Hot Rolled Structure Steel I-Beam Q235 High Quality
- Ref Price:
-
- Loading Port:
- Tianjin
- Payment Terms:
- TT OR LC
- Min Order Qty:
- 100 m.t.
- Supply Capability:
- 10000 m.t./month
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OKorder Financial Service
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Product Description:
OKorder is offering Hot Rolled Structure Steel I-Beam Q235 High Quality Good Price at great prices with worldwide shipping. Our supplier is a world-class manufacturer of steel, with our products utilized the world over. OKorder annually supplies products to European, North American and Asian markets. We provide quotations within 24 hours of receiving an inquiry and guarantee competitive prices.
Product Applications:
Hot Rolled Hot Rolled Structure Steel I-Beam Q235 High Quality are ideal for structural applications and are widely used in the construction of buildings and bridges, and the manufacturing, petrochemical, and transportation industries.
Product Advantages:
OKorder's Hot Rolled Structure Steel I-Beam Q235 High Quality are durable, strong, and resist corrosion.
Main Product Features:
· Premium quality
· Prompt delivery & seaworthy packing (30 days after receiving deposit)
· Corrosion resistance
· Can be recycled and reused
· Mill test certification
· Professional Service
· Competitive pricing
Product Specifications:
Manufacture: Hot rolled
Grade: Q235, Q345, SS400, S235JR, S275JR, S355JR
Standard: GB, JIS, ASTM ST
Certificates: ISO, SGS, BV, CIQ
Length: 5.8m – 12m, as per customer request
Surface: Painted, galvanized, punched
Packaging: Export packing, nude packing, bundled
Place of Origin: Hebei, China
No. | Depth*Flange Width (mm) | Web Thickness (mm) | Weight (Kg/m) |
10 | 100X68 | 4.5 | 11.261 |
12* | 120X74 | 5.0 | 13.987 |
14 | 140X80 | 5.5 | 16.890 |
16 | 160X88 | 6.0 | 20.513 |
18 | 180X94 | 6.5 | 24.143 |
20a | 200X100 | 7.0 | 27.929 |
20b | 200X102 | 9.0 | 31.069 |
22a | 220X110 | 7.5 | 33.070 |
22b | 220X112 | 9.5 | 36.524 |
25a | 250X116 | 8.0 | 38.105 |
25b | 250X118 | 10.0 | 42.030 |
28a | 280X122 | 8.5 | 43.492 |
28b | 280X124 | 10.5 | 47.888 |
30a* | 300X126 | 9.0 | 48.084 |
30b* | 300X128 | 11.0 | 52.794 |
32a | 320X130 | 9.5 | 52.717 |
32b | 320X132 | 11.5 | 57.741 |
36a | 360X136 | 10.0 | 60.037 |
36b | 360X138 | 12.0 | 65.689 |
40a | 400X142 | 10.5 | 67.598 |
40b | 400X144 | 12.5 | 73.878 |
IPEAA 80 | 78*46 | 3.2 | 4.95 |
IPE180 | 180*91 | 5.3 | 18.8 |
FAQ:
Q1: Why buy Materials & Equipment from OKorder.com?
A1: All products offered byOKorder.com are carefully selected from China's most reliable manufacturing enterprises. Through its ISO certifications, OKorder.com adheres to the highest standards and a commitment to supply chain safety and customer satisfaction.
Q2: How do we guarantee the quality of our products?
A2: We have established an advanced quality management system which conducts strict quality tests at every step, from raw materials to the final product. At the same time, we provide extensive follow-up service assurances as required.
Q3: How soon can we receive the product after purchase?
A3: Within three days of placing an order, we will begin production. The specific shipping date is dependent upon international and government factors, but is typically 7 to 10 workdays.
Images:
- Q:Are there any limitations to the depth of steel I-beams?
- The depth of steel I-beams is subject to certain limitations. Various factors, including structural load requirements, span length, and design considerations, determine the depth of an I-beam. As the depth increases, the I-beam's ability to resist bending and deflection also increases. Nevertheless, practical limitations exist due to manufacturing constraints, transportation limitations, and construction considerations. Manufacturing constraints can restrict the maximum depth of I-beams that can be manufactured. The production of large or extremely deep I-beams may require specialized equipment or techniques that are not readily available or cost-effective. Transportation limitations also come into play, as longer or deeper beams may prove challenging to transport to construction sites, particularly in urban areas or areas with limited access. Furthermore, construction considerations, such as building height, space constraints, and architectural requirements, may impose limitations on the depth of I-beams. In high-rise buildings, for instance, the available floor-to-floor heights may impose restrictions on the maximum depth of I-beams that can be utilized. Architects also take into account the aesthetics and visual impact of the structural elements, and excessively deep I-beams may not align with the desired design intent. In conclusion, the depth of steel I-beams is subject to limitations influenced by manufacturing constraints, transportation limitations, and construction considerations. When selecting the depth of I-beams for a given application, designers and engineers must carefully consider these limitations and find a balance between structural requirements and practical constraints.
- Q:Can steel I-beams be used in elevated walkway construction?
- Yes, steel I-beams can be used in elevated walkway construction. Steel I-beams are commonly used in construction projects due to their strength, durability, and versatility. They provide excellent load-bearing capacity, making them suitable for supporting the weight of elevated walkways. Additionally, steel I-beams can be fabricated to various lengths and sizes, allowing for customized designs and efficient installation. The use of steel I-beams in elevated walkway construction ensures a stable and safe structure for pedestrians to walk on.
- Q:Can steel I-beams be used in sports or recreational facility renovation projects?
- Yes, steel I-beams can be used in sports or recreational facility renovation projects. Steel I-beams are often used in construction due to their strength and durability. They can provide structural support and stability to the facility, making them suitable for various renovation projects. Whether it is reinforcing existing structures, creating new spaces, or improving the overall stability of the facility, steel I-beams can be a reliable and efficient choice. Additionally, steel I-beams can be customized and fabricated to meet specific project requirements, ensuring they fit seamlessly into the renovation plans.
- Q:How do steel I-beams perform in extreme weather conditions?
- Steel I-beams are renowned for their remarkable strength and durability, rendering them highly suitable for enduring severe weather conditions. Whether it be scorching heat, freezing temperatures, torrential rain, or powerful gusts of wind, steel I-beams exhibit exceptional performance. A key advantage of steel I-beams lies in their ability to resist temperature fluctuations. Unlike other materials, steel does not undergo significant expansion or contraction due to changes in temperature. Consequently, steel I-beams remain consistently reliable in extreme heat or cold, ensuring their structural integrity over time. When confronted with harsh weather conditions like hurricanes or strong winds, steel I-beams exhibit remarkable resilience against bending or breaking. The I-shape design of these beams grants them excellent load-bearing capabilities, enabling them to withstand intense winds and prevent structural failures. This is of utmost importance in areas prone to tornadoes, hurricanes, or other high-wind events. Steel I-beams also perform exceptionally well in the face of heavy rainfall or snowfall. Their inherent strength allows them to bear the weight of accumulated snow or the force of heavy rain without buckling or collapsing. Moreover, steel possesses resistance against water damage, corrosion, and rotting, ensuring the durability and structural stability of the I-beams in wet conditions. Furthermore, steel I-beams possess superior fire resistance compared to other materials. In the event of a fire, steel does not combust, melt, or contribute to the spread of flames. This characteristic makes steel I-beams a dependable choice in areas susceptible to wildfires or other fire hazards. All in all, steel I-beams are engineered to endure extreme weather conditions and excel in such circumstances. Their strength, durability, resistance to temperature fluctuations, wind resistance, and fire resistance make them a dependable choice for diverse construction projects, guaranteeing the safety and stability of structures even in the most severe weather conditions.
- Q:How do steel I-beams perform in terms of thermal bridging?
- Steel I-beams are highly conductive materials, which means they have a high thermal conductivity. This makes them poor performers in terms of thermal bridging, as they allow heat to easily flow through them, resulting in significant energy losses and potential thermal discomfort in buildings.
- Q:Can steel I-beams be used in educational or school buildings?
- Yes, steel I-beams can be used in educational or school buildings. Steel I-beams are commonly used in construction due to their strength and load-bearing capabilities. They provide structural support for the building, ensuring its stability and safety. In educational or school buildings, where large open spaces are often desired, steel I-beams are often used to create large, open classrooms or auditoriums without the need for excessive columns or supports. Additionally, steel I-beams can be used to create multi-story buildings, allowing for efficient use of limited space in crowded school campuses. Overall, steel I-beams are a reliable and versatile option for constructing educational or school buildings.
- Q:What are the common accessories used with steel I-beams, such as brackets and connectors?
- Common accessories used with steel I-beams include brackets, connectors, cleats, hangers, bolts, and plates. These accessories are essential for providing structural support, connecting beams together, securing them to other components, and ensuring the overall stability and integrity of the I-beam structure.
- Q:How do steel I-beams perform in high-wind stadium applications?
- Steel I-beams perform well in high-wind stadium applications due to their strength and stiffness. The structural integrity and load-bearing capacity of I-beams make them capable of withstanding the wind forces exerted on the stadium. Additionally, the design and placement of these beams are carefully engineered to ensure optimal performance and safety, making them a reliable choice for such applications.
- Q:Can steel I-beams be used in the construction of industrial warehouses?
- Yes, steel I-beams are commonly used in the construction of industrial warehouses due to their structural strength, durability, and ability to support heavy loads.
- Q:How do you calculate the torsional deflection of a steel I-beam?
- To calculate the torsional deflection of a steel I-beam, you need to consider various factors and apply relevant formulas. Here is a step-by-step guide to calculate the torsional deflection: 1. Gather the necessary information: Start by collecting the required data, including the dimensions of the I-beam, such as its height (h), width of the flanges (b1 and b2), thickness of the flanges (t1 and t2), and the length of the beam (L). 2. Determine the material properties: Identify the properties of the steel being used, especially the modulus of rigidity (G) or shear modulus. This value represents the material's resistance to shear deformation and is necessary for the calculations. 3. Calculate the cross-sectional area: Determine the cross-sectional area of the I-beam by subtracting the area of two rectangles (flanges) from the area of one rectangle (web). The area of the web can be calculated as A = h * (b1 - t1 - t2) + b2 * t2. 4. Determine the polar moment of inertia: The polar moment of inertia (J) represents a beam's resistance to torsional deformation. It can be calculated using various formulas depending on the shape of the cross-section. For an I-beam, the formula is J = (b1 * t1^3 + b2 * t2^3) / 3. 5. Calculate the maximum shear stress: The maximum shear stress (τ) caused by torsional loading can be calculated using the formula τ = T * r / J, where T is the applied torque and r is the distance from the center of the beam to the outermost point on the cross-section. 6. Determine the torsional deflection: The torsional deflection (θ) can be calculated using the formula θ = T * L / (G * J), where T is the applied torque, L is the length of the beam, G is the shear modulus, and J is the polar moment of inertia. By following these steps and plugging in the appropriate values, you can calculate the torsional deflection of a steel I-beam. It is important to note that these calculations provide an approximation and should be verified by a professional engineer to ensure accuracy and safety.
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Hot Rolled Structure Steel I-Beam Q235 High Quality
- Ref Price:
-
- Loading Port:
- Tianjin
- Payment Terms:
- TT OR LC
- Min Order Qty:
- 100 m.t.
- Supply Capability:
- 10000 m.t./month
OKorder Service Pledge
OKorder Financial Service
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