Type | Chemical Composition | |||||||||
AWSA5.1 | AWS A5.1M | C | Mn | Si | P | S | Ni | Cr | Mo | V |
E6011 E6013 | E4311 E4313 | ≤0.20 | ≤1.20 | ≤1.00 | ... | ... | ≤0.30 | ≤0.20 | ≤0.30 | ≤0.08 |
E7016 E7018 | E4916 E4918 | ≤0.15 | ≤1.60 | ≤0.75 | ≤0.035 | ≤0.035 | ≤0.30 | ≤0.20 | ≤0.30 | ≤0.08 |
E7018M | E4918M | ≤0.12 | 0.40~1.60 | ≤0.80 | ≤0.030 | ≤0.020 | ≤0.25 | ≤0.15 | ≤0.35 | ≤0.05 |
E308-16 E308L-16 | E308-17 E308L-17 | ≤0.08 | 0.50~2.50 | ≤1.00 | ≤0.04 | ≤0.03 | 9.0~11.0 | 18.0~21.0 | ≤0.75 | Cu ≤0.75 |
≤0.04 | ||||||||||
E309 -16 E309L-16 | E309-17 E316-17 | ≤0.15 | 0.50~2.50 | ≤1.00 | ≤0.04 | ≤0.03 | 12.0~14.0 | 22.0~25.0 | ≤0.75 | Cu ≤0.75 |
≤0.04 | ||||||||||
E316-16 E316-16 | E316L-17 E309L-17 | ≤0.08 | 0.50~2.50 | ≤1.00 | ≤0.04 | ≤0.03 | 11.0~14.0 | 17.0~20.0 | 2.0~ 3.0 | Cu ≤0.75 |
≤0.04 | ||||||||||
E312-16 | E312-17 | ≤0.15 | 0.50~2.50 | ≤1.00 | ≤0.04 | ≤0.03 | 8.0~10.5 | 28.0~32.0 | ≤0.75 | Cu ≤0.75 |
Note: E7016 and E7018 components of Mn+Ni+Cr+Mo+VS1.75;stainless steel electrode code interpretation - example E308-XX (E308-15/E308-16/E308-17/E308-26…...), the prefix code isdivided into -1/-2/-4, representing the welding position; the suffix code is divided into -5l-6/-7,in which 5 represents the alkalinity, 6 represents rutile,and 7 represents the titanic acid type. |
Type | Mechanical Properties | ||||||
AWSA5.1 | AWS A5.1M | Tensile Strength Mpa | Yield Strength Mpa | Elongation A (%) | Impact Value | Radio graphics | |
KV2(J) -45℃ | KV2 ()-30℃ | ||||||
E6011 | E4311 | ≥430 | ≥330 | ≥22 | ... | ≥ 27 | Grade ll |
E6013 | E4313 | ≥430 | ≥330 | ≥17 | ... | ... | |
E7016 | E4916 | ≥490 | ≥400 | ≥22 | ≥ 27 | ≥ 27 | Grade l |
E7018 | E4918 | ≥490 | ≥400 | ≥22 | ≥ 27 | ≥ 27 | |
E7018M | E4918M | Normal ≥ 490 | 370~500 | ≥24 | ... | ≥ 67 | |
2.4MM/370~530 | |||||||
E308-XX | ≥550 | ≥30 | |||||
E308L-XX | ≥520 | ||||||
E309-XX | ≥550 | ||||||
E309L-XX | ≥520 | ||||||
E316-XX | ≥520 | ||||||
E316L-XX | ≥490 | ||||||
E312-XX | ≥ 660 | ≥22 | |||||
Note: E6011 has no special requirements for heat preservation furnace and drvina: Environmental temperature: 20~ 40 C;The requirement of E6013 heat preservation furnace is higher than theambient temperature [10C ~20C];Drying requires drying at least 1 hour at 120 C150 C;E7016/E7018/E7018M requirements for heat preservation furnace and drying; Environmentaltemperature: [30C~140C];Drying requires drying at least 1~2 hours at 260℃~425℃; |
mm: 0.8mm / 0.9mm / 1.0mm / 1.2mm/ 1.6mm
inch: 0.030 / 0.035 / 0.040 / 0.045/ 3/16 - 3/64
mm: 1.2mm/ 1.6mm/ 2.0mm/ 2.4mm/ 3.2mm/ 4.0mm
An aluminum welding wire factory is a specialized manufacturing facility that produces aluminum welding wire for various welding processes, such as MIG (Metal Inert Gas) and TIG (Tungsten Inert Gas) welding.
These factories create high-quality aluminum wires used in industries like automotive, aerospace, and marine for joining aluminum components.
The production involves precise alloy formulation, wire drawing, and quality control to meet industry standards.
Factories produce a range of aluminum welding wires, including common alloys like 4043, 5356, and 1100, each suited for specific applications.
For example, 4043 is ideal for general-purpose welding, while 5356 offers higher strength for structural applications.
Factories may also customize wire compositions to meet unique project requirements, ensuring optimal weld performance.
Aluminum welding wire production involves several key steps to ensure quality and consistency.
Raw aluminum is melted and alloyed with elements like silicon or magnesium, then extruded into thin rods.
These rods are drawn into precise wire diameters, cleaned, and spooled for distribution.
Advanced factories employ automated systems and rigorous testing to ensure the wire meets standards like AWS (American Welding Society) specifications.
Quality control is critical in aluminum welding wire factories.
Manufacturers conduct tests for tensile strength, chemical composition, and surface cleanliness to prevent weld imperfections.
Automated inspection systems and certifications, such as ISO 9001, ensure consistency.
Reputable factories also provide batch traceability to guarantee reliability for end-users.
Aluminum welding wire is essential for industries requiring lightweight, corrosion-resistant welds.
The automotive industry uses it for vehicle frames and body panels, while aerospace relies on it for aircraft components.
Marine applications benefit from aluminum’s resistance to saltwater corrosion.
Other sectors, such as construction and electronics, also utilize aluminum welding wire for its versatility and durability.
Yes, many aluminum welding wire factories offer customized solutions for niche applications.
They can produce wires with specific alloy compositions or diameters tailored to unique welding needs, such as high-strength aerospace welds or thin-gauge electronics welding.
Consulting with the factory’s technical team ensures the wire matches project specifications.
Proper storage of aluminum welding wire is essential to maintain its performance.
Factories recommend storing wire in a dry, temperature-controlled environment to prevent oxidation and contamination.
Airtight packaging or sealed containers help protect against moisture and dust.
Users should avoid prolonged exposure to air, as aluminum wire can develop oxide layers that affect weld quality.
Improper storage can lead to surface contamination or oxidation, causing issues like porosity or poor arc stability during welding.
Contaminated wire may produce weak welds or require additional cleaning before use.
Factories often provide storage guidelines with their products to help users maintain wire integrity.
Reputable aluminum welding wire factories adhere to strict environmental regulations to minimize their ecological footprint.
They implement waste management systems, recycle aluminum scrap, and use energy-efficient production methods.
Many facilities comply with standards like ISO 14001 for environmental management.
Choosing a factory with sustainable practices supports eco-friendly welding operations.