Aluminum is available in several alloy series, and each one behaves differently during manufacturing. Some grades machine cleanly, some bend without cracking, and some maintain strength after welding. These differences affect material selection long before production starts.
Engineers usually narrow the material choice after reviewing the part geometry, loading conditions, corrosion exposure, and manufacturing process. Selecting an unsuitable alloy can increase machining time, create forming defects, complicate welding, and add unnecessary production steps. Therefore, understanding the characteristics of each aluminum alloy series supports better design decisions and smoother production planning.
The following sections compare the common aluminum alloy series, their characteristics, and the applications for which they are commonly selected.
1000 Series Aluminum: Commercially Pure Aluminum for Forming and Electrical Applications
The 1000 series contains commercially pure aluminum with very few alloying additions. Since aluminum makes up at least 99% of the composition, these alloys retain excellent corrosion resistance, electrical conductivity, and thermal conductivity. However, their low strength limits their use in structural components that carry continuous mechanical loads.
During manufacturing, the 1000 series performs well in bending, deep drawing, spinning, stamping, and rolling operations. Soft material properties also produce smooth surface finishes after forming. However, CNC machining requires careful cutting conditions because the material tends to form built-up edges on cutting tools.
The composition mainly consists of aluminum with controlled amounts of iron and silicon. Other alloying elements remain at very low levels to preserve conductivity and corrosion resistance rather than increasing strength.
Common 1000 Series Aluminum Grades
| Grade | Main Composition (Typical) | Tensile Strength (MPa) | Yield Strength (MPa) | Electrical Conductivity (% IACS) | Corrosion Resistance | Machinability | Weldability | Relative Cost | Common Applications |
| 1050 | Al ≥99.5%, Fe, Si | 75 – 110 | 20 – 35 | 61 – 63 | Excellent | Fair | Excellent | $$ | Reflectors, food processing equipment, architectural panels |
| 1060 | Al ≥99.6%, Fe, Si | 70 – 110 | 25 – 35 | 61 – 63 | Excellent | Fair | Excellent | $$ | Busbars, chemical tanks, heat exchangers |
| 1070 | Al ≥99.7%, Fe, Si | 60 – 95 | 20 – 30 | 64 – 66 | Excellent | Fair | Excellent | $$ | Electrical conductors, capacitor foil |
| 1085 | Al ≥99.85%, Fe | 55 – 90 | 15 – 25 | 65 – 67 | Excellent | Fair | Excellent | $$$ | Optical reflectors, lighting products |
| 1100 | Al ≥99.0%, Cu, Fe, Si | 90 – 140 | 35 – 55 | 58 – 60 | Excellent | Fair | Excellent | $$ | Cookware, storage vessels, sheet metal parts |
| 1350 | Al ≥99.5%, Si, Fe | 70 – 95 | 20 – 30 | 61 – 62 | Excellent | Fair | Excellent | $$$ | Power transmission conductors, electrical busbars |
Physical and Mechanical Properties of the 1000 Series
| Property | Typical Value |
| Density | 2.70 g/cm³ |
| Elastic Modulus | 69 GPa |
| Melting Range | 643 – 657°C |
| Thermal Conductivity | 220 – 235 W/m·K |
| Electrical Conductivity | 58 – 67% IACS |
| Coefficient of Thermal Expansion | 23.5 – 24.0 ×10⁻⁶/°C |
| Hardness | 20 – 35 HB |
| Tensile Strength | 60 – 140 MPa |
| Yield Strength | 15 – 55 MPa |
| Elongation | 20 – 45% |
Manufacturing Characteristics
| Characteristic | Performance |
| CNC Milling | Fair |
| CNC Turning | Fair |
| Drilling | Good |
| Tapping | Fair |
| Forming | Excellent |
| Deep Drawing | Excellent |
| Rolling | Excellent |
| Welding | Excellent |
| Brazing | Good |
| Anodizing | Excellent |
| Surface Finish | Excellent |
| Corrosion Resistance | Excellent |
Selection Notes
Select the 1000 series for components that benefit from high electrical conductivity, thermal conductivity, corrosion resistance, and extensive forming operations. These alloys are commonly specified for electrical busbars, conductor systems, chemical processing equipment, storage tanks, heat exchangers, reflective panels, and decorative sheet products.
For CNC-machined brackets, shafts, structural supports, high-load assemblies, wear components, and precision mechanical parts, stronger aluminum alloy series generally provide better performance because the 1000 series has limited mechanical strength and lower machining characteristics.
2000 Series Aluminum: Copper-Alloyed Aluminum for High-Load Components
The 2000 series uses copper as the primary alloying element to increase strength and fatigue performance. Compared with commercially pure aluminum, these alloys withstand much higher mechanical loads, making them suitable for structural components that experience repeated loading. However, the higher copper content reduces natural corrosion resistance, so protective surface treatments are commonly applied before service.
Manufacturers frequently machine the 2000 series into brackets, fittings, structural frames, forgings, and aerospace components. Most grades produce good machining results, although welding is limited for several alloys because the heat-affected zone can reduce joint strength. Therefore, mechanical fastening, riveting, and bolted assemblies remain common joining methods for many applications.
Besides copper, small amounts of magnesium, manganese, silicon, and iron contribute to the final mechanical properties. Heat treatment further increases strength, allowing these alloys to achieve one of the highest strength levels among wrought aluminum families.
Common 2000 Series Aluminum Grades
| Grade | Main Composition (Typical) | Tensile Strength (MPa) | Yield Strength (MPa) | Fatigue Resistance | Corrosion Resistance | Machinability | Weldability | Relative Cost | Common Applications |
| 2011 | Al, 5.0 – 6.0% Cu, Bi, Pb | 345 – 395 | 275 – 310 | Good | Fair | Excellent | Poor | $$$ | Precision CNC parts, fittings, screw machine products |
| 2014 | Al, 3.9 – 5.0% Cu, Si, Mn, Mg | 430 – 485 | 290 – 415 | Excellent | Fair | Good | Poor | $$$ | Aircraft fittings, heavy-duty forgings, structural plates |
| 2017A | Al, 3.5 – 4.5% Cu, Mg, Mn | 380 – 450 | 220 – 280 | Good | Fair | Good | Fair | $$$ | Fasteners, mechanical components, transport equipment |
| 2024 | Al, 3.8 – 4.9% Cu, Mg, Mn | 470 – 490 | 320 – 345 | Excellent | Fair | Good | Poor | $$$ | Aircraft skins, wing structures, and structural frames |
| 2124 | Al, Cu, Mg, Mn (controlled impurities) | 460 – 485 | 320 – 350 | Excellent | Fair | Good | Poor | $$$$ | Aerospace plates, fracture-critical structures |
| 2219 | Al, 5.8 – 6.8% Cu, Mn, V, Zr | 340 – 455 | 220 – 350 | Good | Fair | Good | Good | $$$$ | Cryogenic tanks, rocket structures, pressure vessels |
Physical and Mechanical Properties of the 2000 Series
| Property | Typical Value |
| Density | 2.77 – 2.84 g/cm³ |
| Elastic Modulus | 72 – 73 GPa |
| Melting Range | 500 – 640°C |
| Thermal Conductivity | 120 – 170 W/m·K |
| Electrical Conductivity | 30 – 40% IACS |
| Coefficient of Thermal Expansion | 22.0 – 23.2 ×10⁻⁶/°C |
| Hardness | 95 – 150 HB |
| Tensile Strength | 340 – 490 MPa |
| Yield Strength | 220 – 415 MPa |
| Elongation | 8 – 20% |
Manufacturing Characteristics
| Characteristic | Performance |
| CNC Milling | Excellent |
| CNC Turning | Excellent |
| Drilling | Excellent |
| Tapping | Good |
| Forming | Fair |
| Forging | Excellent |
| Welding | Fair to Poor* |
| Anodizing | Good |
| Surface Finish | Good |
| Corrosion Resistance | Fair |
| Heat Treatability | Excellent |
Weldability depends on the alloy grade. Grade 2219 supports fusion welding much better than grades such as 2024 and 2014.
Selection Notes
Select the 2000 series for structural components that experience high static loads, cyclic loading, and demanding service conditions. These alloys are widely specified for aerospace structures, aircraft fittings, suspension components, military equipment, precision-machined parts, heavy-duty fixtures, and forged mechanical assemblies.
Grade selection depends on manufacturing priorities. 2011 provides excellent machinability for high-volume CNC production. 2014 delivers high structural strength for forged components. 2024 remains a preferred choice for fatigue-loaded aircraft structures. 2219 combines high strength with good weldability and maintains mechanical properties at elevated temperatures, making it suitable for pressure vessels and space hardware. 2124 offers improved fracture toughness for critical aerospace applications.
3000 Series Aluminum: Manganese-Alloyed Aluminum for Sheet Metal Fabrication
Many aluminum sheet products are manufactured from the 3000 series because these alloys handle forming operations without creating frequent production issues. Components such as roofing panels, heat exchangers, cookware, storage tanks, and beverage cans often pass through several bending, rolling, stamping, and drawing operations before reaching their final shape. This series accommodates those processes while maintaining good corrosion resistance.
Unlike the 2000 and 7000 series, the 3000 family is not intended for heavily loaded structural parts. Instead, it fills the gap between commercially pure aluminum and higher-strength alloys. Manganese increases strength without making the material difficult to form, which explains why fabricators frequently specify it for thin-gauge products.
Cold working provides most of the strength improvement in this series because heat treatment does not significantly increase mechanical properties. Therefore, tempers such as H14, H16, and H18 are common for finished sheet products.
Common 3000 Series Aluminum Grades
| Grade | Main Alloy Composition | Tensile Strength (MPa) | Yield Strength (MPa) | Corrosion Resistance | Machinability | Weldability | Formability | Relative Cost | Typical Applications |
| 3003 | Al, 1.0–1.5% Mn, Cu | 110 – 200 | 40 – 145 | Excellent | Fair | Excellent | Excellent | $$ | Cookware, storage tanks, HVAC equipment, sheet metal parts |
| 3004 | Al, 1.0–1.5% Mn, 0.8–1.3% Mg | 180 – 285 | 70 – 240 | Excellent | Fair | Excellent | Excellent | $$ | Beverage cans, fuel tanks, lightweight panels |
| 3105 | Al, 0.3–0.8% Mg, 0.3–0.8% Mn | 170 – 250 | 120 – 205 | Excellent | Fair | Excellent | Excellent | $$ | Roofing, siding, gutters, architectural panels |
| 3A21 | Al, Mn, Cu (GB standard) | 140 – 190 | 60 – 110 | Excellent | Fair | Excellent | Excellent | $$ | Chemical tanks, transportation equipment, and fabricated structures |
Physical and Mechanical Properties
| Property | Typical Value |
| Density | 2.72 – 2.74 g/cm³ |
| Elastic Modulus | 69 GPa |
| Melting Range | 640 – 655°C |
| Thermal Conductivity | 160 – 195 W/m·K |
| Electrical Conductivity | 40 – 50% IACS |
| Coefficient of Thermal Expansion | 23.2 – 23.8 ×10⁻⁶/°C |
| Hardness | 35 – 70 HB |
| Tensile Strength | 110 – 285 MPa |
| Yield Strength | 40 – 240 MPa |
| Elongation | 10 – 30% |
Manufacturing Characteristics
Fabrication shops generally process the 3000 series through sheet metal operations instead of extensive CNC machining. Softer material characteristics simplify bending and drawing, although they can produce built-up edges during milling if cutting parameters are not adjusted. Welding also presents few difficulties for most fabrication work.
| Process | Performance |
| CNC Milling | Fair |
| CNC Turning | Fair |
| Laser Cutting | Excellent |
| Punching | Excellent |
| Bending | Excellent |
| Deep Drawing | Excellent |
| Rolling | Excellent |
| Welding | Excellent |
| Brazing | Good |
| Anodizing | Good |
| Heat Treatment | Not Applicable |
Material Selection Notes
The intended manufacturing process usually narrows the material choice within this series. 3003 remains the standard option for general sheet metal fabrication because it combines good corrosion resistance with consistent forming performance. 3004 provides additional strength through magnesium, making it suitable for beverage containers and lightweight structural panels that experience higher service loads. Building products such as roofing, gutters, and siding frequently use 3105 because it performs well during roll forming and outdoor exposure. 3A21 follows the Chinese GB standard and serves similar fabrication applications across transportation equipment, storage vessels, and industrial sheet metal products.
4000 Series Aluminum: Silicon-Based Alloys for Welding and Brazing
Most engineers encounter the 4000 series during welding and brazing instead of structural part production. These alloys contain silicon, which lowers the melting temperature and improves molten metal flow. As a result, they produce smooth weld beads, reduce cracking, and create sound joints across many aluminum assemblies.
Unlike high-strength structural alloys, the 4000 series mainly serves as filler material. Automotive heat exchangers, HVAC equipment, refrigeration systems, and fabricated aluminum assemblies frequently use these alloys during joining operations. Some grades also contain additional elements that improve wear resistance, making them suitable for pistons and moving mechanical parts.
Silicon generally ranges from about 4% to 13%, depending on the alloy grade. This composition influences melting behavior, fluidity, shrinkage during solidification, and the appearance of the finished weld.
Common 4000 Series Aluminum Grades
| Grade | Main Alloy Composition | Tensile Strength (MPa)* | Primary Advantage | Machinability | Weldability | Relative Cost | Typical Applications |
| 4006 | Al, Si | 150 – 220 | Good wear resistance | Good | Good | $$ | Engine components, cast parts |
| 4015 | Al, Si | 160 – 230 | Improved casting performance | Good | Good | $$ | Automotive castings, industrial components |
| 4032 | Al, 11 -13.5% Si, Mg, Cu, Ni | 315 – 380 | Low thermal expansion, wear resistance | Excellent | Fair | $$$ | Pistons, compressor parts, precision-machined components |
| 4043 | Al, 4.5 – 6.0% Si | 170 – 230 (weld deposit) | Stable welding performance | N/A | Excellent | $$ | GTAW, GMAW filler wire |
| 4045 | Al, 9 – 11% Si | – | Low melting temperature | N/A | Excellent | $$ | Brazing sheet, heat exchangers |
| 4047 | Al, 11 – 13% Si | – | High fluidity, low shrinkage | N/A | Excellent | $$$ | Vacuum brazing, automotive assemblies |
| 4343 | Al, 6.8 – 8.2% Si | – | Controlled brazing characteristics | N/A | Excellent | $$ | Radiators, condensers, evaporators |
*Mechanical values mainly apply to wrought products. Welding and brazing fillers are generally selected based on joining characteristics rather than parent-metal strength.
Physical and Mechanical Properties
| Property | Typical Value |
| Density | 2.66 – 2.69 g/cm³ |
| Elastic Modulus | 69 – 71 GPa |
| Melting Range | 573 – 635°C (grade dependent) |
| Thermal Conductivity | 120 – 170 W/m·K |
| Electrical Conductivity | 38 – 48% IACS |
| Hardness | 45 – 120 HB |
| Tensile Strength | 150 – 380 MPa |
| Yield Strength | 90 – 315 MPa |
| Coefficient of Thermal Expansion | 19 – 22 ×10⁻⁶/°C |
Manufacturing Considerations
The 4000 series supports joining processes more frequently than conventional machining. Grades such as 4043, 4045, 4047, and 4343 are selected according to melting temperature, fluidity, and compatibility with the parent alloy. 4032 differs from the rest because it is manufactured into finished components that require good wear resistance and dimensional stability.
| Manufacturing Process | Performance |
| GTAW (TIG) Welding | Excellent |
| GMAW (MIG) Welding | Excellent |
| Furnace Brazing | Excellent |
| Vacuum Brazing | Excellent |
| Casting | Good |
| CNC Milling | Good (4032) |
| CNC Turning | Excellent (4032) |
| Wear Resistance | Good to Excellent |
| Heat Treatment | Limited (Grade dependent) |
| Corrosion Resistance | Good |
Choosing the Right 4000 Series Alloy
The joining process usually determines the alloy selection. 4043 remains the standard filler for welding many heat-treatable aluminum alloys because it flows smoothly and reduces weld cracking. Brazing applications frequently specify 4045 and 4343, both of which provide lower melting temperatures for controlled joining without affecting the surrounding material. 4047 produces excellent fluidity and fills narrow joints effectively, making it suitable for precision brazed assemblies. Unlike these filler alloys, 4032 is selected for machined components such as pistons and compressor parts because its high silicon content improves wear resistance and limits thermal expansion.
5000 Series Aluminum: Magnesium Alloys for Marine and Fabricated Structures
Marine equipment, storage tanks, pressure vessels, and transportation bodies frequently use the 5000 series because these alloys combine good mechanical strength with excellent corrosion resistance. Magnesium strengthens the material without requiring heat treatment, allowing fabricators to produce welded assemblies while maintaining consistent mechanical properties.
Many components in this series begin as sheet, plate, and extruded products. Fabrication usually involves laser cutting, bending, rolling, and welding rather than extensive machining. This combination makes the 5000 series a common choice for large welded structures that operate in coastal, offshore, and industrial environments.
Magnesium is the primary alloying element and typically ranges from about 2% to 5.5%. Some grades also include manganese and chromium to improve strength and resistance to stress corrosion cracking.
Common 5000 Series Aluminum Grades
| Grade | Main Alloy Composition | Tensile Strength (MPa) | Yield Strength (MPa) | Corrosion Resistance | Machinability | Weldability | Relative Cost | Typical Applications |
| 5005 | Al, 0.5 – 1.1% Mg | 125 – 185 | 55 – 145 | Excellent | Fair | Excellent | $$ | Architectural panels, anodized products, curtain walls |
| 5052 | Al, 2.2 – 2.8% Mg, Cr | 195 – 290 | 90 – 255 | Excellent | Good | Excellent | $$ | Fuel tanks, marine panels, sheet metal parts |
| 5083 | Al, 4.0 – 4.9% Mg, Mn, Cr | 275 – 350 | 125 – 275 | Outstanding | Fair | Excellent | $$$ | Ship hulls, pressure vessels, cryogenic tanks |
| 5086 | Al, 3.5 – 4.5% Mg, Mn | 290 – 340 | 125 – 240 | Outstanding | Fair | Excellent | $$$ | Marine structures, bridges, and transportation equipment |
| 5251 | Al, 1.7 – 2.4% Mg, Mn | 180 – 260 | 80 – 180 | Excellent | Good | Excellent | $$ | Fabricated sheet components, vehicle panels |
| 5454 | Al, 2.4 – 3.0% Mg, Mn | 240 – 310 | 110 – 240 | Excellent | Good | Excellent | $$$ | Road tankers, pressure vessels, chemical storage tanks |
| 5754 | Al, 2.6 – 3.6% Mg | 190 – 280 | 80 – 220 | Excellent | Good | Excellent | $$ | Flooring, tread plate, automotive body panels |
Physical and Mechanical Properties
| Property | Typical Value |
| Density | 2.66 – 2.68 g/cm³ |
| Elastic Modulus | 69 – 71 GPa |
| Melting Range | 570 – 645°C |
| Thermal Conductivity | 120 – 150 W/m·K |
| Electrical Conductivity | 30 – 38% IACS |
| Hardness | 55 – 95 HB |
| Tensile Strength | 180 – 350 MPa |
| Yield Strength | 80 – 275 MPa |
| Elongation | 10 – 25% |
| Coefficient of Thermal Expansion | 23 – 24 ×10⁻⁶/°C |
Manufacturing Considerations
Fabrication shops select the 5000 series for welded structures because the material maintains good joint properties after welding. Forming operations also produce consistent results across most grades, particularly for sheet and plate products. CNC machining remains practical for secondary operations, although these alloys are better suited to fabrication than to high-volume precision machining.
| Manufacturing Process | Performance |
| CNC Milling | Good |
| CNC Turning | Good |
| Laser Cutting | Excellent |
| Waterjet Cutting | Excellent |
| Bending | Excellent |
| Rolling | Excellent |
| Welding | Excellent |
| Anodizing | Excellent |
| Marine Service | Excellent |
| Heat Treatment | Not Heat Treatable |
Selecting the Right 5000 Series Alloy
Application requirements usually determine the grade selection. 5052 remains one of the most common choices for sheet metal fabrication because it combines good formability with excellent corrosion resistance. 5083 provides the highest strength within this family and is widely specified for shipbuilding, offshore structures, and pressure vessels operating in aggressive environments. 5086 performs well in large welded assemblies that require additional structural strength. 5754 is frequently selected for flooring panels, vehicle bodies, and formed components, while 5005 produces uniform anodized finishes for architectural products. 5454 performs well in elevated-temperature storage tanks and road tankers that transport chemicals and industrial liquids.
6000 Series Aluminum: Balanced Strength for Structural and Extruded Components
Many structural products made from aluminum belong to the 6000 series. Machine frames, automation equipment, construction profiles, bicycle frames, and support brackets commonly use these alloys because they combine good mechanical strength with straightforward machining, welding, and corrosion resistance.
Magnesium and silicon form magnesium silicide during heat treatment, increasing strength without making fabrication difficult. This balance makes the 6000 series one of the most widely specified aluminum families for general engineering applications.
Common 6000 Series Aluminum Grades
| Grade | Main Alloy Composition | Tensile Strength (MPa) | Yield Strength (MPa) | Machinability | Weldability | Relative Cost | Typical Applications |
| 6005 | Al, Mg, Si | 260 – 320 | 220 – 270 | Good | Excellent | $$ | Structural profiles, ladders, transport equipment |
| 6005A | Al, Mg, Si | 260 – 350 | 220 – 300 | Good | Excellent | $$ | Bridges, industrial extrusions |
| 6061 | Al, Mg, Si, Cu | 290 – 340 | 240 – 280 | Excellent | Excellent | $$ | CNC parts, machine frames, fixtures, and bicycle frames |
| 6063 | Al, Mg, Si | 180 – 245 | 140 – 210 | Good | Excellent | $$ | Windows, doors, furniture, architectural profiles |
| 6082 | Al, Mg, Si, Mn | 310 – 340 | 250 – 300 | Excellent | Good | $$$ | Bridges, cranes, transportation structures |
| 6262 | Al, Mg, Si, Pb, Bi | 310 – 360 | 240 – 290 | Excellent | Fair | $$$ | Precision machined parts, fittings, and screw machine products |
Physical and Mechanical Properties
| Property | Typical Value |
| Density | 2.70 g/cm³ |
| Elastic Modulus | 69 GPa |
| Thermal Conductivity | 150 – 180 W/m·K |
| Hardness | 60 – 110 HB |
| Tensile Strength | 180 – 360 MPa |
| Yield Strength | 140 – 300 MPa |
| Corrosion Resistance | Good to Excellent |
| Heat Treatment | Heat Treatable |
Manufacturing Considerations
| Manufacturing Process | Performance |
| CNC Milling | Excellent |
| CNC Turning | Excellent |
| Extrusion | Excellent |
| Bending | Good |
| Welding | Excellent |
| Anodizing | Excellent |
Selecting the Right 6000 Series Alloy
6061 remains the standard choice for CNC machining and structural components because it balances strength, machinability, and weldability. 6063 produces smoother surface finishes after extrusion and is widely used for architectural products. 6082 provides higher structural strength for heavy-duty applications, particularly in Europe. 6005 and 6005A suit structural extrusions, while 6262 is preferred for precision-machined components that require excellent chip control.
Reference basis: Property ranges are compiled from The Aluminum Association, ASM International, MatWeb, AZoM, and manufacturer technical data sheets. Values vary with temper designation.
7000 Series Aluminum: Zinc Alloys for High-Strength Engineering Components
Weight-sensitive structures with high mechanical loads frequently use the 7000 series. Zinc is the primary alloying element, producing some of the strongest commercially available aluminum alloys after heat treatment. These materials are commonly specified for aerospace components, defense equipment, molds, sporting goods, and high-performance mechanical assemblies.
Higher strength comes with some trade-offs. Several grades have lower weldability and require additional attention to corrosion protection during service.
Common 7000 Series Aluminum Grades
| Grade | Main Alloy Composition | Tensile Strength (MPa) | Yield Strength (MPa) | Machinability | Weldability | Relative Cost | Typical Applications |
| 7049 | Al, Zn, Mg, Cu | 500 – 570 | 430 – 500 | Good | Poor | $$$$ | Aircraft fittings, hydraulic components |
| 7050 | Al, Zn, Mg, Cu, Zr | 510 – 580 | 430 – 510 | Good | Poor | $$$$ | Aircraft bulkheads, fuselage frames |
| 7068 | Al, Zn, Mg, Cu | 640 – 710 | 590 – 650 | Excellent | Poor | $$$$ | High-strength aerospace and defense parts |
| 7075 | Al, Zn, Mg, Cu | 510 – 570 | 430 – 505 | Excellent | Poor | $$$ | Aircraft structures, molds, and performance equipment |
| 7085 | Al, Zn, Mg, Cu | 520 – 590 | 450 – 540 | Good | Poor | $$$$ | Thick aerospace plates, structural forgings |
| 7150 | Al, Zn, Mg, Cu | 530 – 590 | 460 – 540 | Good | Poor | $$$$ | Wing structures, aerospace forgings |
Physical and Mechanical Properties
| Property | Typical Value |
| Density | 2.80 – 2.85 g/cm³ |
| Elastic Modulus | 71 – 72 GPa |
| Thermal Conductivity | 120 – 150 W/m·K |
| Hardness | 140 – 190 HB |
| Tensile Strength | 500 – 710 MPa |
| Yield Strength | 430 – 650 MPa |
| Corrosion Resistance | Moderate |
| Heat Treatment | Heat Treatable |
Manufacturing Considerations
| Manufacturing Process | Performance |
| CNC Milling | Excellent |
| CNC Turning | Excellent |
| Drilling | Excellent |
| Heat Treatment | Excellent |
| Welding | Poor |
| Anodizing | Good |
Selecting the Right 7000 Series Alloy
7075 remains the most widely used grade for high-strength machined components. 7050 and 7150 are widely specified for aerospace structures because they maintain good strength in thicker sections. 7068 provides one of the highest strength levels available among commercial aluminum alloys, making it suitable for specialized engineering components. 7085 supports large structural forgings, while 7049 performs well in aircraft fittings and hydraulic systems.
Considerations for Choosing a Suitable Aluminum Partner
Material selection is only one part of a successful project. Manufacturing capability, quality control, and technical support also affect the finished component. Reviewing a supplier before production helps reduce delays, dimensional issues, and unnecessary manufacturing costs.
Consider the following factors during supplier evaluation:
- Material availability: Confirm the supplier stocks the required alloy, temper, and product form, including plate, sheet, bar, tube, and extrusion.
- Manufacturing capabilities: Check whether the supplier supports the required processes, such as CNC machining, sheet metal fabrication, welding, extrusion, anodizing, and surface finishing.
- Tolerance capability: Review the dimensional tolerances the supplier can consistently achieve, especially for precision-machined features and critical assemblies.
- Quality certifications: Look for recognized certifications such as ISO 9001 and request inspection reports, material certificates, or first article inspection documentation if required.
- Engineering support: Suppliers that provide DFM feedback, material recommendations, and manufacturing reviews can identify production risks before machining begins.
- Production capacity: Verify that the supplier can support prototype quantities, low-volume production, and larger manufacturing orders without affecting lead times.
- Inspection equipment: Ask about available inspection resources, including CMMs, optical measurement systems, surface roughness testers, and hardness testing equipment.
- Surface finishing options: If the project requires anodizing, powder coating, bead blasting, polishing, or plating, confirm that these services are available through the same supplier.
- Industry experience: Experience with aerospace, automotive, electronics, medical devices, marine equipment, or industrial machinery often indicates familiarity with industry-specific quality requirements.
Get Premium CNC Aluminum Machining Parts From Us
Choosing the right aluminum alloy is only the first step. Producing accurate parts also depends on machining experience, process control, inspection, and material quality. Premium Parts delivers precision CNC aluminum machining for prototypes, custom components, and production orders across a wide range of aluminum grades.
Our team supports CNC milling, CNC turning, surface finishing, and engineering review to help you select suitable materials for your application. Every project is manufactured according to your drawings, dimensional requirements, and quality specifications.
Upload your CAD files today to receive a fast quotation and engineering feedback for your custom aluminum parts.
FAQs
Which aluminum alloy is best for CNC machining?
6061 aluminum remains one of the most common choices for CNC machining because it combines good machinability, corrosion resistance, weldability, and mechanical strength. For higher-strength components, 7075 aluminum is frequently selected, while 2011 and 6262 are suitable for high-speed machining due to their excellent chip formation.
Which aluminum alloy offers the highest corrosion resistance?
The 1000, 3000, and 5000 series provide excellent corrosion resistance. Among them, 5052 and 5083 are widely specified for marine equipment, chemical processing systems, and outdoor structures exposed to moisture and saltwater.
What is the difference between the 6061 and 7075 aluminum alloys?
6061 provides a balanced combination of strength, weldability, corrosion resistance, and machining performance, making it suitable for general engineering applications. 7075 delivers much higher mechanical strength and hardness but offers lower weldability and typically requires additional corrosion protection in demanding environments.
Which aluminum alloy series can be heat-treated?
The 2000, 6000, and 7000 series are heat-treatable aluminum alloys. Heat treatment increases their mechanical strength for structural and high-performance applications. In contrast, the 1000, 3000, 4000 (most filler alloys), and 5000 series mainly gain strength through cold working rather than heat treatment.