Steel Beam - C-Channel Dimensions & Drawings | Dimensions.com (2024)

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Steel Beam - C-Channel Dimensions & Drawings | Dimensions.com (1)Steel Beam - C-Channel Dimensions & Drawings | Dimensions.com (2)

Description

Description

C-channel steel beams are a type of structural steel beam that is shaped like a "C". They are made from hot-rolled carbon steel and are available in a variety of sizes and thicknesses. C-channel beams are used in a variety of applications, including construction, manufacturing, and transportation. They are known for their strength, durability, and versatility.

Dimensions & Sizes

Dimensions & Sizes

C-Channel Steel Beams are available in a range of sizes with widths between 1.35”-3.15” (3.4-8 cm), depths from 3”-12” (7.6-30.5 cm), and thicknesses between .12”-.4” (3-10 mm). C-Channel Steel Beams are available in typical lengths between 4’-20’ (1.22-6.1 m).

Steel Beam - C-Channel Dimensions & Drawings | Dimensions.com (3)

Description

Description

C-channel steel beams are a type of structural steel beam that is shaped like a "C". They are made from hot-rolled carbon steel and are available in a variety of sizes and thicknesses. C-channel beams are used in a variety of applications, including construction, manufacturing, and transportation. They are known for their strength, durability, and versatility.

Dimensions & Sizes

Dimensions & Sizes

C-Channel Steel Beams are available in a range of sizes with widths between 1.35”-3.15” (3.4-8 cm), depths from 3”-12” (7.6-30.5 cm), and thicknesses between .12”-.4” (3-10 mm). C-Channel Steel Beams are available in typical lengths between 4’-20’ (1.22-6.1 m).

Steel Beam - C-Channel Dimensions & Drawings | Dimensions.com (4)

Steel Beam - C-Channel Dimensions & Drawings | Dimensions.com (5)

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3D Model

3D Model

Common Questions

Common Questions

What can be adjusted to make a steel beam stronger?

The best way to make a steel beam stronger will depend on the specific application. In some cases, it may be sufficient to increase the cross-sectional area of the beam. In other cases, it may be necessary to use a higher-strength steel or add stiffeners to the beam. In still other cases, a composite beam may be the best option.

What gives a steel beam its strength?

Steel beams are strong because of their chemical composition, their manufacturing process, and the shape of the beam. teel is an alloy of iron and carbon, and the amount of carbon in the steel determines its strength. Steel with a higher carbon content is stronger, but it is also more brittle. Steel beams are typically made with a low carbon content, which gives them a good balance of strength and ductility.

What types of buildings use steel beams?

Steel beams are used in a variety of buildings, including residential, commercial, industrial, and agricultural buildings. They are also used in bridges, stadiums, and other large structures. Steel beams are strong and durable, and they can support a lot of weight. They are also relatively inexpensive, which makes them a popular choice for many types of buildings.

What can be adjusted to make a steel beam stronger?

The best way to make a steel beam stronger will depend on the specific application. In some cases, it may be sufficient to increase the cross-sectional area of the beam. In other cases, it may be necessary to use a higher-strength steel or add stiffeners to the beam. In still other cases, a composite beam may be the best option.

What gives a steel beam its strength?

Steel beams are strong because of their chemical composition, their manufacturing process, and the shape of the beam. teel is an alloy of iron and carbon, and the amount of carbon in the steel determines its strength. Steel with a higher carbon content is stronger, but it is also more brittle. Steel beams are typically made with a low carbon content, which gives them a good balance of strength and ductility.

What types of buildings use steel beams?

Steel beams are used in a variety of buildings, including residential, commercial, industrial, and agricultural buildings. They are also used in bridges, stadiums, and other large structures. Steel beams are strong and durable, and they can support a lot of weight. They are also relatively inexpensive, which makes them a popular choice for many types of buildings.

Floors+Floors+

What is the rule-of-three in selecting flooring?

The rule-of-three in selecting flooring refers to the principle of limiting the variety of flooring materials to three different types within a single space or home to create a cohesive and harmonious aesthetic. By using no more than three different flooring materials, you can create visual continuity and avoid a disjointed or cluttered appearance. This rule helps in balancing diversity in textures and patterns, while maintaining a sense of unity and flow throughout the space.

What are the cultural differences in labeling floor levels?

Cultural differences in labeling floor levels vary mainly between countries. In the US, the ground floor is typically called the first floor, and the floor above it is the second floor. However, in many European countries, the ground floor is distinct from the numbered floors, so the floor above the ground floor is the first floor. Additionally, in some cultures, certain numbers are considered unlucky; for example, buildings in China often omit floors with the number 4.

How will floors change in the future?

Floors in the future are likely to incorporate smart and sustainable technologies. They might include embedded sensors to adjust heating or lighting based on occupancy or preference. Energy-harvesting floors could generate electricity from footsteps. Modular and reconfigurable floor systems may allow for adaptable spaces. Sustainable materials, such as recycled plastics or bamboo, will be more prevalent. Also, 3D printing may facilitate custom designs and faster installation, while virtual and augmented reality could be integrated for interactive floor displays.

What is the rule-of-three in selecting flooring?

The rule-of-three in selecting flooring refers to the principle of limiting the variety of flooring materials to three different types within a single space or home to create a cohesive and harmonious aesthetic. By using no more than three different flooring materials, you can create visual continuity and avoid a disjointed or cluttered appearance. This rule helps in balancing diversity in textures and patterns, while maintaining a sense of unity and flow throughout the space.

What are the cultural differences in labeling floor levels?

Cultural differences in labeling floor levels vary mainly between countries. In the US, the ground floor is typically called the first floor, and the floor above it is the second floor. However, in many European countries, the ground floor is distinct from the numbered floors, so the floor above the ground floor is the first floor. Additionally, in some cultures, certain numbers are considered unlucky; for example, buildings in China often omit floors with the number 4.

How will floors change in the future?

Floors in the future are likely to incorporate smart and sustainable technologies. They might include embedded sensors to adjust heating or lighting based on occupancy or preference. Energy-harvesting floors could generate electricity from footsteps. Modular and reconfigurable floor systems may allow for adaptable spaces. Sustainable materials, such as recycled plastics or bamboo, will be more prevalent. Also, 3D printing may facilitate custom designs and faster installation, while virtual and augmented reality could be integrated for interactive floor displays.

Walls+Walls+

What are the tallest walls in the world?

As of September 2021, the Great Wall of China is often considered the longest, but not the tallest. The tallest walls are typically retaining structures, such as the Diga del Vajont in Italy, which stands at 262 meters (860 ft). For inhabited structures, the Ryugyong Hotel in North Korea stands as a wall-like skyscraper at 330 meters (1,080 ft). The Israeli West Bank barrier is one of the tallest security walls, reaching heights of 8 meters (26 ft) in places.

What are the different types of walls used today?

Walls are versatile structures that can be classified into various types based on their function and construction. Load-bearing walls are integral to a building's structure, supporting the weight above them, while partition walls are used to divide spaces without bearing any load. Shear walls are crucial in providing lateral support to buildings, particularly in earthquake-prone areas. Retaining walls are engineered to hold back earth and maintain different levels of soil. Boundary walls define property lines and offer security. Additionally, cavity walls consist of two parallel walls with an airspace in between for insulation, and veneer walls are non-structural, providing a decorative surface.

How will walls change in the future?

In the future, walls are likely to become more adaptive and multifunctional. Smart walls with integrated technology could regulate temperature, lighting, and even display information or images. Modular and movable walls may facilitate adaptable living spaces. The use of sustainable materials like rammed earth or recycled plastics could be prevalent. Transparent solar panels might be integrated into walls for energy generation. Additionally, advances in 3D printing technology could revolutionize how walls are constructed, making it faster and more cost-effective.

What are the tallest walls in the world?

As of September 2021, the Great Wall of China is often considered the longest, but not the tallest. The tallest walls are typically retaining structures, such as the Diga del Vajont in Italy, which stands at 262 meters (860 ft). For inhabited structures, the Ryugyong Hotel in North Korea stands as a wall-like skyscraper at 330 meters (1,080 ft). The Israeli West Bank barrier is one of the tallest security walls, reaching heights of 8 meters (26 ft) in places.

What are the different types of walls used today?

Walls are versatile structures that can be classified into various types based on their function and construction. Load-bearing walls are integral to a building's structure, supporting the weight above them, while partition walls are used to divide spaces without bearing any load. Shear walls are crucial in providing lateral support to buildings, particularly in earthquake-prone areas. Retaining walls are engineered to hold back earth and maintain different levels of soil. Boundary walls define property lines and offer security. Additionally, cavity walls consist of two parallel walls with an airspace in between for insulation, and veneer walls are non-structural, providing a decorative surface.

How will walls change in the future?

In the future, walls are likely to become more adaptive and multifunctional. Smart walls with integrated technology could regulate temperature, lighting, and even display information or images. Modular and movable walls may facilitate adaptable living spaces. The use of sustainable materials like rammed earth or recycled plastics could be prevalent. Transparent solar panels might be integrated into walls for energy generation. Additionally, advances in 3D printing technology could revolutionize how walls are constructed, making it faster and more cost-effective.

Related Collections

Related Collections

Floors

Walls

Related Tags

Related Tags

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Steel Beam - C-Channel Dimensions & Drawings | Dimensions.com (7)Steel Beam - C-Channel Dimensions & Drawings | Dimensions.com (8)

Details

Details

*Under Development*

Height:

Width:

1.35”-3.15” | 3.4-8 cm

Depth:

3”-12” | 7.6-30.5 cm

Length:

4’-20’ | 1.22-6.1 m

:

:

Weight:

Area:

:

Thickness: .12”-.4” | 3-10 mm

Materials:

Structural steel

:

:

Drawings include:

C-Channel Steel Beam plan (various sizes), elevation

Related Collections

Related Collections

Floors

Walls

Related Tags

Related Tags

Types

Types

Guides

Guides

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Steel beams and joists are structural elements used in construction to support floors, roofs, and other loads. Steel beams are long, slender members that carry tension and compression forces, while joists are shorter, thicker members that carry bending forces.

Steel Connection - Plate, Gusset

12.8”-43.3” | 32.6-110 cm

21.6”-75.6” | 54.8-192 cm

.35”-.87” | 9-22 mm (Plate)

Steel Connection - Plate, Gusset

110.000

192.000

2.200

5300

https://p3d.in/e/WU9Xs

GUIDE3D

Steel Beam - Open-Web Joist

3”-18” | 7.6-45.7 cm

8”-72” | 20.3-183 cm

12’-100’ | 3.66-30.5 m

Steel Beam - Open-Web Joist

45.700

183.000

3050.000

1900

https://p3d.in/e/NPNcK

GUIDE3D

Steel Beam - Wide Flange

4”-16” | 10.2–40.6 cm

4”-16” | 10.2–40.6 cm

8’-20’ | 2.44-6.1 m (Typical); 40’ | 12.2 m (Max)

Steel Beam - Wide Flange

40.600

40.600

610.000

1700

https://p3d.in/e/zyT5K

GUIDE3D

Steel Beam - Wide Flange, 1:2

3”-18” | 7.6-45.7 cm

4”-36” | 10.2-40.6 cm

12’-80’ | 3.66-24.4 m (Span)

Steel Beam - Wide Flange, 1:2

45.700

40.600

2440.000

1700

https://p3d.in/e/PLlKC

GUIDE3D

Steel Connection - Plate, Flange

.35”-.87” | 9-22 mm (Plate)

3.7”-12.25” | 9.4-31.1 cm

3.35”-10.5” | 8.5-26.6 cm

Steel Connection - Plate, Flange

2.200

31.100

36.600

700

https://p3d.in/e/rLoc6

GUIDE3D

Steel Beam - H-Section

4”-16” | 10.2–40.6 cm

4”-16” | 10.2–40.6 cm

8’-20’ | 2.44-6.1 m (Typical); 40’ | 12.2 m (Max)

Steel Beam - H-Section

40.600

40.600

610.000

250

https://p3d.in/e/ucYQ5

GUIDE3D

Steel Beam - L-Section

.6”-9.84” | 1.5-25 cm

.6”-9.84” | 1.5-25 cm

20’-54’ | 6.1-16.5 m

Steel Beam - L-Section

25.000

25.000

1650.000

50

https://p3d.in/e/xCVsY

GUIDE3D

Steel Connection - End Plate

7.5”-21.1” | 19-53.6 cm

4.1”-12.2” | 10.3-31 cm

.35”-.87” | 9-22 mm (Plate)

Steel Connection - End Plate

53.600

31.000

2.200

50

https://p3d.in/e/QorIo

GUIDE3D

Steel Beam - T-Section

1”-12” | 2.5-30.5 cm

1”-12” | 2.5-30.5 cm

10’-20’ | 3.05-6.1 m

Steel Beam - T-Section

30.500

30.500

610.000

35

https://p3d.in/e/VUdeG

GUIDE3D

Steel Beam - C-Purlin

2”, 2.5” | 5.1, 6.4 cm

5.5”-10.5” | 14-26.7 cm

6’-25’ | 1.83-7.62 m

Steel Beam - C-Purlin

6.400

26.700

762.000

30

https://p3d.in/e/NXIH3

GUIDE3D

Steel Connection - End Plate, Extended

9.7”-26.1” | 24.6-66.4 cm

6.1”-13” | 15.4-33 cm

4.1”-12.2” | 10.3-31 cm

Steel Connection - End Plate, Extended

66.400

33.000

31.000

20

https://p3d.in/e/l4PRu

GUIDE3D

Steel Connection - Cleat, Web

2.5”-10” | 6.4-25.4 cm

1.5”-4.9” | 3.9-12.5 cm

1.5”-4.9” | 3.9-12.5 cm

Steel Connection - Cleat, Web

25.400

12.500

12.500

20

https://p3d.in/e/sCdXJ

GUIDE3D

Steel Beam - C-Channel

1.35”-3.15” | 3.4-8 cm

3”-12” | 7.6-30.5 cm

4’-20’ | 1.22-6.1 m

Steel Beam - C-Channel

8.000

30.500

610.000

10

https://p3d.in/e/D3UVN

GUIDE3D

Steel Connection - Cleat, Flange

1.5”-4.9” | 3.9-12.5 cm

1.5”-4.9” | 3.9-12.5 cm

2.5”-10” | 6.4-25.4 cm

Steel Connection - Cleat, Flange

12.500

12.500

25.400

10

https://p3d.in/e/1oRFZ

GUIDE3D

Steel Beam - Bulb Plate

6.3”-16.9” | 16-43 cm

.87”-2.64” | 2.2-6.7 cm

20’-54’ | 6.1-16.5 m

Steel Beam - Bulb Plate

43.000

6.700

1650.000

5

https://p3d.in/e/LIJQZ

GUIDE3D

Steel Beam - U-Channel

1.35”-3.15” | 3.4-8 cm

3”-12” | 7.6-30.5 cm

4’-20’ | 1.22-6.1 m

Steel Beam - U-Channel

8.000

30.500

610.000

5

https://p3d.in/e/7y348

GUIDE3D

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Steel Beam - C-Channel Dimensions & Drawings | Dimensions.com (2024)

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