object of the present invention is to solve at least the above problems and/or disadvantages and to provide at least the advantages described hereinafter.
To achieve these objects and other advantages in accordance with the purpose of the invention, there is provided a method of constructing a concealed type stone-built wall body of an embedded assembly type H-beam framework, comprising the steps of:
firstly, fixing an embedded connecting piece on a barred rock foundation or a cast-in-place ground beam by adopting an anchoring bolt, vertically and horizontally placing H-shaped steel A to the embedded connecting piece, and connecting the H-shaped steel A and the embedded connecting piece by using a bolt to form a column base; building masonry after connection and fixation, building a stone wall around the H-shaped steel A by adopting yellow mud to wrap the H-shaped steel A in the wall, and building the masonry in a staggered manner; meanwhile, a gap between the H-shaped steel A and the stone wall body is densely filled by adopting fine stone concrete, and the building of the first layer of wall body is completed;
step two, two ends of H-shaped steel B are respectively connected with a middle H-shaped steel connecting piece through bolts, the H-shaped steel B is transversely placed on a first layer of wall body, steel plates of the middle H-shaped steel connecting pieces at the two ends are tightly attached to the surface of a flange or a web plate of the H-shaped steel A, two limbs of the middle H-shaped steel connecting piece are fixedly connected with the H-shaped steel A in a bolt connection mode to form a unified whole, then stone wall bodies around the transverse H-shaped steel B are built, the transverse H-shaped steel B is wrapped in the stone wall bodies to form a girt structural column, and fine stone concrete is filled in gaps; and continuously building the stone wall, arranging an H-shaped steel combined steel skeleton at the arrangement position of the ring beam structural column of the subsequent floor according to the building method, and building layer by layer from bottom to top according to the building sequence of the stone masonry structure to form an H-shaped steel combined steel skeleton masonry structure house and form an embedded assembly type H-shaped steel skeleton hidden stone wall structure house, wherein the top layer of the vertical H-shaped steel A adopts a top layer H-shaped steel connecting piece to realize the connection of the vertical H-shaped steel A and the horizontal H-shaped steel B.
Preferably, the masonry of the stone wall body is made of irregular rubbles, the used rubbles are solid in texture and free of weathering and peeling, and the strength grade is not lower than MU 15.
Preferably, the cross-sectional dimension of the H-section steel a is HM200 × 150 × 6 × 9, the cross-sectional dimension of the transverse H-section steel B is HM150 × 100 × 6 × 9, and the flanges and the webs of the H-section steel a and the H-section steel B are provided with bolt holes; the strength grades of the H-shaped steel A and the H-shaped steel B are not lower than Q235.
Preferably, in the second step, the bolt used is a hexagon bolt, the specification is M14, the maximum diameter of the head is 21mm, the maximum thickness of the head is 14mm, and the reference length of the thread is 40 mm.
Preferably, the structure of the embedded connecting piece is consistent with that of the middle H-shaped steel connecting piece; and 8 connecting steel bars with the diameter of 12mm are uniformly distributed and welded in a plane 20mm away from the edge at the lower part of the embedded connecting piece, and the lower ends of the connecting steel bars are bent and bound with the longitudinal bars at the lower part of the cast-in-place ground beam.
Preferably, in the first step, 2 phi 6mm horizontal tie bars are arranged every 500mm along the vertical height and penetrate into the stone wall body for a length of no less than 1000mm, the horizontal tie bars are formed by bending a whole steel bar around a vertical H-shaped steel A, and a steel bar mesh is formed by spot welding or binding transverse phi 4mm short bars among the 2 horizontal tie bars.
Preferably, in the second step, the connection mode of the H-shaped steel combined steel skeleton is suitable for the connection positions of the longitudinal and transverse steel members of the L-shaped corners of the stone wall body, the connection positions of the longitudinal and transverse steel members of the T-shaped corners of the stone wall body, the connection positions of the longitudinal and transverse steel members of the cross-shaped cross of the stone wall body and the connection positions of the longitudinal and transverse steel members of the middle parts of the limbs of the stone wall body, and different stone masonry modes are adopted for the transverse and vertical steel sections.
Preferably, the structure of the middle H-beam connector includes:
the upper part and the lower part of the vertical steel plate A are respectively provided with four bolt holes A so as to be conveniently connected with a flange or a web plate of the H-shaped steel A through bolts; the middle part of the vertical steel plate A is horizontally welded with a parallel transverse steel plate A, and the transverse steel plate A is provided with four bolt holes B so as to be conveniently connected with upper and lower flange bolts of the H-shaped steel B; parallel clamping steel plates A are welded in the middle of the vertical steel plate A and are positioned in the parallel transverse steel plates A; the clamping steel plates A are respectively provided with four bolt holes C so as to be connected with web bolts of the H-shaped steel B conveniently; the clamping steel plate A is respectively vertical to the vertical steel plate A and the transverse steel plate A; two steel rib plates A are welded between the vertical steel plate A and the transverse steel plate A; and two steel rib plates B are welded between the vertical steel plate A and the clamping steel plate A.
Preferably, the structure of the top layer H-shaped steel connecting piece comprises:
the upper part of the vertical steel plate B is provided with two bolt holes D, the lower part of the vertical steel plate B is provided with four bolt holes E, and the bolt holes D, E are in bolt connection with the flange or the web plate of the H-shaped steel A; the middle part of the vertical steel plate B is horizontally welded with a parallel transverse steel plate B, and the transverse steel plate B is provided with four bolt holes F so as to be conveniently connected with upper and lower flange bolts of the H-shaped steel B; parallel clamping steel plates B are welded in the middle of the vertical steel plate B and are positioned in the parallel transverse steel plates B; the clamping steel plates B are respectively provided with four bolt holes G so as to be connected with web bolts of the H-shaped steel B conveniently; the clamping steel plate B is respectively vertical to the vertical steel plate B and the transverse steel plate B; two steel rib plates C are welded between the vertical steel plate B and the transverse steel plate B; and two steel rib plates D are welded between the vertical steel plate B and the clamping steel plate B.
According to the invention, proper H-shaped steel is used as an embedded steel skeleton, and the stone blocks outside the H-shaped steel are directly built with the whole stone wall, so that a template supporting procedure is omitted, meanwhile, yellow mud masonry stones and fine aggregate concrete are used for filling gaps around the vertical H-shaped steel A, so that the vertical H-shaped steel A component is well restrained, the anti-overturning capability is good, the impact resistance is good, the longitudinal and transverse steel components (H-shaped steel A and H-shaped steel B) are connected in a bolt splicing manner to form a unified whole, and the framework for restraining the wall body is formed through the cooperative working capability of the H-shaped steel A and the H-shaped steel B. The invention at least comprises the following beneficial effects:
(1) according to the invention, the ring beam and the constructional column are replaced by the vertical H-shaped steel A component and the horizontal H-shaped steel B component, so that the construction process of integrally cast-in-place ring beam and constructional column concrete is omitted, the concrete curing time is saved, meanwhile, the construction procedures of supporting, dismantling and the like of the ring beam and the constructional column template are also omitted, the construction progress is greatly accelerated, the construction period is shortened, and the construction quality is ensured; (2) the manufacturing cost of steel plates, bolts and the like required by the production of the H-shaped steel and the H-shaped steel connecting piece is low, the steel plates, bolts and the like are all easily obtained materials, the cost of the stone wall structure can be obviously reduced, the section distribution of the H-shaped steel is more optimized, the strength-to-weight ratio is better than that of steel pipes and I-shaped steel, the bending resistance in all directions is stronger, the connector is adopted for welding and is combined with the bolts in a connecting mode, the construction is simple, the welding and assembling workload can be reduced, and the construction cost can be saved; (3) the H-shaped steel is processed in a factory, the construction is rapid, the size of the factory can be adjusted according to the region of a built house during prefabrication, the H-shaped steel is good in reliability, low in cost and excellent in performance, the assembly of a profile steel framework can be carried out simultaneously with the masonry of a stone wall body, the construction procedures are reduced, the construction speed is improved, the H-shaped steel fully exerts the characteristics of multiple specifications, flexibility in use, light weight, high strength and good matching and use with other building materials of the H-shaped steel as a steel structure, the bearing capacity and the anti-seismic performance of a house with a traditional masonry structure can be enhanced, and the defect that the stress concentration phenomenon is caused by uneven shrinkage deformation of the traditional steel-concrete ring beam constructional column is overcome; the method has the characteristics of short construction period, energy conservation, land conservation, material conservation, environmental protection and the like; (4) the invention is beneficial to realizing the modularity of the masonry structure design, the industrialized production and the construction standardization, improving the earthquake resistance of the buildings with the stone wall structures in the Tibetan areas and ensuring the life and property safety of the masses. (5) The earthquake-resistant performance of the traditional Tibetan rubble masonry house is effectively improved on the premise of keeping the national characteristics and the geomorphology of the Tibetan rubble masonry structure house.
Additional advantages, objects, and features of the invention will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the invention.
Description of the drawings:
FIG. 1 is a schematic perspective view of a connecting member of the middle H-section steel of the present invention;
FIG. 2 is a schematic plan view of a connecting member of the middle H-section steel of the present invention;
FIG. 3 is a schematic perspective view of a top H-beam connector according to the present invention;
FIG. 4 is a schematic plan view of the top H-beam connector of the present invention;
FIG. 5 is a schematic view showing the connection of longitudinal and transverse H-shaped steel members at the cross of the stone wall according to the present invention;
FIG. 6 is a schematic view showing the connection of longitudinal and transverse H-shaped steel members at the corner of the T-shaped wall of the stone wall body;
FIG. 7 is a schematic view showing the connection of longitudinal and transverse H-shaped steel members at the middle of the stone wall limbs according to the present invention;
FIG. 8 is a schematic connecting view of longitudinal and transverse H-shaped steel members at the corners of a stone wall body L in the invention;
FIG. 9 is a schematic view showing the connection of the cross H-shaped steel members at the cross of the top stone wall in the present invention;
FIG. 10 is a schematic view showing the connection of the vertical and horizontal H-shaped steel members at the T-shaped wall corner of the top stone wall in the present invention;
FIG. 11 is a schematic view showing the connection of longitudinal and transverse H-shaped steel members at the middle of the top stone wall limbs in the present invention;
FIG. 12 is a schematic view showing the connection of the vertical and horizontal H-shaped steel members at the corners of the top stone wall body L in the present invention;
FIG. 13 is a schematic view of a method of stone masonry in accordance with the present invention applied to vertical H-section steel of masonry wall;
FIG. 14 is a schematic view of the method of the present invention for laying stone blocks on the transverse H-section steel of the masonry wall;
FIG. 15 is a schematic structural view of a stone foundation or a cast-in-place ground beam of the present invention with an anchor bolt for fixing a pre-buried connector;
FIG. 16 is a schematic top view of the stone foundation or the cast-in-place ground beam of the present invention with the anchor bolts used to fix the pre-buried connectors;
fig. 17 is a schematic view of the assembly of the concealed stone wall with the embedded assembly type H-shaped steel framework.
The specific implementation mode is as follows:
the present invention is further described in detail below with reference to the attached drawings so that those skilled in the art can implement the invention by referring to the description text.
It will be understood that terms such as "having," "including," and "comprising," as used herein, do not preclude the presence or addition of one or more other elements or groups thereof.
Example 1:
a building method of a hidden type stone-built wall body with an embedded assembly type H-shaped steel framework comprises the following steps:
step one, as shown in fig. 1-17, fixing an embedded connecting piece 3 on a stone slab foundation or a cast-in-place ground beam 1 by using an anchor bolt 2, vertically and horizontally placing H-shaped steel A4 with the model of HM200 x 150 on the embedded connecting piece 3, and connecting the H-shaped steel A and the embedded connecting piece by using a bolt to form a column base; the masonry is constructed after connection and fixation, stones around the vertical H-shaped steel A are constructed in a mode of mixing rubbles and rubbles, the vertical H-shaped steel A is connected with the stone wall 7, the rubbles which are approximately square, smooth on two sides and suitable in size are placed around the vertical H-shaped steel A in parallel to the flange of the section steel, the thickness of the rubbles is preferably 3-8mm, the length and the width are 20-40cm, small stones are filled between the rubbles and filled with high-viscosity loess, the H-shaped steel A is wrapped in the wall body by constructing the stone wall body around the H-shaped steel A by adopting high-viscosity loess, a stone masonry column is formed, and the stone masonry is constructed in a staggered mode and effectively connected with the stone wall 7; the gap between the H-shaped steel A and the stone wall body is densely filled with fine stone concrete, so that the connection between the H-shaped steel A and the stone wall body is increased, the cooperative working capacity is improved, the H-shaped steel A component can be protected from being corroded, and a stone masonry column wrapping the H-shaped steel A is formed; finishing the building of the first layer of wall;
step two, when a first layer of wall body is built, two ends of H-shaped steel B8 with the model of HM150 multiplied by 100 are respectively fixed with a middle H-shaped steel connecting piece 9 through bolts, the H-shaped steel B8 is transversely placed on the first layer of wall body, steel plates of the middle H-shaped steel connecting piece 9 at the two ends are tightly attached to the surface of a flange or a web plate of the H-shaped steel A4, two limbs (parallel transverse steel plates) of the middle H-shaped steel connecting piece 9 are fixedly connected with the H-shaped steel A4 in a bolt connection mode to form a unified whole, then stone wall bodies around the transverse H-shaped steel B8 are built, a mixed building method of rubble stones is also adopted around the transverse H-shaped steel B8, rubble stones with the thicknesses of 3-5mm are placed on upper and lower flanges of the section steel, then the rubble stones are placed on the rubble stones and placed at the positions of gaps of the web plate of the section steel, the thicknesses of the middle rub, filling and compacting gaps between the profile steel members and the rubble sheets by using fine aggregate concrete, wrapping the transverse H-shaped steel B in the stone wall body to form a ring beam construction column, and filling the gaps with the fine aggregate concrete; continuously building a stone wall, arranging an H-shaped steel combined steel skeleton at the arrangement position of a ring beam constructional column of a subsequent floor according to the building method, building layer by layer from bottom to top according to the building sequence of the stone masonry structure to form an H-shaped steel combined steel skeleton masonry structure house, and forming an embedded assembly type H-shaped steel skeleton hidden stone masonry wall structure house, wherein the top layer of vertical H-shaped steel A adopts a top layer H-shaped steel connecting piece 10 to realize the connection of vertical H-shaped steel A and transverse H-shaped steel B, the thickness of the built wall is not less than 350mm at the first layer, the thickness of the second layer of wall is about 300mm, and the thickness of the top layer of wall is 250 mm;
the masonry of the stone wall body is made of irregular rubbles with different sizes, the used rubbles are solid in texture and free of weathering and peeling, and the strength grade is not lower than MU 15;
the section size of the H-shaped steel A is HM200 multiplied by 150 multiplied by 6 multiplied by 9, the section size of the transverse H-shaped steel B is HM150 multiplied by 100 multiplied by 6 multiplied by 9, and bolt holes are arranged on flanges and webs of the H-shaped steel A and the H-shaped steel B; the strength grades of the H-shaped steel A and the H-shaped steel B are not lower than Q235;
in the second step, the adopted bolt is a hexagon bolt with the specification of M14, the maximum diameter of the head is 21mm, the maximum thickness of the head is 14mm, and the reference length of the thread is 40 mm;
the structure of the embedded connecting piece is consistent with that of the middle H-shaped steel connecting piece; uniformly distributing and welding 8 phi 12mm connecting steel bars in a plane 20mm away from the edge at the lower part of the embedded connecting piece, and bending the lower ends of the connecting steel bars to be bound and connected with longitudinal bars at the lower part of the cast-in-place ground beam (not shown);
in the first step, 2 phi 6mm horizontal tie bars are arranged every 500mm along the vertical height and penetrate into the stone wall body for at least 1000mm, the horizontal tie bars are formed by bending a whole bar around a vertical H-shaped steel A, and a transverse phi 4mm short bar is spot-welded or bound among the 2 horizontal tie bars to form a steel bar mesh;
in the second step, as shown in fig. 5-12, the H-shaped steel combined steel skeleton connecting mode is suitable for the joints of the longitudinal and transverse steel members of the L-shaped corners of the stone wall body, the joints of the longitudinal and transverse steel members of the T-shaped corners of the stone wall body, the joints of the longitudinal and transverse steel members of the cross stone wall body and the joints of the longitudinal and transverse steel members of the middle parts of the wall limbs of the stone wall body, and different stone masonry modes are adopted for the transverse and vertical steel sections.
The structure of the middle H-shaped steel connecting piece 9 comprises:
the upper part and the lower part of the vertical steel plate A90 are provided with four bolt holes A91 so as to be conveniently connected with a flange or a web plate of the H-shaped steel A through bolts; the middle part of the vertical steel plate A90 is horizontally welded with a parallel transverse steel plate A92, and the transverse steel plate A92 is provided with four bolt holes B93 so as to be conveniently connected with upper and lower flanges of the H-shaped steel B; parallel clamping steel plates A94 are welded in the middle of the vertical steel plate A90, and the parallel clamping steel plates A94 are located in parallel transverse steel plates A92; the clamping steel plates A94 are respectively provided with four bolt holes C95 so as to be connected with web bolts of the H-shaped steel B conveniently; the clamping steel plate A94 is respectively vertical to the vertical steel plate A90 and the horizontal steel plate A92; two steel rib plates A96 are welded between the vertical steel plate A90 and the transverse steel plate A92; two steel rib plates B97 are welded between the vertical steel plate A90 and the clamping steel plate A94; the four bolt holes A of the vertical steel plate A are matched and connected with the bolt holes on the flange and the web plate of the vertical H-shaped steel A through hexagon bolts; the four bolt holes B of the transverse steel plate A are matched and connected with the bolt holes on the flange of the transverse H-shaped steel B through hexagon bolts; the web plate of the transverse H-shaped steel B is inserted between the parallel clamping steel plates A, and the four bolt holes C are matched and connected with the bolt holes of the web plate of the H-shaped steel B through hexagon bolts; by adopting the connection mode, the H-shaped steel combined steel skeleton is formed;
in the invention, the structures of the embedded connecting piece and the middle H-shaped steel connecting piece are consistent, namely the embedded connecting piece is horizontally placed on the barred rock foundation or the cast-in-place ground beam in the using process, four bolt holes A91 at the upper part and the lower part of the vertical steel plate A90 are fixedly connected with the barred rock foundation or the cast-in-place ground beam through anchor bolts, and the flange of the vertical H-shaped steel A is respectively connected with the transverse steel plate A92 through four bolt holes B93 through bolts; the web of the vertical H-section steel a is inserted into the parallel clamping steel plate a 94 and fixed by bolts.
The structure of the top layer H-shaped steel connecting piece 10 comprises:
the upper part of the vertical steel plate B100 is provided with two bolt holes D101, the lower part of the vertical steel plate B is provided with four bolt holes E102, and the bolt holes D, E are in bolt connection with the flange or the web plate of the H-shaped steel A; the middle part of the vertical steel plate B100 is horizontally welded with a parallel transverse steel plate B103, and the transverse steel plate B103 is provided with four bolt holes F104 so as to be conveniently connected with upper and lower flanges of the H-shaped steel B through bolts; parallel clamping steel plates B105 are welded in the middle of the vertical steel plate B100, and the parallel clamping steel plates B105 are positioned in parallel transverse steel plates B103; the clamping steel plates B105 are respectively provided with four bolt holes G106 so as to be connected with web bolts of the H-shaped steel B conveniently; the clamping steel plate B105 is respectively vertical to the vertical steel plate B100 and the horizontal steel plate B103; two steel ribs C107 are welded between the vertical steel plate B100 and the transverse steel plate B103; two steel rib plates D108 are welded between the vertical steel plate B100 and the clamping steel plate B105. The four bolt holes D and the two bolt holes E of the vertical steel plate B are matched and connected with the bolt holes in the flange and the web plate of the vertical H-shaped steel A through hexagon bolts; the four bolt holes F of the transverse steel plate B are matched and connected with the bolt holes on the flange of the transverse H-shaped steel B through hexagon bolts; the web plate of the transverse H-shaped steel B is inserted between the parallel clamping steel plates B, and the four bolt holes G are matched and connected with the bolt holes of the web plate of the H-shaped steel B through hexagon bolts; by adopting the connecting mode, the H-shaped steel combined steel skeleton is formed.
While embodiments of the invention have been described above, it is not limited to the applications set forth in the description and the embodiments, which are fully applicable in various fields of endeavor to which the invention pertains, and further modifications may readily be made by those skilled in the art, it being understood that the invention is not limited to the details shown and described herein without departing from the general concept defined by the appended claims and their equivalents.

Claims (9)

1. A building method of a hidden type stone-built wall body with an embedded assembly type H-shaped steel framework is characterized by comprising the following steps:
firstly, fixing an embedded connecting piece on a barred rock foundation or a cast-in-place ground beam by adopting an anchoring bolt, vertically and horizontally placing H-shaped steel A to the embedded connecting piece, and connecting the H-shaped steel A and the embedded connecting piece by using a bolt to form a column base; building masonry after connection and fixation, building a stone wall around the H-shaped steel A by adopting yellow mud to wrap the H-shaped steel A in the wall, and building the masonry in a staggered manner; meanwhile, a gap between the H-shaped steel A and the stone wall body is densely filled by adopting fine stone concrete, and the building of the first layer of wall body is completed;
step two, two ends of H-shaped steel B are respectively connected with a middle H-shaped steel connecting piece through bolts, the H-shaped steel B is transversely placed on a first layer of wall body, steel plates of the middle H-shaped steel connecting pieces at the two ends are tightly attached to the surface of a flange or a web plate of the H-shaped steel A, two limbs of the middle H-shaped steel connecting piece are fixedly connected with the H-shaped steel A in a bolt connection mode to form a unified whole, then stone wall bodies around the transverse H-shaped steel B are built, the transverse H-shaped steel B is wrapped in the stone wall bodies to form a girt structural column, and fine stone concrete is filled in gaps; and continuously building the stone wall, arranging an H-shaped steel combined steel skeleton at the arrangement position of the ring beam structural column of the subsequent floor according to the building method, and building layer by layer from bottom to top according to the building sequence of the stone masonry structure to form an H-shaped steel combined steel skeleton masonry structure house and form an embedded assembly type H-shaped steel skeleton hidden stone wall structure house, wherein the top layer of the vertical H-shaped steel A adopts a top layer H-shaped steel connecting piece to realize the connection of the vertical H-shaped steel A and the horizontal H-shaped steel B.
2. The method for constructing the concealed stone-built wall body with the embedded assembly type H-shaped steel skeleton according to claim 1, wherein the stone wall body is built by adopting rubbles with different sizes and irregularities, and the rubbles are firm and have no efflorescence and strength grade of not less than MU 15.
3. The method for constructing the concealed masonry wall with the embedded assembly type H-shaped steel framework as claimed in claim 1, wherein the cross-sectional dimension of the H-shaped steel A is HM200 x 150 x 6 x 9, the cross-sectional dimension of the transverse H-shaped steel B is HM150 x 100 x 6 x 9, and bolt holes are formed on the flanges and the webs of the H-shaped steel A and the H-shaped steel B; the strength grades of the H-shaped steel A and the H-shaped steel B are not lower than Q235.
4. The method for constructing the concealed stone-built wall body with the embedded assembly type H-shaped steel skeleton according to claim 1, wherein in the second step, the adopted bolt is a hexagon bolt with the specification of M14, the maximum diameter of the head part is 21mm, the maximum thickness of the head part is 14mm, and the reference length of the thread is 40 mm.
5. The method for constructing the concealed stone-built wall body with the embedded assembly type H-shaped steel framework as claimed in claim 1, wherein the embedded connecting piece is consistent with the middle H-shaped steel connecting piece in structure; and 8 connecting steel bars with the diameter of 12mm are uniformly distributed and welded in a plane 20mm away from the edge at the lower part of the embedded connecting piece, and the lower ends of the connecting steel bars are bent and bound with the longitudinal bars at the lower part of the cast-in-place ground beam.
6. The method for constructing the concealed masonry wall body with the embedded assembly type H-shaped steel skeleton according to claim 1, wherein in the first step, 2 phi 6mm horizontal tie bars are arranged every 500mm along the vertical height and penetrate into the stone wall body for at least 1000mm, the horizontal tie bars are formed by bending a whole bar around a vertical H-shaped steel A, and transverse phi 4mm short bars are spot-welded or bound among the 2 horizontal tie bars to form a steel bar mesh.
7. The method for constructing the concealed masonry wall body with the embedded assembly type H-shaped steel skeleton according to claim 1, wherein in the second step, the connection mode of the H-shaped steel combined steel skeleton is suitable for the connection of longitudinal and transverse steel members at the L-shaped corners of the masonry wall body, the connection of longitudinal and transverse steel members at the T-shaped corners of the masonry wall body, the connection of longitudinal and transverse steel members at the cross of the masonry wall body and the connection of longitudinal and transverse steel members at the middle parts of the limbs of the masonry wall body, and different stone masonry modes are adopted for the transverse and vertical steel parts.
8. The method for constructing a hidden type masonry wall with an embedded assembly type H-shaped steel framework as claimed in claim 1, wherein the structure of the middle H-shaped steel connecting piece comprises:
the upper part and the lower part of the vertical steel plate A are respectively provided with four bolt holes A so as to be conveniently connected with a flange or a web plate of the H-shaped steel A through bolts; the middle part of the vertical steel plate A is horizontally welded with a parallel transverse steel plate A, and the transverse steel plate A is provided with four bolt holes B so as to be conveniently connected with upper and lower flange bolts of the H-shaped steel B; parallel clamping steel plates A are welded in the middle of the vertical steel plate A and are positioned in the parallel transverse steel plates A; the clamping steel plates A are respectively provided with four bolt holes C so as to be connected with web bolts of the H-shaped steel B conveniently; the clamping steel plate A is respectively vertical to the vertical steel plate A and the transverse steel plate A; two steel rib plates A are welded between the vertical steel plate A and the transverse steel plate A; and two steel rib plates B are welded between the vertical steel plate A and the clamping steel plate A.
9. The method for constructing the concealed masonry wall with the embedded assembly type H-shaped steel framework as claimed in claim 1, wherein the structure of the top layer H-shaped steel connecting piece comprises:
the upper part of the vertical steel plate B is provided with two bolt holes D, the lower part of the vertical steel plate B is provided with four bolt holes E, and the bolt holes D, E are in bolt connection with the flange or the web plate of the H-shaped steel A; the middle part of the vertical steel plate B is horizontally welded with a parallel transverse steel plate B, and the transverse steel plate B is provided with four bolt holes F so as to be conveniently connected with upper and lower flange bolts of the H-shaped steel B; parallel clamping steel plates B are welded in the middle of the vertical steel plate B and are positioned in the parallel transverse steel plates B; the clamping steel plates B are respectively provided with four bolt holes G so as to be connected with web bolts of the H-shaped steel B conveniently; the clamping steel plate B is respectively vertical to the vertical steel plate B and the transverse steel plate B; two steel rib plates C are welded between the vertical steel plate B and the transverse steel plate B; and two steel rib plates D are welded between the vertical steel plate B and the clamping steel plate B.
CN202010553925.4A 2020-06-17 2020-06-17 Construction method of concealed stone-built wall body with embedded assembly type H-shaped steel framework Pending CN111648492A (en)

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CN111749343A (en) * 2020-07-15 2020-10-09 湖南轻宅信息科技有限公司 Mounting method of detachable assembled steel structure house
CN112324159A (en) * 2020-11-12 2021-02-05 长安大学 Assembling method for H-shaped steel combined special-shaped beam column steel frame structure
CN113137404A (en) * 2021-04-25 2021-07-20 湖南华鑫美好公路环境建设有限公司 Mounting structure and mounting method of jet fan
CN114961104A (en) * 2022-05-21 2022-08-30 上海宝冶集团有限公司 Construction structure and construction method for I-shaped steel replacing constructional column
IT202100023633A1 (en) * 2021-09-14 2023-03-14 Matteo Mattei STRUCTURE FITTING
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Publication number Priority date Publication date Assignee Title
CN111749343A (en) * 2020-07-15 2020-10-09 湖南轻宅信息科技有限公司 Mounting method of detachable assembled steel structure house
CN112324159A (en) * 2020-11-12 2021-02-05 长安大学 Assembling method for H-shaped steel combined special-shaped beam column steel frame structure
CN113137404A (en) * 2021-04-25 2021-07-20 湖南华鑫美好公路环境建设有限公司 Mounting structure and mounting method of jet fan
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CN114961104A (en) * 2022-05-21 2022-08-30 上海宝冶集团有限公司 Construction structure and construction method for I-shaped steel replacing constructional column
CN114961104B (en) * 2022-05-21 2024-04-16 上海宝冶集团有限公司 I-steel substituted constructional column construction structure and construction method
CN116180976A (en) * 2023-04-25 2023-05-30 石家庄铁道大学 Assembled building wall and construction method

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