steel structure workshop warehouse building

steel structure workshop warehouse building System 1

steel structure workshop warehouse building

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Loading Port:: China Main Port

Payment Terms:: TT OR LC

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Specifications

Steel structure workshop warehouse building
1. ISO9001:2008, SGS and BV Certification
2. Structural safety and reliability

steel structure workshop warehouse building

Technical Parameters

Item Name	steel structure workshop warehouse building
Main Material	Q235/Q345 Welded H Beam and Hot Rolled Section Steel
Surface	Painted or Hot Dip Galvanized
Roof & Wall Panel	EPS Sandwich panel /Single Corrugated Steel Sheet/ Colour sheet with Glass-wool, for customers choose
Window	PVC Steel or Aluminum Alloy
Door	Sliding Door or Rolling Up Door
Service	Design, Fabrication and Installation
	We can make quotation according to customer's drawing or requirement
	(size by length/width/height and wind speed), offering a free design
	drawing and all detailed drawings for installation.
Packing	According to customer's requirement
Packing	Load into 40/20GP,40HQ or 40OT

Packaging Detail:According to container size,container of 20 feet:Inside capacity is 5.69m x 2.34m x 2.18m,Gross weight of allocation is generally 17.5 ton,volumn is 24-26m3. container of 40 feet:Inside capacity is 11.8m x 2.34m x 2.18m,Gross weight of allocation is generally 22 ton,volumn is 54m3. HC container of 45 feet:Inside capacity is 13.58m x 2.34m x 2.71m,Gross weight of allocation is generally 29 ton,volumn is 86m3.Delivery Detail:30 days.

Q: How are steel structures designed to resist fire and heat?: Steel structures are designed to resist fire and heat through various measures. One key strategy is the use of fire-resistant coatings or intumescent paints that can expand and form an insulating layer when exposed to high temperatures. Additionally, steel members can be protected using fireproofing materials such as concrete encasement or fire-resistant boards. Structural design also incorporates fire barriers and compartmentalization to limit the spread of fire and heat. Overall, the combination of these design elements enhances the fire resistance of steel structures, ensuring their durability and safety in the event of a fire.

Q: Which is better, the steel structure or the frame structure?: The frame structure with partial concrete wall is called frame shear wall structureOften used in high-rise office buildings, shopping malls and hotels.Advantages: the use of indoor space and the partition of the room wall, as flexible as the frame structure. The seismic performance is as strong as that of the pure shear wall structure.Disadvantages: large amount of concrete, from the major, the total height is usually no more than 150m.

Q: Name of steel structure awning: Awning shed products are unique in shape, beautiful and generous, and what is more outstanding is its high strength, high durability, anti ultraviolet and insulation effect. According to the JIS standard, the snow resistance (load 875px snow pack) is effectively considered in terms of safety, and strong wind resistance (strong resistance to 42m/s wind).

Q: How are steel structures used in water treatment plants?: Steel structures are commonly used in water treatment plants for various purposes. They provide support for equipment and machinery, such as pumps, motors, and filters, ensuring their stability and safety. Steel structures also form the framework for the treatment plant buildings, housing the various treatment processes and storage tanks. Additionally, steel is often used for pipelines and conduits, which transport water throughout the plant. Overall, steel structures play a vital role in the construction and functionality of water treatment plants.

Q: How are steel structures designed for efficient use of natural resources?: Various approaches are employed in the design of steel structures to ensure the efficient utilization of natural resources. Firstly, steel itself is a highly recyclable material, capable of being recycled repeatedly without compromising its inherent properties. This characteristic reduces the need for extracting raw materials and conserves natural resources, thereby significantly mitigating the environmental impact of steel production and promoting a circular economy. Additionally, steel structures are engineered to be lighter and more efficient, necessitating less material compared to alternative construction materials like concrete. This reduction in material usage translates into a decreased demand for natural resources and a diminished overall environmental footprint. Furthermore, the lightweight nature of steel facilitates easier transportation during construction, further minimizing energy consumption. Moreover, steel structures offer the advantage of adaptability and longevity, extending their lifespan. This adaptability diminishes the requirement for new construction and associated resource consumption. By allowing for easy expansion or reconfiguration, steel structures can accommodate evolving needs without necessitating a complete overhaul, contributing to the sustainable management of resources. Furthermore, steel structures are designed to be durable and resistant to environmental factors such as corrosion, fire, and earthquakes. This durability reduces the necessity for frequent maintenance, repairs, and replacements, thereby decreasing the consumption of materials and energy throughout the structure's life cycle. Lastly, the energy efficiency of steel structures is taken into consideration during the design process. The incorporation of efficient insulation systems, energy-saving lighting, and optimized HVAC systems reduces the energy consumption of these buildings. By reducing energy demand, steel structures aid in the conservation of natural resources used in energy production. In conclusion, the design of steel structures prioritizes the efficient utilization of natural resources through the recyclability of steel, lightweight design, adaptability, durability, and energy efficiency. These considerations not only minimize the environmental impact but also contribute to the sustainable management of resources and the promotion of a greener future.

Q: Are steel structures resistant to earthquakes?: Yes, steel structures are generally considered to be resistant to earthquakes. Steel has high strength-to-weight ratio and excellent ductility, making it a suitable material for construction in areas prone to seismic activity. The flexibility and elasticity of steel allows it to absorb and dissipate seismic energy, reducing the impact of ground shaking on the structure. Additionally, steel structures can be designed and built to meet specific seismic design criteria, ensuring their resistance to earthquake forces. However, it is important to note that the level of earthquake resistance also depends on the design and construction techniques used, as well as the adherence to building codes and regulations.

Q: How do steel structures meet building code requirements?: Steel structures are able to meet building code requirements due to their inherent strength and durability. Building codes are established by regulatory bodies to ensure the safety and integrity of structures, and steel has proven to be a reliable and compliant material. Firstly, steel structures are designed and engineered by professionals who adhere to building codes and standards. These codes outline specific requirements for factors such as load-bearing capacity, fire resistance, seismic resistance, and wind resistance. Steel's high strength-to-weight ratio allows for efficient structural designs that meet or exceed these requirements. Secondly, steel undergoes rigorous testing and quality control measures to ensure its consistency and performance. The manufacturing process involves precise fabrication techniques, such as welding and bolted connections, that meet the code's specifications. Additionally, steel components are often subjected to non-destructive testing methods, including ultrasonic testing, magnetic particle inspection, and visual inspections to detect any flaws or defects. Steel structures also benefit from their ability to adapt to changing building code requirements. As building codes evolve and become more stringent, steel provides the flexibility to incorporate new design techniques and technologies. For example, steel structures can be easily retrofitted to improve their resistance against earthquakes or to enhance their energy efficiency. Furthermore, steel structures offer several advantages that align with building code requirements. Steel is non-combustible, which helps in meeting fire safety regulations. It is also resistant to termites, rot, and decay, ensuring the longevity and structural integrity of the building. Moreover, steel's high recyclability makes it an environmentally-friendly choice that aligns with sustainable building practices, which are increasingly becoming part of building codes. In conclusion, steel structures meet building code requirements through their strength, durability, and compliance with engineering standards. The use of steel in construction allows for efficient designs, precise fabrication, and adherence to various safety regulations. With its ability to adapt to evolving codes and its inherent advantages, steel remains a reliable and popular choice for meeting building code requirements.

Q: Can steel structures be earthquake-resistant?: Yes, steel structures can be made earthquake-resistant through careful engineering and design. Steel is a versatile and strong material that can absorb and dissipate seismic forces, making it a suitable choice for earthquake-prone areas. By incorporating features like cross-bracing, flexible connections, and damping systems, steel structures can effectively withstand earthquakes and minimize damage.

Q: How do steel structures handle vibrations and oscillations?: Steel structures are designed to handle vibrations and oscillations by utilizing their inherent properties of strength, stiffness, and resilience. The stiffness of steel helps to minimize the amplitude of vibrations, while its strength allows it to withstand dynamic loads. Additionally, steel structures can be designed with damping devices or tuned mass dampers to absorb and dissipate vibrations, further enhancing their ability to handle oscillations.

Q: How are steel structures designed for different water systems?: Steel structures for different water systems are designed by considering various factors such as the type and volume of water, the environmental conditions, and the specific requirements of the system. Engineers analyze the water pressure, flow rates, and potential corrosion factors to determine the appropriate steel material, thickness, and reinforcement needed for the structure. Additionally, they consider factors like seismic activity, temperature fluctuations, and maintenance accessibility to ensure the steel structure can withstand the specific water system's demands and provide long-lasting performance.

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