Services

 
1. Purpose:
Corrosion protection in steel fabrication is implemented to prevent or minimize the degradation of steel components due to environmental factors, primarily corrosion.

2. Common Methods:
Painting: Application of protective coatings, such as primers and topcoats, to create a barrier between the steel surface and the surrounding environment.
Galvanization: Immersion of steel components in molten zinc to form a protective zinc coating, providing enhanced corrosion resistance.

3. Surface Preparation:
Proper surface preparation, including cleaning and removal of contaminants, is crucial before applying protective coatings to ensure adhesion and effectiveness.

4. Quality Standards:
Adherence to industry standards and specifications for corrosion protection, such as those provided by organizations like the American Institute of Steel Construction (AISC).
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1. Purpose:
Corrosion protection in steel fabrication is implemented to prevent or minimize the degradation of steel components due to environmental factors, primarily corrosion.

2. Common Methods:
Painting: Application of protective coatings, such as primers and topcoats, to create a barrier between the steel surface and the surrounding environment.
Galvanization: Immersion of steel components in molten zinc to form a protective zinc coating, providing enhanced corrosion resistance.

3. Surface Preparation:
Proper surface preparation, including cleaning and removal of contaminants, is crucial before applying protective coatings to ensure adhesion and effectiveness.

4. Quality Standards:
Adherence to industry standards and specifications for corrosion protection, such as those provided by organizations like the American Institute of Steel Construction (AISC).
 
1. Definition:
Site erected work in steel fabrication involves the on-site assembly and installation of fabricated steel components to create the final structure. This is a critical phase in the construction process.

2. Transportation:
Fabricated steel components, such as beams, columns, and trusses, are transported to the construction site from the fabrication shop.

3. Erection Sequence:
The on-site assembly follows a carefully planned erection sequence to ensure the safe and efficient installation of structural steel elements.

4. Rigging and Lifting:
Rigging equipment and cranes are used to lift and position steel components into their designated locations. Rigging plans are developed to ensure safe lifting operations.

5. Connection Detailing:
On-site welders or bolting crews connect the steel components according to detailed connection specifications, ensuring structural stability.
...
1. Definition:
Site erected work in steel fabrication involves the on-site assembly and installation of fabricated steel components to create the final structure. This is a critical phase in the construction process.

2. Transportation:
Fabricated steel components, such as beams, columns, and trusses, are transported to the construction site from the fabrication shop.

3. Erection Sequence:
The on-site assembly follows a carefully planned erection sequence to ensure the safe and efficient installation of structural steel elements.

4. Rigging and Lifting:
Rigging equipment and cranes are used to lift and position steel components into their designated locations. Rigging plans are developed to ensure safe lifting operations.

5. Connection Detailing:
On-site welders or bolting crews connect the steel components according to detailed connection specifications, ensuring structural stability.
 
1. Definition:
Structural steelwork involves the fabrication and assembly of steel components used in the construction of buildings, bridges, and other structures. It provides the framework that supports the load-bearing elements of a construction project.

2. Materials:
Primary material is structural steel, typically hot-rolled steel sections like beams, columns, and channels. The choice of steel grade depends on structural requirements and design specifications.

3. Fabrication Processes:
Involves cutting, drilling, and welding of steel sections to create members like beams, columns, and trusses. Precision is crucial to ensure accurate assembly on-site.

4. Connection Details:
Detailed design and fabrication of connections, including welding or bolting, to ensure stability and load transfer between different structural members.

5. 3D Modeling:
Utilizes 3D modeling software for creating detailed models of the structure, aiding in visualization, coordination, and accurate fabrication.
...
1. Definition:
Structural steelwork involves the fabrication and assembly of steel components used in the construction of buildings, bridges, and other structures. It provides the framework that supports the load-bearing elements of a construction project.

2. Materials:
Primary material is structural steel, typically hot-rolled steel sections like beams, columns, and channels. The choice of steel grade depends on structural requirements and design specifications.

3. Fabrication Processes:
Involves cutting, drilling, and welding of steel sections to create members like beams, columns, and trusses. Precision is crucial to ensure accurate assembly on-site.

4. Connection Details:
Detailed design and fabrication of connections, including welding or bolting, to ensure stability and load transfer between different structural members.

5. 3D Modeling:
Utilizes 3D modeling software for creating detailed models of the structure, aiding in visualization, coordination, and accurate fabrication.
 
1. Definition:
Plate work refers to the fabrication of structural components using steel plates. These plates are cut, formed, and assembled to create a variety of structures, including tanks, vessels, and industrial equipment.

2. Materials:
Typically involves the use of steel plates, which may vary in thickness based on the structural requirements. Common steel grades include mild steel, stainless steel, and high-strength alloys.

3. Cutting Process:
Steel plates are cut to the required shape using processes like flame cutting, plasma cutting, or laser cutting, ensuring precision and adherence to design specifications.

4. Forming and Bending:
Plates are formed and bent into the desired shapes using tools such as press brakes or rolling machines. This process gives the plates the required curvature for specific applications.

5. Welding:
Welding plays a critical role in plate work, as plates are often joined together to form larger structures. Welding methods may include MIG (Metal Inert Gas) or TIG (Tungsten Inert Gas) welding, depending on the project requirements.

6. Applications:
Plate work is widely used in the construction of pressure vessels, storage tanks, industrial silos, and other structures where a combination of strength and formability is essential.
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1. Definition:
Plate work refers to the fabrication of structural components using steel plates. These plates are cut, formed, and assembled to create a variety of structures, including tanks, vessels, and industrial equipment.

2. Materials:
Typically involves the use of steel plates, which may vary in thickness based on the structural requirements. Common steel grades include mild steel, stainless steel, and high-strength alloys.

3. Cutting Process:
Steel plates are cut to the required shape using processes like flame cutting, plasma cutting, or laser cutting, ensuring precision and adherence to design specifications.

4. Forming and Bending:
Plates are formed and bent into the desired shapes using tools such as press brakes or rolling machines. This process gives the plates the required curvature for specific applications.

5. Welding:
Welding plays a critical role in plate work, as plates are often joined together to form larger structures. Welding methods may include MIG (Metal Inert Gas) or TIG (Tungsten Inert Gas) welding, depending on the project requirements.

6. Applications:
Plate work is widely used in the construction of pressure vessels, storage tanks, industrial silos, and other structures where a combination of strength and formability is essential.
 
1. Purpose:

Steel detailing serves as the bridge between structural engineering design and actual fabrication and construction.
It provides detailed information about the dimensions, materials, and specifications required for the fabrication of each steel component.

2. Steel Detailing Process:

Initial Review: The detailing process begins with a review of the structural engineering drawings and specifications.
3D Modeling: Detailers use specialized software to create a 3D model of the structure, which includes all steel components.
Detailing Drawings: Based on the 3D model, detailed drawings are created for each steel member, connection, and assembly.

3. Components of Steel Detailing:

Shop Drawings: These detailed drawings are used by fabricators to manufacture individual steel components.
Erection Drawings: These drawings guide the steel erector on how to assemble the fabricated components at the construction site.
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1. Purpose:

Steel detailing serves as the bridge between structural engineering design and actual fabrication and construction.
It provides detailed information about the dimensions, materials, and specifications required for the fabrication of each steel component.

2. Steel Detailing Process:

Initial Review: The detailing process begins with a review of the structural engineering drawings and specifications.
3D Modeling: Detailers use specialized software to create a 3D model of the structure, which includes all steel components.
Detailing Drawings: Based on the 3D model, detailed drawings are created for each steel member, connection, and assembly.

3. Components of Steel Detailing:

Shop Drawings: These detailed drawings are used by fabricators to manufacture individual steel components.
Erection Drawings: These drawings guide the steel erector on how to assemble the fabricated components at the construction site.