Trane Aluminum Evaporator Coil

Hot Products

Coated Aluminium Coil for Aluminium Can End

Coated Embossed Aluminum Coils for coil storages 3105, H44

Mill Finished Aluminium Coil AA1100 for Building

Coated Aluminium Coil For Curtain Wall Materials Production

3104 5052 5182 Aluminum Coil for Beverage Can Body/ End Tab Stock

Diamond Pattern Embossed Aluminum Checkered Anti-Slip Coated Sheet and Coil

Mill Finished Aluminium Coil for Can End

Aluminum Coil suppliers Wholesale in China

Color prepainted aluminum panel sheet 3105H44

Laminated Raw Aluminum Coil From China 3003 H14

FAQ

Aluminum coils are formed into different shapes and profiles through a process known as metal forming. This involves applying force to the coil to change its shape and contour. There are several methods used for shaping aluminum coils, including rolling, bending, extrusion, and stamping. Rolling is the most common method used to shape aluminum coils. It involves passing the coil through a series of rollers that apply pressure to the metal, gradually changing its shape. This process can be done hot or cold, depending on the desired outcome. Hot rolling is typically used for thicker coils, while cold rolling is suitable for thinner ones. Bending is another method used to shape aluminum coils, especially when creating curved or angled profiles. This can be done manually or using specialized bending machines. By applying force, the coil is bent to the desired shape, creating curves or angles as needed. Bending is commonly used in applications such as HVAC systems, automotive components, and construction. Extrusion is a process where the aluminum coil is pushed through a die to create a specific cross-sectional shape. The coil is heated and forced through the die, which determines the final shape of the extrusion. This method is often used for creating complex profiles with consistent dimensions, such as window frames, door frames, and structural components. Stamping is a technique used to create precise shapes and patterns on the surface of aluminum coils. It involves pressing the coil against a die with the desired design, causing the metal to deform and take on the shape of the die. Stamping is commonly used for decorative purposes, such as creating patterns, logos, or text on aluminum sheets. Overall, aluminum coils can be formed into different shapes and profiles through a variety of metal forming methods such as rolling, bending, extrusion, and stamping. These processes allow for the customization and versatility of aluminum in various industries and applications.

Yes, aluminum coils are generally resistant to vibration. Due to their inherent strength and elasticity, aluminum coils can withstand vibrations and oscillations without significant deformation or damage. This property makes them suitable for various applications that involve mechanical movement or exposure to vibrations.

Kitchen utensils can indeed incorporate aluminum coils in their production. Aluminum is a favored material for kitchen utensils owing to its lightweight nature, durability, and ability to conduct heat. Aluminum coils are effortlessly malleable, allowing them to take on various forms and designs for utensils like pots, pans, baking trays, and even cutlery. Moreover, aluminum possesses resistance against corrosion, making it a suitable choice for contact with food and liquids. Nevertheless, it is essential to keep in mind that aluminum utensils may require a non-stick coating or a protective layer to prevent any adverse reactions with acidic or alkaline foods. Ultimately, owing to their adaptability and practicality, aluminum coils are extensively employed in the production of kitchen utensils.

The gauge of aluminum coils refers to the thickness of the aluminum sheet used to manufacture the coil. The gauge is typically measured in terms of its thickness, with a smaller gauge indicating a thicker sheet. The gauge of aluminum coils has a significant impact on their performance. Firstly, the gauge affects the strength and durability of the aluminum coil. Thicker gauges provide increased strength and resistance to bending or warping, making them suitable for applications that require robust and long-lasting coils. On the other hand, thinner gauges are more flexible but may be prone to damage or deformation, making them suitable for less demanding applications. Secondly, the gauge affects the thermal conductivity of the aluminum coil. Thicker gauges have lower thermal conductivity, meaning they are slower to heat up or cool down. This can be advantageous in certain applications where temperature control is crucial, as it helps to maintain a stable environment. Thinner gauges, on the other hand, have higher thermal conductivity, allowing for faster heat transfer. This can be beneficial in applications that require rapid heating or cooling. Thirdly, the gauge affects the weight and cost of the aluminum coil. Thicker gauges are heavier and generally more expensive due to the increased amount of material used. This can be a consideration in applications where weight or cost is a significant factor. Thinner gauges, being lighter and less expensive, can be more suitable for applications where weight reduction or cost efficiency is important. Lastly, the gauge affects the ease of fabrication and formability of the aluminum coil. Thinner gauges are more easily bent, shaped, or formed into desired configurations, making them suitable for applications that require intricate or complex designs. Thicker gauges, while less malleable, can still be formed but may require specialized equipment or processes. In conclusion, the gauge of aluminum coils has a direct impact on their performance. It affects their strength, durability, thermal conductivity, weight, cost, and formability. Therefore, selecting the appropriate gauge for a specific application is essential to ensure optimal performance and efficiency.

The durability of roofs and facades is greatly enhanced by aluminum coils, thanks to their inherent properties and design characteristics. Firstly, aluminum's resistance to corrosion makes it an ideal material for roofs and facades that are constantly exposed to harsh weather conditions. This corrosion resistance ensures that the coils remain unaffected by moisture, UV rays, and extreme temperatures, thus extending the lifespan of the entire roofing or facade system. Moreover, aluminum coils provide structural integrity to roofs and facades while being lightweight. This lightweight nature simplifies the installation process and reduces the load on the building's structure, which is particularly advantageous for larger structures. Despite their lightness, aluminum coils have high tensile strength, enabling them to withstand significant loads and pressure without warping or deforming. This strength enhances the overall stability and durability of the roof or facade, ensuring resistance against external forces like wind, snow, and hail. Furthermore, aluminum coils are highly malleable, allowing for easy customization during the manufacturing process. This flexibility enables the coils to be shaped and formed to fit various architectural designs, resulting in a seamless and aesthetically pleasing appearance. The ability to customize the coils also facilitates efficient installation, as they can be tailored to fit different dimensions, angles, and contours of roofs or facades. Additionally, aluminum is a non-combustible material, which makes it an excellent choice for roofs and facades in terms of fire safety. The non-combustible nature of aluminum coils greatly reduces the risk of fire spreading, providing an extra layer of protection to both the building and its occupants. In conclusion, aluminum coils significantly contribute to the durability of roofs and facades by offering corrosion resistance, lightweight yet high tensile strength, malleability for customization, and non-combustibility. These properties ensure that the roof or facade can withstand the test of time, harsh weather conditions, and external forces, making aluminum coils a reliable and long-lasting choice for any building structure.

Indeed, heat exchanger fins can utilize aluminum coils. Aluminum is widely preferred for heat exchangers owing to its remarkable thermal conductivity, lightweight properties, and resistance to corrosion. By incorporating aluminum coils into heat exchanger fins, the transfer of heat between two fluids becomes highly efficient, making it an ideal material for this specific purpose. Moreover, aluminum coils can be effortlessly shaped into different fin configurations, which allows for design flexibility and maximizes the surface area for heat transfer. All in all, aluminum coils are commonly employed in heat exchanger fins to boost heat transfer efficiency and enhance the overall performance of the heat exchanger system.

i know that your not suppose to use DC for aluminum only with AC but is it possible?

Yes you can use the following settings with the following particularities: 1. DC+ (positive at the electrode) - This setting will provide you with lower penetration of the weld and high wear of the electrode (70% of the heat is at the (+) pole and 30% of the heat is at the( -)) The definite advantage of this setting is that the aluminum oxides are cleaned during welding by the eletric arc from the parts you are welding and the weld is a high quality clean weld that looks very good and appealing. In order to avoid premature wear (or even melting) of the electrode try to weld with lower amperage. 2. DC- (negative at the electrode) - This setting is reversed compared to the first one. Because of the 70% of the heat at the (+) pole the penetration is good, the electrode preserves very well but you don't get the cleaning effect of the electric arc during welding. If you choose this setting then you will have to clean thoroughly the material right before welding. The weld won't be as appealing as the one obtained with the first setting. 3. AC actually combines the DC+ and DC- because half the time the electrode is (-) and half the time is (+). This is the best setting you can have for TIG Aluminum welding using Argon as shielding gas. Remember the cleaning action works only with Argon. I hope this helps.

I take an extracurricular aircraft class, and I got the okay to take some old painted sheet aluminum for another project I'm working on. The problem is, what I'm using it for I need bare aluminum. I heard around that air crafts are painted with something that regular (store-bought) paint stripper can't remove. Is this true? I am aware of the fact that stripping something like that will result in a toxic paint sludge, so I've taken precautions for that. I just need to know if heavy-duty paint stripper from Home Depot will do the job. Thanks :)

It depends on how old the paint is. If your panel was painted before the 1970's, then pretty much any chemical paint stripper will work. After the 70's, they started using epoxy based primers and paints and those are more resistant to chemical strippers. In any case, wear rubber gloves and breathing protection while using chemical paint strippers. They can burn your skin and create toxic fumes when in use.