Guangdong LiYou Steel Structure Engineering Co., Ltd. +8619147784007 liyousteelstructure@outlook.com
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Erection in steel structure is a crucial phase in constructing durable and safe steel buildings. It involves the careful assembly of prefabricated steel components such as beams, columns, trusses, and braces into a stable and reliable framework. Liyou delivers professional erection services that ensure structural integrity, precision alignment, and timely completion. Our expertise allows clients to achieve efficient, safe, and visually appealing steel structures across industrial, commercial, and residential projects.
Accurate Assembly: Ensures precise alignment and structural stability.
Durable & Reliable: Erection techniques preserve the integrity of steel components.
Flexible Solutions: Adaptable to various building types, spans, and heights.
Efficient Construction: Prefabricated components allow faster, cost-effective assembly.
Safety-Oriented: Professional equipment and methods minimize risk on-site.
Material Handling: Supports multiple steel grades and prefabricated components
Assembly Techniques: Customizable methods to suit project size, type, and complexity
Standards Compliance: In line with international steel construction and erection guidelines
Design Flexibility: Supports bespoke layouts, spans, and structural forms
Quality Assurance: Rigorous inspection ensures reliable performance and long-term stability
| Quantity: | |
|---|---|
Steel
Online technical support
Metal Frame School/Classroom Project
Guangdong, China
Industrial Area
3 years
total solution for projects
LYB-001
Metal Frame School/Classroom Project
Industrial
CE Certification
Industrial Commercial
C.Z Shape Steel Channel
Sliding Door
Customized Color
Sandwich Panel Optional
Aluminum Alloy Sliding Window
SAP2000/AutoCAD /PKPM /3D3S/TEKLA
Hot Dip Galvanized
25-60 days
Single item
1X1X1 cm
1.000 kg
PRODUCT SPECIFICATIONS
| No | Components | Specification | ||
| Embedded Parts | ||||
| 1 | Anchor Bolt | M24 | ||
| 2 | High Strength Bolt | M20,10.9S | ||
| 3 | Common Bolt | M16 | ||
| 4 | Galvanized Bolt | M12 | ||
| 5 | Shear Nail | M16 | ||
| 6 | Tir rod | ∅32*2.5 | ||
| Main Steel Structure Parts | ||||
| 1 | Steel Column (Q355B) | H550*300*10*16 | ||
| 2 | Wind Column (Q355B) | H400*220*6*10 | ||
| 3 | Roof Frame Beam (Q355B) | H900~500*220*10*12 H500~650*220*8*12 | ||
| 4 | Crane Beam (Q355B) | H650*320/240*10*16/14 | ||
| 5 | Tie Bar(Q235B) | ∅168*4.0 | ||
| 6 | Horizontal Brace (Q235B) | ∅168*4.0 | ||
| 7 | Column Brace (Q235B) | ∅25 | ||
| 8 | Angle Brace (Q235B) | L63*5.0 | ||
| 9 | Roof Purlin (Galvanized) | Z280*80*20*2.5 | ||
| 10 | Wall Purlin (Galvanized) | C250*75*20*2.5 | ||
| 11 | Connecting Plate | 6mm-30mm | ||
| Other Steel Structure Parts | ||||
| 1 | Roof Panel | 50mm Rock wool Sandwich panel | ||
| 2 | Wall Panel | 50mm Rock wool Sandwich panel | ||
| 3 | Gutter | 2mm Galvanized Steel Plate | ||
| 4 | Down Pipe | PVC160 (Including parts) | ||
| 5 | Trimming | Color steel 0.5mm Gavanized steel panel | ||
The erection of a steel structure involves the assembly and installation of prefabricated steel components on-site. The process typically begins with preparing the foundation, followed by the delivery of steel beams, columns, and other components. Workers then use cranes to lift and position the steel parts according to the design plans. After the frame is in place, additional components such as roof panels, wall cladding, and insulation are installed. The erection process is completed by securing all parts and performing necessary safety checks.
The time required to erect a steel structure depends on the size and complexity of the project. For smaller buildings, the erection can typically be completed in a few weeks, while larger, more complex projects may take several months. The process is generally quicker than traditional construction methods, as most of the components are pre-fabricated off-site, reducing on-site labor time.
Safety is critical during the erection of steel structures. Key safety considerations include:
Proper equipment: Using cranes, scaffolding, and other lifting equipment that meets safety standards.
Fall protection: Workers should wear harnesses and use safety nets or guardrails to prevent falls from heights.
Structural integrity: Ensuring that the foundation and steel frame are securely positioned before further work is done.
Weather conditions: Avoiding erection during bad weather such as high winds, rain, or lightning, which can create unsafe working conditions.
The type of foundation required depends on factors such as the size and load of the structure and local soil conditions. Typically, steel structures require either a concrete slab foundation or deep pier foundation. A qualified structural engineer will determine the appropriate foundation type based on the design of the building and the specific site conditions.
The erection of a steel structure typically requires various types of equipment, including:
Cranes for lifting and positioning steel beams, columns, and other heavy components.
Forklifts and skid steer loaders for handling smaller steel components and materials.
Welding equipment for joining structural parts.
Scaffolding and elevated platforms for workers to access higher parts of the structure.
Leveling tools to ensure the steel frame is correctly aligned during assembly.
Steel is widely used for structural erection because of its strength, durability, and cost-effectiveness. Steel frames can support large loads while remaining lightweight, making it an ideal material for many construction projects. Additionally, steel's flexibility allows for large open spaces without the need for internal columns. Steel structures also have a longer lifespan, require less maintenance, and are resistant to fire, pests, and harsh weather conditions.
Yes, the design of a steel structure can often be customized during the erection phase, especially for projects that involve modular components. While the initial design is usually finalized before construction begins, some flexibility exists to adjust the layout or add features such as windows, doors, and internal walls during the erection process. It's essential to communicate with the project manager or architect to ensure any changes comply with safety standards and regulations.
The erection of a steel structure may present several challenges, including:
Weather conditions: Adverse weather can delay the installation process or create unsafe working conditions.
Coordination of deliveries: Delays in the arrival of prefabricated steel components can hinder progress.
Site access: Limited access to the site for heavy machinery or transport trucks can complicate the erection process.
Worker safety: Ensuring the safety of workers during high-altitude installation and using heavy machinery requires strict safety protocols.
Yes, steel structures can be erected in remote locations, but certain challenges may arise, such as transportation of materials and access for heavy machinery. To facilitate the erection process in these areas, the steel components are often pre-assembled in a factory and shipped to the site. Depending on the location, specialized equipment, such as helicopters or all-terrain cranes, may be required to transport and install the steel parts.
To ensure the erection of a steel structure meets local building codes, it is essential to work with an experienced contractor or structural engineer who is familiar with the area's regulations. They will ensure that the design, materials, and erection process comply with all safety standards, zoning laws, and environmental requirements. Obtaining the necessary permits before construction begins is also critical.
PRODUCT SPECIFICATIONS
| No | Components | Specification | ||
| Embedded Parts | ||||
| 1 | Anchor Bolt | M24 | ||
| 2 | High Strength Bolt | M20,10.9S | ||
| 3 | Common Bolt | M16 | ||
| 4 | Galvanized Bolt | M12 | ||
| 5 | Shear Nail | M16 | ||
| 6 | Tir rod | ∅32*2.5 | ||
| Main Steel Structure Parts | ||||
| 1 | Steel Column (Q355B) | H550*300*10*16 | ||
| 2 | Wind Column (Q355B) | H400*220*6*10 | ||
| 3 | Roof Frame Beam (Q355B) | H900~500*220*10*12 H500~650*220*8*12 | ||
| 4 | Crane Beam (Q355B) | H650*320/240*10*16/14 | ||
| 5 | Tie Bar(Q235B) | ∅168*4.0 | ||
| 6 | Horizontal Brace (Q235B) | ∅168*4.0 | ||
| 7 | Column Brace (Q235B) | ∅25 | ||
| 8 | Angle Brace (Q235B) | L63*5.0 | ||
| 9 | Roof Purlin (Galvanized) | Z280*80*20*2.5 | ||
| 10 | Wall Purlin (Galvanized) | C250*75*20*2.5 | ||
| 11 | Connecting Plate | 6mm-30mm | ||
| Other Steel Structure Parts | ||||
| 1 | Roof Panel | 50mm Rock wool Sandwich panel | ||
| 2 | Wall Panel | 50mm Rock wool Sandwich panel | ||
| 3 | Gutter | 2mm Galvanized Steel Plate | ||
| 4 | Down Pipe | PVC160 (Including parts) | ||
| 5 | Trimming | Color steel 0.5mm Gavanized steel panel | ||
The erection of a steel structure involves the assembly and installation of prefabricated steel components on-site. The process typically begins with preparing the foundation, followed by the delivery of steel beams, columns, and other components. Workers then use cranes to lift and position the steel parts according to the design plans. After the frame is in place, additional components such as roof panels, wall cladding, and insulation are installed. The erection process is completed by securing all parts and performing necessary safety checks.
The time required to erect a steel structure depends on the size and complexity of the project. For smaller buildings, the erection can typically be completed in a few weeks, while larger, more complex projects may take several months. The process is generally quicker than traditional construction methods, as most of the components are pre-fabricated off-site, reducing on-site labor time.
Safety is critical during the erection of steel structures. Key safety considerations include:
Proper equipment: Using cranes, scaffolding, and other lifting equipment that meets safety standards.
Fall protection: Workers should wear harnesses and use safety nets or guardrails to prevent falls from heights.
Structural integrity: Ensuring that the foundation and steel frame are securely positioned before further work is done.
Weather conditions: Avoiding erection during bad weather such as high winds, rain, or lightning, which can create unsafe working conditions.
The type of foundation required depends on factors such as the size and load of the structure and local soil conditions. Typically, steel structures require either a concrete slab foundation or deep pier foundation. A qualified structural engineer will determine the appropriate foundation type based on the design of the building and the specific site conditions.
The erection of a steel structure typically requires various types of equipment, including:
Cranes for lifting and positioning steel beams, columns, and other heavy components.
Forklifts and skid steer loaders for handling smaller steel components and materials.
Welding equipment for joining structural parts.
Scaffolding and elevated platforms for workers to access higher parts of the structure.
Leveling tools to ensure the steel frame is correctly aligned during assembly.
Steel is widely used for structural erection because of its strength, durability, and cost-effectiveness. Steel frames can support large loads while remaining lightweight, making it an ideal material for many construction projects. Additionally, steel's flexibility allows for large open spaces without the need for internal columns. Steel structures also have a longer lifespan, require less maintenance, and are resistant to fire, pests, and harsh weather conditions.
Yes, the design of a steel structure can often be customized during the erection phase, especially for projects that involve modular components. While the initial design is usually finalized before construction begins, some flexibility exists to adjust the layout or add features such as windows, doors, and internal walls during the erection process. It's essential to communicate with the project manager or architect to ensure any changes comply with safety standards and regulations.
The erection of a steel structure may present several challenges, including:
Weather conditions: Adverse weather can delay the installation process or create unsafe working conditions.
Coordination of deliveries: Delays in the arrival of prefabricated steel components can hinder progress.
Site access: Limited access to the site for heavy machinery or transport trucks can complicate the erection process.
Worker safety: Ensuring the safety of workers during high-altitude installation and using heavy machinery requires strict safety protocols.
Yes, steel structures can be erected in remote locations, but certain challenges may arise, such as transportation of materials and access for heavy machinery. To facilitate the erection process in these areas, the steel components are often pre-assembled in a factory and shipped to the site. Depending on the location, specialized equipment, such as helicopters or all-terrain cranes, may be required to transport and install the steel parts.
To ensure the erection of a steel structure meets local building codes, it is essential to work with an experienced contractor or structural engineer who is familiar with the area's regulations. They will ensure that the design, materials, and erection process comply with all safety standards, zoning laws, and environmental requirements. Obtaining the necessary permits before construction begins is also critical.
