• Mild Steel Hot Rolled I Beam IPE In Construction Use System 1
  • Mild Steel Hot Rolled I Beam IPE In Construction Use System 2
Mild Steel Hot Rolled I Beam IPE In Construction Use

Mild Steel Hot Rolled I Beam IPE In Construction Use

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Loading Port:
China main port
Payment Terms:
TT or LC
Min Order Qty:
25 m.t.
Supply Capability:
10000 m.t./month

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Structure of Mild Steel Hot Rolled I Beam IPE In Construction Use Description:

Mild steel hot rolled I beam IPE in construction use is a beam with an I-shaped cross-section. The horizontal elements of the "I" are known as flanges, while the vertical element is termed the "web". Mild steel hot rolled I beam IPE in construction use is usually made of structural steel and is used in construction and civil engineering. The mild steel hot rolled I beam IPE in construction use resists shear forces, while the flanges resist most of the bending moment experienced by the beam. Mild steel hot rolled I beam IPE in construction use theory shows that the I-shaped section is a very efficient form for carrying both bending and shears loads in the plane of the web.

 

2. Main Features of Mild Steel Hot Rolled I Beam IPE In Construction Use:

• Grade: Q235

• Type: Mild carbon steel

• Deflection: The stiffness of the I-beam will be chosen to minimize deformation

• Vibration: The stiffness and mass are chosen to prevent unacceptable vibrations, particularly in settings sensitive to vibrations, such as offices and libraries.

• Local yield: Caused by concentrated loads, such as at the beam's point of support.

 

3. Mild Steel Hot Rolled I Beam IPE In Construction Use Images:

 

 

 

4. Mild Steel Hot Rolled I Beam IPE In Construction Use Specification:

Mechanical Properties

Grade

Steel diametermm

≤16

16~40

40~60

60~100

Yield Point Δs/MPa

Q195

≥195

≥185

-

-

Q235

235

225

215

205

Tensile Strength

Q195

315~390

Q235

375~500

Elongation δ5%

Q195

≥33

≥32

-

-

Q235

26

25

24

23

 

5. FAQ

We have organized several common questions for our clients,may help you sincerely:

①Is this product same as W beam?

In the United States, the most commonly mentioned I-beam is the wide-flange (W) shape. These beams have flanges in which the planes are nearly parallel. Other I-beams include American Standard (designated S) shapes, in which flange surfaces are not parallel, and H-piles (designated HP), which are typically used as pile foundations. Wide-flange shapes are available in grade ASTM A992,[4] which has generally replaced the older ASTM grades A572 and A36.

②How to inspect the quality?

We have a professional inspection group which belongs to our company. We resolutely put an end to unqualified products flowing into the market. At the same time, we will provide necessary follow-up service assurance.

③Is there any advantage about this kind of product?

Steel I beam bar IPE has a reduced capacity in the transverse direction, and is also inefficient in carrying torsion, for which hollow structural sections are often preferred.

Q:How do you calculate the shear capacity of a steel I-beam?
In order to calculate the shear capacity of a steel I-beam, two main factors must be taken into consideration: the shear strength of the material and the cross-sectional properties of the beam. The first step is to determine the shear strength of the material. This information can be obtained from the manufacturer's specifications or from relevant design codes and standards. The shear strength represents the maximum stress that the material can withstand before it fails due to shear. Next, the cross-sectional properties of the I-beam need to be determined. This includes calculating the moment of inertia (I) and the area (A) of the cross-section. These properties can be calculated using the dimensions of the beam, such as its height, flange width, and web thickness. Once the shear strength and cross-sectional properties are known, the shear capacity can be calculated using the following formula: Shear Capacity = Shear Strength * (A / I) This formula establishes a relationship between the shear strength of the material and the cross-sectional properties of the beam. Dividing the area (A) of the cross-section by the moment of inertia (I) provides a measure of the material's efficiency in resisting shear. It is important to note that factors other than shear strength and cross-sectional properties also influence the shear capacity of a steel I-beam. These factors include the presence of stiffeners and the type of connection used. These considerations should be taken into account during the overall design and analysis of the beam. In conclusion, calculating the shear capacity of a steel I-beam involves determining the shear strength of the material and using the cross-sectional properties of the beam to calculate the shear capacity using the formula Shear Capacity = Shear Strength * (A / I).
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 you calculate the deflection of a steel I-beam?
By utilizing the principles of structural engineering and mechanics, one can determine the deflection of a steel I-beam. Deflection refers to the extent of bending or flexing that occurs when a load is applied to the beam. It is a crucial aspect to consider in the design of structures to guarantee their stability and safety. To calculate the deflection of a steel I-beam, the following steps can be undertaken: 1. Identifying the load: Initially, one must identify the type and magnitude of the load acting upon the beam. This could be a concentrated load, uniformly distributed load, or a combination of both. 2. Determining the reaction forces: The reaction forces at the supports of the beam must be determined. This can be done by considering the equilibrium of forces and moments acting on the beam. 3. Calculating the bending moment: The bending moment at any point along the length of the beam can be calculated using the principles of statics. This involves considering the distribution of the applied load and the geometry of the beam. 4. Finding the moment of inertia: The moment of inertia is a characteristic of the beam that describes its resistance to bending. It relies on the shape and dimensions of the cross-section of the beam. The moment of inertia can be determined using standard engineering reference tables or specific formulas for the I-beam shape. 5. Applying the beam deflection formula: The beam deflection formula varies depending on the type of load and the support conditions of the beam. For a simply supported beam under a concentrated load at the center, the deflection formula (δ) is given as δ = (5FL^4) / (384EI), where F represents the applied load, L is the length of the beam, E is the modulus of elasticity of the steel, and I is the moment of inertia. 6. Calculating the deflection: By utilizing the values derived from the previous steps, one can calculate the deflection of the steel I-beam. This will provide an indication of the extent to which the beam will bend or flex under the applied load. It is essential to note that this explanation offers a simplified overview of the calculation process. Additional factors such as beam supports, structural connections, and other loads acting on the beam may need to be taken into account. It is recommended to consult with a structural engineer or refer to relevant design codes and standards to ensure accurate and safe calculations.
Q:How are steel I-beams used in commercial construction?
Due to their strength, versatility, and cost-effectiveness, steel I-beams are widely used in commercial construction. These beams, typically made of high-quality steel, have the shape of the letter "I" with horizontal top and bottom flanges and a vertical web in the middle. In commercial construction, steel I-beams serve as crucial structural components that bear the weight of the building and transfer loads to the foundation. They are commonly employed in constructing floors, roofs, walls, and the framework of bridges and other large structures. The ability of steel I-beams to span long distances and support heavy loads is one of their main advantages. The I-beam shape boasts an excellent strength-to-weight ratio, enabling it to carry significant loads without becoming excessively heavy. Consequently, large open spaces can be created within commercial buildings like warehouses, shopping centers, and industrial facilities, without the need for additional columns or supports. Moreover, steel I-beams offer design and construction flexibility. They can be tailored to meet specific structural requirements, such as desired span, load capacity, and overall design aesthetics. This adaptability empowers architects and engineers to craft efficient and functional commercial spaces while maintaining structural integrity. Furthermore, steel I-beams possess high durability and resistance to fire, corrosion, and pests, rendering them suitable for long-term use in commercial buildings. Their maintenance needs are minimal compared to other construction materials, which helps reduce overall lifecycle costs. In conclusion, steel I-beams play a vital role in commercial construction due to their strength, versatility, and cost-effectiveness. They provide essential structural support, enable the creation of large open spaces, and offer design flexibility. Their durability and low maintenance requirements make them an ideal choice for long-lasting and efficient commercial buildings.
Q:Can steel I-beams be used in the construction of schools and educational facilities?
Schools and educational facilities can definitely make use of steel I-beams in their construction. Steel I-beams offer numerous benefits in building, making them a popular option for various types of structures, including schools. To begin with, steel I-beams are renowned for their strength and durability. They can bear heavy loads, allowing for the creation of expansive open spaces without the need for excessive support columns or walls. This is especially advantageous in educational facilities, as it permits adaptable spaces that can be easily reconfigured to meet changing needs and accommodate different activities. Additionally, steel I-beams possess fire-resistant qualities, which are crucial for ensuring the safety of students and staff. Steel does not burn, melt, or contribute to the spread of fires, making it an excellent choice for schools where fire safety is a top priority. Moreover, steel is an environmentally friendly and sustainable material. It can be recycled and reused, reducing waste and minimizing the construction process's carbon footprint. This aligns with the increasing focus on sustainability in educational facilities. Furthermore, steel I-beams prove to be cost-effective in the long run. Although the initial investment in steel construction may be higher compared to other materials, the durability and low maintenance requirements of steel make it a cost-efficient choice over its lifespan. This is particularly advantageous for schools with limited budgets, as it reduces the need for frequent repairs and replacements. Lastly, steel I-beams offer design flexibility, allowing architects and designers to create modern and visually appealing educational facilities. The sleek and slender profile of the I-beams can be incorporated into various architectural styles, providing a contemporary and aesthetically pleasing look to the building. In conclusion, steel I-beams are a suitable and advantageous option for constructing schools and educational facilities. Their strength, fire-resistant properties, sustainability, cost-effectiveness, and design flexibility make them an ideal material for establishing safe, functional, and visually appealing learning environments.
Q:Can steel I-beams be used in residential remodeling or addition projects?
Yes, steel I-beams can be used in residential remodeling or addition projects. Steel I-beams are commonly used as structural support beams due to their strength and durability. They can be used to replace load-bearing walls, create open-concept spaces, or support additional floors or additions. Steel I-beams provide excellent support for heavy loads and can span longer distances than traditional wood beams. Additionally, they have a smaller profile compared to wood beams, allowing for more flexibility in design and maximizing the usable space in a residential project. However, it is important to consult with a structural engineer or a professional contractor to ensure that the steel I-beams are properly sized and installed to meet the specific structural requirements of the project.
Q:Are steel I-beams suitable for residential basement walls?
Depending on the specific circumstances and requirements of the project, residential basement walls can potentially utilize steel I-beams. Steel I-beams possess numerous benefits, including a high strength-to-weight ratio, durability, and resistance to various forces like bending, shearing, and compression. The ability of steel I-beams to support heavy loads is one of their primary advantages when used in basement walls, making them particularly suitable for areas with expansive soil or high water tables. They effectively withstand the lateral pressure exerted by the soil, thus preventing basement wall failure, a common concern in residential construction. Furthermore, steel I-beams offer an added level of fire protection compared to materials such as wood, as they are non-combustible. This feature enhances the safety of residential basements, especially in terms of potential hazards like fire or smoke spreading from adjacent spaces. However, before opting for steel I-beams in residential basement walls, several factors need consideration. Firstly, the cost of steel I-beams may exceed that of other materials, which can impact the overall project budget. Secondly, their installation process may necessitate specialized equipment and skilled labor, potentially increasing construction complexity and time requirements. Additionally, steel I-beams may require adequate insulation to prevent thermal bridging, as metal conducts heat more readily than materials like wood or concrete. Proper insulation ensures a comfortable temperature in the basement and reduces energy consumption. In conclusion, steel I-beams can be a suitable choice for residential basement walls due to their strength, durability, and fire resistance. Nevertheless, it is vital to assess factors such as cost, installation complexity, and insulation requirements before making a final decision. Seeking guidance from a structural engineer or professional contractor can provide valuable insight into whether steel I-beams are the optimal choice for a specific residential basement project.
Q:Can steel I-beams be used in railway infrastructure?
Certainly, railway infrastructure can make use of steel I-beams. These I-beams are frequently employed in the fabrication of railway bridges and support structures because of their impressive strength-to-weight ratio and durability. Their exceptional load-bearing capacity renders them capable of sustaining the weight of trains and other hefty railway equipment. Furthermore, steel I-beams possess the added advantage of being able to span great distances, rendering them ideal for railway applications necessitating wide spans. Moreover, steel is a versatile material that can be effortlessly fabricated and welded, making it a pragmatic selection for railway infrastructure projects.
Q:What are the different types of steel I-beam connections for mezzanine floors?
There are several different types of steel I-beam connections commonly used for mezzanine floors. Some of the most popular options include bolted connections, welded connections, and moment connections. Bolted connections involve using bolts and nuts to secure the beams together, making it easy to disassemble and reconfigure if needed. Welded connections involve welding the beams together, creating a strong and permanent connection. Moment connections are designed to resist bending moments and provide additional stability to the structure. Each type of connection has its own advantages and considerations, and the choice depends on the specific requirements and design of the mezzanine floor.
Q:What are the load-bearing capacity of rectangular and I-beam steel sections of the same size?
In the same section size, the web and wing plate of I-beam are higher than rectangular steel, so the modulus of bending section is also high.

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