steel structure workshop warehouse building

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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

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:
Steel structures for military and defense facilities are designed with a strong emphasis on durability, strength, and security. These structures are typically engineered to withstand extreme environmental conditions, including high winds, seismic activity, and potential attacks. Additionally, they are designed to accommodate specialized equipment and systems required for military operations. The design process involves thorough analysis, simulations, and consideration of specific functional requirements to ensure the structures meet the stringent standards of military and defense facilities.
Q:
Steel structures are designed for wind loads by considering factors such as the wind speed, the shape and size of the structure, and the surrounding environment. Engineers use various design codes and standards, such as ASCE 7, to determine the wind loads that a structure may experience. These loads are then used to calculate the necessary size and spacing of structural members, as well as the connections between them, to ensure the structure can withstand the anticipated wind forces. Additionally, techniques like wind tunnel testing and computer simulations are often employed to refine the design and optimize its performance against wind loads.
Q:
Steel structures for mining and extraction facilities are designed using a combination of engineering principles and specific industry requirements. These structures are designed to withstand the harsh operating conditions, heavy loads, and potential hazards associated with mining and extraction operations. Factors such as site location, geological conditions, equipment requirements, and safety regulations are taken into account during the design process. The design involves careful analysis and calculations to ensure the structural integrity, stability, and durability of the steel structures to support the safe and efficient operation of mining and extraction facilities.
Q:
When designing steel high-rise buildings, several key considerations must be taken into account. These include structural integrity, fire resistance, wind resistance, seismic design, building codes and regulations, material choice, sustainability, construction methods, and cost-effectiveness. It is crucial to ensure that the structure can withstand the loads and forces imposed on it, provide adequate fire protection measures, and incorporate seismic design principles to mitigate potential earthquake damage. Adherence to building codes and regulations is essential to ensure safety and compliance. The choice of materials should prioritize strength, durability, and resistance to corrosion. Incorporating sustainable design practices can enhance energy efficiency and reduce environmental impact. Construction methods need to be efficient and safe, considering factors such as site logistics and crane access. Lastly, cost-effectiveness is crucial to ensure the project remains within budget while meeting all the necessary requirements and quality standards.
Q:
When designing steel structures in areas with high wind loads, there are several important considerations to take into account. 1. Wind Load Calculation: The first step is to accurately determine the wind loads that the structure will be subjected to. This requires careful assessment of local wind patterns, directionality, and intensity. Wind load calculations can be done using established codes and standards such as ASCE 7 or Eurocode. 2. Structural Stability: Steel structures must be designed to withstand the wind loads without experiencing excessive deflection or failure. The stability of the structure needs to be ensured by considering factors such as the shape and profile of the structure, bracing systems, and connections between structural members. 3. Material Selection: Choosing the appropriate grade of steel is crucial for withstanding high wind loads. High-strength steel with good ductility and toughness is often preferred as it provides better structural integrity and resistance against wind-induced forces. 4. Aerodynamic Design: The shape and profile of the structure should be optimized to minimize wind resistance and reduce the likelihood of vortex shedding, which can lead to dynamic instabilities. Aerodynamic features such as streamlined shapes or tapered sections can help to mitigate wind-induced vibrations. 5. Connection Design: The connections between structural members need to be carefully designed to ensure their integrity under high wind loads. Proper connection detailing, such as using high-strength bolts or welds, can enhance the overall strength and stability of the structure. 6. Foundation Design: The foundation system needs to be designed to transfer the wind loads from the structure into the ground. Adequate soil investigation and foundation design are critical to ensure that the foundation can resist the lateral forces generated by the wind. 7. Wind Breaks and Barriers: In some cases, additional wind breakers or barriers may be necessary to reduce the wind load on the structure. These can include features such as wind fences, wind screens, or adjacent buildings that can help redirect or dissipate the wind forces. 8. Maintenance and Inspection: Regular inspection and maintenance of the steel structure are essential to ensure its long-term performance in high wind load areas. This includes checking for corrosion, damage, or any signs of structural degradation that could compromise its integrity. By considering these factors, engineers can design steel structures that can safely withstand high wind loads, ensuring the safety and durability of the infrastructure in areas prone to strong winds.
Q:
Steel structures are widely used in research and laboratory buildings due to their numerous advantages. Firstly, steel is known for its strength and durability, making it an ideal material for supporting heavy scientific equipment and machinery. This allows for the construction of large open spaces without the need for excessive columns or walls, providing flexibility for future modifications or reconfigurations of the building layout. Additionally, steel structures offer a high level of precision and accuracy, which is crucial in research and laboratory settings. The dimensional stability of steel ensures that measurements and experiments are not affected by structural deformations over time. This is especially important in environments where sensitive instruments and equipment are used, as even the slightest movement or vibration can compromise the accuracy of results. Steel also possesses excellent fire resistance properties, which is essential for laboratory buildings where hazardous materials are handled. Steel structures can be designed to meet specific fire resistance requirements, ensuring the safety of researchers and preventing the spread of fire in case of an accident or malfunction. Moreover, steel structures are relatively lightweight compared to other construction materials, allowing for faster and more efficient construction processes. This is particularly advantageous for research and laboratory buildings where time is a critical factor in project completion. The use of steel also reduces the need for extensive foundations, resulting in cost savings and less disruption to the surrounding environment. In terms of sustainability, steel structures are highly recyclable and can be reused or repurposed after their useful life, minimizing waste and reducing the environmental impact. Steel also has a lower carbon footprint compared to other materials commonly used in construction, making it a more sustainable choice for research and laboratory buildings. Overall, the use of steel structures in research and laboratory buildings offers numerous benefits, including strength, durability, precision, fire resistance, efficiency, and sustainability. These advantages make steel a preferred choice for creating safe, adaptable, and functional spaces that meet the unique requirements of research and laboratory facilities.
Q:
Warehouses and storage facilities rely heavily on steel due to its strength, durability, and versatility. Its use in construction, shelving systems, and material handling equipment is crucial for the efficient and safe operation of these facilities. The construction of warehouse buildings is one of the primary applications of steel. Steel frames and structural components provide the necessary strength and stability to support the weight of stored goods and withstand external forces like wind and seismic activity. This allows for the creation of large, open spaces without the need for excessive internal columns or walls, maximizing storage capacity and flexibility. Inside the warehouse, steel is utilized for shelving and racking systems. Steel shelves and racks are designed to securely store and organize goods, ensuring efficient inventory management and easy access to products. The strength and load-bearing capacity of steel shelving systems enable the storage of heavy or bulky items, optimizing the use of vertical space and maximizing storage density. In addition, steel is widely employed in the manufacturing of material handling equipment used in warehouses and storage facilities. Forklifts, pallet jacks, and conveyors are typically constructed from steel due to its ability to withstand heavy loads and rough handling. Steel equipment guarantees the safe and efficient movement of goods within the facility, contributing to smooth operations and reducing the risk of accidents or damage. Moreover, steel's high resistance to fire, pests, and moisture makes it perfect for warehouse environments. It offers protection against fire hazards and can withstand extreme temperatures, ensuring the safety of stored goods. Steel structures and equipment are also less prone to damage from pests and moisture, preserving the integrity of the facility and preventing contamination of stored goods. In conclusion, steel is an essential component in warehouses and storage facilities. It provides the necessary strength and stability for building construction, supports efficient storage and organization through shelving systems, and ensures the safe and smooth movement of materials with material handling equipment. Its durability and resistance to fire, pests, and moisture make it a reliable choice for these demanding environments.
Q:
Steel structures can contribute to the overall aesthetics of a building by providing a sleek and modern appearance. The use of steel allows for open and expansive spaces, large windows, and unique architectural designs that can create a visually striking and impressive look. Additionally, steel's strength and durability allow for the incorporation of large spans and cantilevers, giving architects the freedom to design bold and innovative structures that catch the eye.
Q:
Yes, steel structures can be designed to be resistant to corrosion in marine environments through various measures such as using corrosion-resistant coatings, galvanization, and proper maintenance practices.
Q:
Due to their strength, durability, and versatility, steel structures find wide use in security and surveillance systems. These structures serve as a secure and stable foundation for various components of such systems. One common application of steel structures in security and surveillance systems involves the installation of CCTV cameras. Steel poles or towers are employed to mount these cameras at elevated positions, granting a better view of the surroundings. The stability of steel ensures the cameras remain steady and can withstand adverse weather conditions, thereby preventing potential damage or tampering. Aside from camera installations, steel structures are also utilized in the construction of control rooms and monitoring stations. These structures create a safe and secure environment for security personnel to monitor surveillance footage and control various security systems. The durability of steel guarantees these structures can withstand external threats and safeguard the valuable equipment and personnel housed within. Furthermore, steel structures are used to construct barriers and fences in high-security areas. Acting as a physical deterrent, these structures prevent unauthorized access and intrusions. Steel fences are highly challenging to breach, as their strong and rigid nature resists cutting or tampering, thereby enhancing overall premises security. Moreover, steel structures are commonly employed in the construction of access control systems, such as gates and turnstiles. These structures provide a robust framework for integrating electronic security measures, including biometric scanners or card readers, ensuring only authorized individuals can enter. The strength of steel makes it difficult to break through, adding an additional layer of security to these access control systems. In conclusion, steel structures play a vital role in the security and surveillance industry. Their strength, durability, and versatility make them ideal for supporting various system components, including camera installations, control rooms, fences, and access control systems. By utilizing steel structures, security and surveillance systems can achieve a higher level of protection and ensure the safety of people and assets.

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