Aluminum extrusion for machine crossbeam
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Aluminum extrusion for machine crossbeam
1. Usage: Crossbeam profile
2. Surface:black anodize
3. Alloy:6005-T6 alloy temper
4. Size:according to customer’s requirement
5. Advantage:Durability, good corrosion resistance and lightweight
6. Package:Normal paper package and soft plastic interleaving each profile to protect the surface. In case of any special package, additional packing cost will be charged.
7. Raw materials varies from pure aluminum to alloy duralumin,
8.Surface Treatment: Anodized , Powder Coating, Electrophoresis, Wooden-pattern transfer, Thermal-break, Sand blasting, mechanical polishing,etc;
9.Color: Any color as per customer demand;
Industrial Aluminium Profiles
1. Various sections for industrial application--heat radiators, flow line, elevators, textile industry, solar energy, vehicle lamps, medical treatment, ship building industry, etc
2. Raw materials varies from pure aluminum to alloy duralumin,
3. Material Type: 6063A, 6063, 6061,6060,6005, etc;
4. Heat Treat.: T5, T6
5. Surface Treatment: Anodized, Powder Coating, Electrophoresis, Wooden-pattern transfer, Thermal-break, Sand blasting, mechanical polishing,etc;
6. Color: Any color as per customer demand;
7. Packing: Plastic film and craft paper wrapping, or wooden crates
- Q:Can aluminum profiles be used in green building projects?
- Yes, aluminum profiles can be used in green building projects. Aluminum is a highly sustainable material that has several advantages when it comes to green building. Firstly, aluminum is lightweight, which reduces transportation costs and energy consumption during construction. Additionally, aluminum is 100% recyclable, meaning that it can be reused indefinitely without any degradation in quality. This makes it an excellent choice for green building projects as it contributes to the reduction of waste and promotes a circular economy. Moreover, aluminum has a long lifespan and requires minimal maintenance, which further contributes to its sustainability. It is also worth mentioning that aluminum profiles can be easily integrated with other green building materials such as glass, allowing for energy-efficient designs that maximize natural light and minimize the need for artificial lighting. Overall, aluminum profiles are a sustainable and versatile choice for green building projects.
- Q:Calculation of heat dissipation of aluminium profile radiator
- This requires software that is not easy to compute directly, and the formulas may pull out a long string and are inaccurateBecause the contact of the bottom of the profile is initiated by the heat source, the contact area is first set, which affects the distance and conduction angle of the thermal conductivityWhen you change this condition, the whole formula varies greatlyAgain, set convection and convection intensities, convection fluid properties and relative heat exchange efficienciesIn the radiator industry, there have been similar formulas, but only the natural convection settings, and in the heat under the state, heat dissipation at room temperature settingsProfessional software has many, FLOWTHEM, e-therm, ice-pake and so on, even Pro-E seems to be able to hang modules to do simulationSuggest going directly to software
- Q:How do aluminum profiles perform in thermal insulation applications?
- Aluminum profiles are not typically renowned for their exceptional thermal insulation properties. Nonetheless, with the aid of supplementary measures, they can still be effectively employed in thermal insulation applications. Aluminum, being a highly conductive material, readily conducts heat. Consequently, there can be substantial heat transfer between the interior and exterior of a building, resulting in energy loss and decreased thermal efficiency. Thus, aluminum profiles alone may not offer adequate insulation. To enhance the thermal insulation performance of aluminum profiles, multiple strategies can be utilized. One prevalent approach involves the utilization of thermal breaks or barriers. These insulating elements are positioned between the outer and inner aluminum sections to minimize heat transfer. Thermal breaks can be composed of materials with low thermal conductivity, such as polyamide or polyurethane. Another technique is the incorporation of double or triple glazing in windows and doors. By integrating multiple layers of glass with an interstitial gap, the insulating properties are substantially enhanced, thereby reducing heat transfer through the aluminum frames. Furthermore, the application of low-emissivity (low-e) coatings on the glass surfaces can further augment the thermal insulation performance. These coatings reflect heat back into the interior while permitting visible light to pass through, resulting in improved energy efficiency. In conclusion, although aluminum profiles possess inherent limitations in terms of thermal insulation, they can still be effectively utilized in thermal insulation applications by incorporating thermal breaks, double or triple glazing, and low-e coatings. These measures aid in minimizing heat transfer and enhancing energy efficiency, rendering aluminum profiles suitable for various types of buildings.
- Q:Can aluminum profiles be used in the production of electronics?
- Yes, aluminum profiles can be used in the production of electronics. Aluminum is a lightweight, corrosion-resistant metal with excellent thermal conductivity, making it suitable for various electronic applications. It is commonly used in the construction of electronic enclosures and heat sinks. Aluminum profiles can be easily formed into different shapes and sizes, allowing for customization and flexibility in designing electronic components. Additionally, aluminum profiles are often used for electromagnetic shielding purposes due to their electrical conductivity. Overall, the use of aluminum profiles in electronics manufacturing offers numerous advantages such as durability, thermal management, and design versatility.
- Q:Can aluminum profiles be used in agricultural applications?
- Indeed, aluminum profiles find utility in agricultural applications. The strength, durability, and corrosion resistance of aluminum render it a perfect material for diverse agricultural structures and equipment. One can utilize it for constructing greenhouse frames, irrigation systems, grain storage bins, livestock housing, and beyond. Moreover, aluminum profiles possess a lightweight nature, simplifying their handling and installation procedures. Furthermore, their exceptional thermal conductivity facilitates efficient temperature regulation within agricultural settings. On the whole, aluminum profiles present a multitude of advantages and are progressively gaining popularity in the agricultural sector.
- Q:Can aluminum profiles be used in marine environments?
- Yes, aluminum profiles can be used in marine environments. Aluminum is often chosen for its excellent corrosion resistance and lightweight properties, making it ideal for marine applications. It is commonly used in the construction of boats, shipbuilding, and offshore structures due to its durability and ability to withstand exposure to saltwater and harsh weather conditions.
- Q:How do you prevent warping or distortion of aluminum profiles during fabrication?
- To prevent warping or distortion of aluminum profiles during fabrication, there are several key steps that can be taken: 1. Proper storage: Before fabrication, it is crucial to store aluminum profiles in a controlled environment with stable temperature and humidity levels. This helps to minimize any potential changes in the metal's shape or dimensions. 2. Correct handling: Aluminum profiles should be handled with care to avoid bending or twisting. This includes using appropriate lifting equipment, avoiding excessive force, and ensuring that the profiles are supported evenly during transportation. 3. Proper machining techniques: During fabrication, it is important to use appropriate machining techniques that minimize heat buildup. Excessive heat can cause the aluminum to expand and potentially warp. Cooling techniques like using lubricants or coolants can help dissipate heat and prevent distortion. 4. Controlled welding: When welding aluminum profiles, it is crucial to maintain proper control over the welding process. The use of appropriate welding techniques, such as preheating and post-weld heat treatment, can help minimize distortion. 5. Adequate fixturing: Using proper fixturing methods during fabrication helps ensure that the aluminum profiles are held in the correct position throughout the process. This prevents any unintended bending or warping that could occur due to improper support or clamping. 6. Stress-relieving: After fabrication, stress-relieving processes can be employed to minimize residual stresses within the aluminum profiles. This helps to prevent distortion or warping that may occur during subsequent handling or usage. 7. Quality control: Regular inspection and measurement of the aluminum profiles during fabrication can help identify any deviations from the desired specifications. This enables quick corrective actions to be taken, minimizing the risk of warping or distortion. By following these steps, manufacturers can significantly reduce the likelihood of warping or distortion in aluminum profiles during fabrication, ensuring the production of high-quality components or products.
- Q:What are the different machining options available for aluminum profiles?
- There are several machining options available for aluminum profiles, depending on the desired outcome and the specific requirements of the project. 1. Milling: Milling is a widely used technique for cutting and shaping aluminum profiles. It involves removing material from the workpiece using a rotating cutter. This process can create complex shapes and features such as slots, pockets, and contours. 2. Drilling: Drilling is a machining process that involves creating holes in the aluminum profiles. It is commonly used to attach components or to provide openings for various purposes. Drilling can be done manually or using CNC machines for precision and efficiency. 3. Turning: Turning is a machining process where a single-point cutting tool is used to remove material from a rotating workpiece. This technique is often used for cylindrical or symmetrical aluminum profiles to create features like threads, grooves, and chamfers. 4. Bending: Bending is a process that is used to reshape aluminum profiles by applying force to bend them into the desired shape. It is commonly used for creating curved or angled profiles for architectural or structural purposes. 5. Punching: Punching is a process that involves using a punch and die set to create holes or cutouts in the aluminum profiles. It is commonly used for creating openings for fasteners, connectors, or other components. 6. Sawing: Sawing is a machining process where a rotating blade is used to cut through the aluminum profile. It is commonly used for cutting aluminum profiles to specific lengths or for separating them into smaller sections. 7. Grinding: Grinding is a machining process that involves using an abrasive wheel to remove material from the aluminum profiles. It is commonly used for surface finishing, deburring, or to achieve tight tolerances on the profile's dimensions. Each machining option has its advantages and limitations, and the choice depends on factors such as the complexity of the desired shape, the required precision, and the material properties of the aluminum profiles. Careful consideration of these factors will help determine the most suitable machining option for a particular project.
- Q:Can aluminum profiles be used for modular storage systems?
- Yes, aluminum profiles can be used for modular storage systems. Aluminum is a lightweight and durable material that is commonly used in various industries, including storage and shelving systems. Its versatility allows for easy customization and the ability to create modular units that can be easily assembled, disassembled, and reconfigured as needed. Additionally, aluminum profiles provide a sleek and modern aesthetic to storage systems.
- Q:What are the different surface etching options for aluminum profiles?
- Some different surface etching options for aluminum profiles include chemical etching, mechanical etching, and laser etching. Chemical etching involves using a chemical solution to remove layers of the aluminum surface, creating a desired pattern or texture. Mechanical etching involves using abrasive materials or tools to physically remove material from the surface. Laser etching uses a laser beam to selectively remove material from the surface, creating precise and intricate designs.
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Aluminum extrusion for machine crossbeam
- Ref Price:
-
- Loading Port:
- China Main Port
- Payment Terms:
- TT OR LC
- Min Order Qty:
- -
- Supply Capability:
- -
OKorder Service Pledge
Quality Product, Order Online Tracking, Timely Delivery
OKorder Financial Service
Credit Rating, Credit Services, Credit Purchasing
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