CNC Machining Materials: Types, Metals, Plastics and Choice

CNC machining is compatible with a wide range of materials, from metals to nonmetals, making it valuable across many industries. 

CNC machining versatility, including non-traditional processes like water jet cutting allows manufacturers to handle diverse material requirements with precision

However, not all materials are suitable for CNC machining, and selecting the right one is essential for the success of your project. 

In this article, we’ll discuss the materials that are compatible with CNC machining and provide insights into the key factors to consider when choosing the best material for your specific machining needs.

What Is CNC Machining?

CNC (Computer Numerical Control) machining is an automated manufacturing process where pre-programmed software dictates the movement of machinery and tools. 

This technology allows for the precise control of complex machinery like lathes, mills, routers, grinders, and novel technologies like water jet cutters, making it possible to create detailed parts with minimal human intervention. 

CNC machining is critical in various industries, including aerospace, automotive, medical, and consumer electronics, where precision and repeatability are essential. 

Its ability to work with a wide range of materials enhances its importance in modern manufacturing processes.

How to Select the Right Material for CNC Machining Projects?

Selecting the right material for CNC machining projects involves considering different essential factors. 

These elements ensure that the material will meet the functional requirements, endure specific environmental stressors, and remain within budget. 

Below, we’ll outline the process and considerations necessary for choosing materials for CNC machining projects.

General Material Selection Process

When selecting materials for CNC machining, the first step is to define the material’s requirements based on its intended application. You need to assess factors such as mechanical properties (e.g., tensile strength, wear resistance), thermal and electrical conductivity, and environmental durability. 

For example, a project that requires corrosion resistance or strength at high temperatures may need stainless steel or other materials with specific properties like abrasion and wear resistance.

Once the material requirements are clear, create a shortlist of materials. This involves narrowing down the options by considering factors like environmental conditions, load-bearing requirements, and machinability. 

The final choice should balance performance with cost, taking into account factors like lead time and material availability.

Lastly, make trade-offs between material properties. For example, materials with a high strength-to-weight ratio, such as certain aluminum alloys, may cost more but could be critical for applications where weight is a concern. In contrast, a project focused on cost-efficiency might prioritize easy-to-machine materials like polypropylene (PP) or carbon steel.

Environmental Factors

Environmental considerations play a significant role in material selection for CNC machining. Different environments can drastically affect material performance, particularly in terms of resistance to heat, corrosion, and other external stressors.

1. Heat Resistance: Certain applications expose materials to high temperatures during both the machining process and the product’s operational life. Materials like aluminum alloys and stainless steel are excellent choices due to their high heat resistance. This ensures the material retains its mechanical properties even when subjected to elevated temperatures.
2. Corrosion Resistance: Materials must also withstand environmental elements such as moisture, chemicals, and UV radiation, especially in outdoor or industrial applications. Stainless steel and ultra-high molecular weight polyethylene (UHMWPE) are commonly used for their corrosion-resistant properties, making them ideal for parts exposed to harsh environments.
3. Flame Retardance: In certain industries, such as aerospace or medical, materials may need to meet specific flame-retardant standards. For such applications, plastics like polyvinyl chloride (PVC) or specific flame-retardant metals may be necessary to ensure safety and compliance with regulatory standards.
4. Food and Medical Grade: For applications in the medical and food industries, material selection must prioritize hygiene and safety. Materials like 316 stainless steel, known for its corrosion resistance and ease of sterilization, are commonly used in these sectors. Additionally, plastics like polypropylene (PP) offer chemical resistance and can be used safely in food-grade or medical equipment.

Mechanical Properties

Mechanical properties play a vital role in determining the suitability of materials for CNC machining. The key considerations include strength, elasticity, toughness, wear resistance, and hardness.

• Strength: Different types of strength—tensile, compressive, and impact—determine how a material reacts to various stresses. For lightweight yet strong components, materials with a high strength-to-weight ratio, such as aluminum alloys, are ideal. Tensile strength, in particular, helps in applications requiring materials that can resist being stretched or pulled apart, making stainless steel and carbon steel excellent choices for high-stress environments.
• Elasticity and Toughness: Elasticity refers to the material’s ability to return to its original shape after deformation, while toughness determines how well a material can resist tearing or cracking. For CNC machined parts that experience bending or constant pressure, materials like ultra-high molecular weight polyethylene (UHMWPE) are often chosen due to their excellent toughness and durability.
• Wear Resistance: For components under constant friction, such as gears or sliding parts, wear-resistant materials are essential. While highly wear-resistant materials offer durability, they can be harder to machine, increasing production complexity. However, the trade-off is often justified for long-term reliability, especially in parts used in demanding environments.
• Hardness vs. Machinability: Harder materials, such as certain alloy steels, provide greater durability but may be more challenging and expensive to machine. On the other hand, softer materials like polypropylene (PP) are easier to machine but may lack the toughness needed for more strenuous applications. Balancing hardness and machinability ensures optimal performance without excessive production costs.

Thermal and Electrical Properties

Thermal and electrical properties are critical when the part will be exposed to heat, electricity, or magnetic fields. Materials should be chosen based on their ability to either conduct or insulate thermal and electrical energy.

• Thermal Conductivity: For parts that need to conduct heat, such as heat sinks or components in high-temperature environments, materials like aluminum are ideal due to their excellent thermal conductivity. Conversely, in applications where heat insulation is necessary, materials with low thermal conductivity, like plastics, may be a better fit.
• Electrical Conductivity and Magnetism: Electrical conductivity is crucial for parts that interact with electrical currents. Copper alloys, for example, are frequently used in electrical applications due to their high conductivity. In cases where electrical insulation is needed, non-conductive materials such as polyvinyl chloride (PVC) are preferable. Additionally, non-magnetic materials, such as certain stainless steel grades, are often easier to machine and ensure better performance in environments sensitive to magnetic interference.

Surface Finish and Aesthetics

The surface finish and aesthetic quality of CNC machined parts are vital for both functional and cosmetic reasons. Different materials offer varying levels of finish and customization options.

• Machined Finish: Some materials are better suited to achieve smooth or polished finishes, making them ideal for applications where appearance is important. Aluminum and stainless steel, for instance, can be easily polished to create a sleek, professional look. These materials are frequently used for high-visibility parts in consumer products or medical devices that require a clean, smooth surface.
• Paintability: Certain materials, like plastic (e.g., polycarbonate) or metals (e.g., carbon steel), are easy to paint, coat, or otherwise treat to enhance their appearance. Paintability allows for customization, whether for color, texture, or added surface protection, which is often important in industries such as consumer electronics or automotive parts.
• Cosmetic Importance: For products where aesthetics are paramount, choosing materials that can be colored or textured is key. Plastics like polypropylene (PP) and materials used in CNC machining, such as brass and copper, offer unique cosmetic options. This flexibility makes them popular in applications where visual appeal is a critical factor, like in interior design components or consumer goods.

Manufacturing Considerations

Beyond aesthetics, manufacturing considerations such as machinability, dimensional tolerance, and lead time are equally important in material selection for CNC machining.

• Dimensional Tolerance: Dimensional tolerance refers to how closely a material can be machined to its specified dimensions. For high-precision applications like medical devices or aerospace components, maintaining tight tolerances is crucial. Materials such as stainless steel and aluminum are known for their ability to maintain high accuracy, which is vital in industries requiring extreme precision.
• Machinability: The ease with which a material can be machined directly affects the production cost and time. Softer materials, such as plastics like ABS and polyvinyl chloride (PVC), are easier to machine, reducing tool wear and machining time. However, these materials may not be suitable for high-stress applications where strength and durability are critical. Harder materials, such as alloy steels, offer better strength but are more expensive to machine due to increased tool wear.
• Lead Time: Material availability can affect production timelines, especially when tight deadlines are involved. For projects with short lead times, materials that are readily available, such as aluminum or polypropylene, may be preferable. This ensures that production moves forward without delays due to sourcing challenges.
• Fastening Compatibility: Certain materials are better suited for fastening and assembly processes. Metals like carbon steel and stainless steel are commonly used in parts that require bolting or welding due to their strength and corrosion resistance. However, in some cases, galvanic corrosion may be a concern when dissimilar metals are used together, so material compatibility is a critical consideration during the selection process.

Specific Environmental Needs

When selecting materials for CNC machining, it’s essential to consider the environment in which the final product will operate.

• Indoors vs. Outdoors: Materials intended for outdoor use must be able to withstand harsh conditions, including UV rays, rain, and corrosion. Corrosion-resistant materials like stainless steel (especially 316 SS) and certain plastics such as polyvinyl chloride (PVC) are ideal for outdoor components. For indoor applications, the material requirements are typically less demanding. For example, plastics like polypropylene (PP) and nylon can be used in indoor applications where exposure to environmental factors like moisture or sunlight is minimal.
• Moisture Resistance: In environments where moisture is a concern, choosing the right corrosion-resistant or moisture-resistant materials is critical. Stainless steel and ultra-high molecular weight polyethylene (UHMW PE) are excellent options for applications exposed to moisture or saltwater. These materials resist moisture absorption, reducing the risk of material degradation over time. For marine or humid environments, ensuring materials have high corrosion resistance is essential to prolong the lifespan of machined parts.

Material Properties to Assess

Several material properties directly influence the performance of CNC machined components, especially under challenging environmental or operational conditions.

• Temperature Resistance: Some CNC machining materials must endure extreme or fluctuating temperatures without warping, melting, or breaking down. Metals like stainless steel and alloys such as aluminum and carbon steel have high temperature resistance, making them ideal for parts in high-heat environments like engine parts or aerospace frames. On the other hand, plastic materials, such as polycarbonate (PC), are selected for their ability to perform in moderate temperature ranges while offering heat conductivity when necessary.
• Strength to Weight Ratio: Balancing strength and weight is crucial for modern applications, particularly in the aerospace and automotive industries. Materials with a high strength-to-weight ratio, such as aluminum alloys and carbon fiber composites, offer durability while minimizing the overall weight of machined parts. This is especially beneficial in applications where reducing weight without sacrificing strength is key to efficiency, such as in aerospace frames or engine components.
• Elongation and Elasticity: For applications where components need to stretch or return to their original shape after deformation, materials with good elasticity are important. Plastics like nylon and metals like brass are suitable for applications where elasticity and elongation under stress are essential. These materials can endure repeated stress without fracturing, making them ideal for CNC machined components in dynamic or load-bearing applications.

Cost Factors

When deciding on materials, it’s essential to find a balance between the material cost and its required functionality.

• Material Costs: Material costs directly impact the overall expense of your CNC machining project. Plastics like polypropylene (PP) or polyvinyl chloride (PVC) are generally less expensive and ideal for applications where high strength isn’t required, making them a good option for simple parts. On the other hand, high-grade metals like stainless steel or aluminum alloys, commonly used in CNC machining, are more expensive but necessary for parts requiring durability, heat resistance, or corrosion resistance. Your material choice will largely depend on whether cost efficiency or material properties are the priority.
• Production Costs: The machinability of a material also affects production costs. Softer materials like certain plastics or aluminum are easier to machine, reducing tool wear and machining time, which lowers production costs. However, harder materials like alloy steels and carbon steel, while offering higher tensile strength and wear resistance, may increase production time and cause more tool wear, driving up costs. Evaluating the balance between material toughness and ease of machining will help you manage both material and production expenses.

Material-Specific Applications

The material you select must match the part’s purpose. Each material offers different mechanical properties, making the selection process essential for achieving the desired outcome in your machining project.

• Purpose and Application: The material you select should be aligned with the specific function of the part. For instance, if the component requires electrical insulation, plastics like acetal or nylon are appropriate. For load-bearing applications, materials with high mechanical properties, like stainless steel or carbon steel, are often required to withstand stress and provide dimensional stability. CNC machined parts used in the aerospace industry may require lightweight but strong materials, such as aluminum alloys or carbon fiber.
• Load Requirements and Operating Temperature: Parts exposed to high-stress loads or frequent impact need materials with excellent tensile strength, such as alloy steel or titanium. These materials are often used in engine parts, medical devices, or structural components. Additionally, if the part will be used in high-temperature environments, such as in manufacturing equipment or aerospace frames, it’s crucial to select materials that can maintain structural integrity under heat, like stainless steel or polycarbonate. Evaluating the strength-to-weight ratio and thermal conductivity of your materials will ensure the part performs reliably in its intended environment.

Significance of CNC Machining Process Type

It’s essential to consider the specific process being used—ranging from well-known methods like milling and turning to non-traditional techniques such as waterjet cutting. 

Each process imposes unique mechanical, thermal, and operational demands on the material, and aligning your material choice with the chosen machining method will help optimize cost, efficiency, and final part quality.

Traditional Machining Example: Milling and Turning

Milling involves cutting away material with rotating tools to shape parts with complex surfaces or features. Materials that withstand consistent tool contact and heat generation, such as aluminum or carbon steel, are often preferred due to their balance of machinability and durability. Turning, on the other hand, shapes a rotating workpiece with a stationary cutting tool and is commonly used for producing cylindrical or conical parts. Metals like stainless steel and certain plastics (e.g., acetal) offer excellent machinability and can achieve tight tolerances in turning operations. In both milling and turning, harder materials may require more robust tooling and extended machining times, increasing production costs. Softer materials reduce tool wear but can compromise strength, making it crucial to assess the application’s load requirements.

Material Choice for Non-Traditional Processes: Waterjet Cutting

Unlike milling or turning, the waterjet cutting process does not involve mechanical contact or heat-affected zones. Instead, a high-pressure stream of water—often mixed with abrasives—erodes the material. This makes waterjet cutting suitable for materials that might warp or degrade under high temperatures, such as certain plastics, composites, or heat-sensitive metals. 

Thicker or extremely hard materials may require higher pressures and longer cutting times, influencing both cost and lead time. 

Ensuring the chosen material can be efficiently cut at the desired thickness without delamination (in the case of composites) or surface damage (for metals) is a key consideration for waterjet-based projects.

Ultimately, understanding the nuances of each CNC process—its thermal load, tooling requirements, and impact on material properties—will guide you toward an optimal material choice. By matching the material’s characteristics to the demands of milling, turning, waterjet, or other CNC processes, you’ll ensure both cost-effectiveness and reliable performance for your final product.

 

What Materials Can Be CNC Machined?

CNC machining can handle a wide range of materials, each offering unique properties such as strength to weight ratio, corrosion resistance, and mechanical properties. 

Whether you’re working with metals or plastics, the material you choose will affect both the machining process and the final product’s performance.

Metals

Metals are commonly used in CNC machining due to their durability, tensile strength, and ability to withstand various environmental conditions. Below is a list of metals typically used in CNC machining:

1. Stainless Steel (316 SS): Stainless steel is a popular choice for CNC machining projects that require corrosion resistance and mechanical strength. It is often used in medical devices and aerospace applications due to its ability to handle high stress and wear resistance. 316 SS provides excellent resistance to moisture and chemicals, making it suitable for both indoor and outdoor uses.
2. Aluminum Alloys: Aluminum is favored for its high strength to weight ratio, making it ideal for components in industries like automotive and aerospace. Aluminum is also easy to machine, reducing production costs, and can be anodized for a smooth surface finish. It is frequently used in machined parts that need to maintain dimensional stability under stress.
3. Carbon Steel: Known for its durability and hardness, carbon steel is widely used for heavy-duty applications such as machinery and construction components. It offers excellent abrasion and wear resistance, making it suitable for parts that undergo constant use.
4. Brass: Brass provides excellent machinability and is often used in electrical components due to its electrical conductivity. It is also resistant to corrosion, making it useful for parts exposed to moisture, such as fittings and valves.
5. Titanium: Titanium is another material known for its strength to weight ratio and corrosion resistance. It is commonly used in aerospace frames and medical implants where strength and low weight are critical factors. Titanium’s high heat resistance also makes it suitable for parts exposed to extreme temperatures.
6. Copper: Copper is used for its superior thermal conductivity and electrical properties. It is often found in heat sinks and other components that require efficient heat dissipation.

Aluminium

Aluminum is widely used in CNC machining due to its excellent strength-to-weight ratio and corrosion resistance. It is lightweight, easy to machine, and provides a smooth surface finish. Aluminum alloys also exhibit good electrical conductivity and thermal properties, making them suitable for a wide range of industries, including aerospace, automotive, and electronics.

Grades and Applications:

• 6061: Known for its versatility, 6061 is used in aerospace frames, automotive components, and consumer electronics. It offers good mechanical properties and is resistant to corrosion.
• 7075: This high-strength alloy is often used in aerospace and military applications where strength is critical.
• 2024: Widely used in aerospace, this alloy has high strength and fatigue resistance but is less corrosion resistant than 6061.
• 5052: Known for its excellent corrosion resistance, 5052 is often used in marine and aerospace industries.
• 3003: This is a softer, more malleable aluminum, commonly used for forming and spinning processes, especially in consumer products like cooking utensils.

Characteristics Table

Property	6061	7075	2024	5052	3003
Temperature Resistance	Medium	High	High	Medium	Low
Tensile Strength (MPa)	310	572	470	215	130
Yield Strength (MPa)	276	503	324	193	95
Elongation at Break (%)	12	11	19	12	9
Hardness (Brinell)	95	150	120	60	35
Corrosion Resistance	High	Medium	Low	Very High	High
Density (g/cm³)	2.70	2.81	2.78	2.68	2.73
Magnetic Properties	Non-magnetic	Non-magnetic	Non-magnetic	Non-magnetic	Non-magnetic
Machinability	Excellent	Good	Fair	Good	Excellent
Module of Elasticity (GPa)	69	71	73	70	69
Electrical Conductivity	Good	Fair	Fair	Good	Good
Coefficient of Thermal Expansion (µm/m°C)	23.6	23.5	23.2	23.8	24.0
Thermal Conductivity (W/mK)	167	130	121	138	160

 

Carbon Steel (e.g., 1018, 1045)

Carbon steel is suitable for CNC machining due to its strength, hardness, and cost-effectiveness. The material is easy to machine, making it a preferred choice for parts that require durability without excessive cost. Its mechanical properties, such as tensile strength and wear resistance, make it ideal for a wide range of applications in the automotive, construction, and machinery sectors.

Grades and Applications:

• 1018: Known for its excellent machinability and uniformity, 1018 is commonly used in shafts, gears, and other mechanical components that do not require high strength.
• 1045: This medium carbon steel is stronger than 1018 and is used for parts like axles, bolts, and couplings, where strength and toughness are essential.

Characteristics Table

Property	1018	1045
Temperature Resistance	Medium	Medium
Tensile Strength (MPa)	440	570
Yield Strength (MPa)	370	450
Elongation at Break (%)	15	12
Hardness (Brinell)	126	197
Corrosion Resistance	Low	Low
Density (g/cm³)	7.87	7.87
Magnetic Properties	Magnetic	Magnetic
Machinability	Excellent	Good
Module of Elasticity (GPa)	205	210
Electrical Conductivity	Fair	Fair
Coefficient of Thermal Expansion (µm/m°C)	12.1	11.8
Thermal Conductivity (W/mK)	51.9	46.6

Alloy Steel (e.g., 4140, 4340)

Alloy steel is particularly suitable for CNC machining because of its enhanced mechanical properties compared to carbon steel. By adding elements such as chromium, molybdenum, and nickel, alloy steels achieve better strength, hardness, and corrosion resistance. This makes them ideal for parts that require high performance under stress, including shafts, gears, and high-load components in industries such as aerospace and automotive.

Grades and Applications:

• 4140: Known for its excellent toughness and fatigue resistance, 4140 is commonly used in crankshafts, heavy-duty gears, and structural tubing.
• 4340: This grade offers higher strength and toughness than 4140, making it suitable for aircraft landing gear, axles, and connecting rods.

Characteristics Table

Property	4140	4340
Temperature Resistance	High	High
Tensile Strength (MPa)	655	745
Yield Strength (MPa)	415	470
Elongation at Break (%)	20	18
Hardness (Brinell)	197	217
Corrosion Resistance	Moderate	Moderate
Density (g/cm³)	7.85	7.85
Magnetic Properties	Magnetic	Magnetic
Machinability	Good	Fair
Module of Elasticity (GPa)	210	210
Electrical Conductivity	Low	Low
Coefficient of Thermal Expansion (µm/m°C)	12.3	12.4
Thermal Conductivity (W/mK)	42.7	44.5

Tool Steel (e.g., D2, A2)

Tool steel is highly suited for CNC machining because of its hardness, durability, and ability to maintain its form under stress. Tool steels are often used for cutting, pressing, and mold-making tools due to their wear resistance. With added alloying elements such as chromium, vanadium, and molybdenum, tool steel grades like D2 and A2 achieve high hardness and excellent edge retention. This makes them ideal for parts that will undergo high-stress machining processes.

Grades and Applications:

• D2 Tool Steel: Known for its hardness and abrasion resistance, D2 is used in cutting tools, punches, and dies. It is an air-hardening steel with excellent edge retention.
• A2 Tool Steel: This air-hardening grade is tough and moderately wear-resistant, making it ideal for punches, forming dies, and shearing blades.

Characteristics Table

Property	D2	A2
Temperature Resistance	High	High
Tensile Strength (MPa)	1900	1600
Yield Strength (MPa)	1600	1450
Elongation at Break (%)	12	14
Hardness (Rockwell C)	58-62	57-62
Corrosion Resistance	Moderate	Low
Density (g/cm³)	7.7	7.85
Magnetic Properties	Magnetic	Magnetic
Machinability	Fair	Good
Module of Elasticity (GPa)	210	210
Electrical Conductivity	Low	Low
Coefficient of Thermal Expansion (µm/m°C)	11.0	11.2
Thermal Conductivity (W/mK)	20	24

Stainless Steel (e.g., 303, 304, 316, 410, 17-4 PH)

Stainless steel is a widely used material for CNC machining due to its excellent resistance to corrosion, high tensile strength, and impressive durability. It is particularly effective for parts that will experience harsh environments or high temperatures. With multiple grades available, stainless steel offers varying levels of mechanical properties, making it suitable for diverse applications such as medical devices, aerospace components, and food processing equipment.

Grades and Applications:

• 303 Stainless Steel: Known for its excellent machinability, this grade is used for high-volume components like fittings and fasteners where corrosion resistance is necessary.
• 304 Stainless Steel: One of the most commonly used grades, 304 is versatile and corrosion-resistant, suitable for kitchen equipment, pipes, and architectural applications.
• 316 Stainless Steel (316 SS): With added molybdenum, 316 SS offers superior corrosion resistance, especially in marine environments. It’s commonly used in chemical processing equipment and marine components.
• 410 Stainless Steel: This martensitic stainless steel is heat treatable and offers good wear resistance. It is frequently used for cutlery, valves, and surgical instruments.
• 17-4 PH Stainless Steel: Precipitation-hardened for excellent strength and corrosion resistance, 17-4 PH is used in aerospace and nuclear industries for parts like turbine blades and aerospace frames.

Characteristics Table

Property	303	304	316 SS	410	17-4 PH
Temperature Resistance (°C)	870	870	800	815	620
Tensile Strength (MPa)	500	505	515	440	1170
Yield Strength (MPa)	190	215	205	275	1035
Elongation at Break (%)	35	40	40	20	10
Hardness (Rockwell B)	85	92	95	88	38-44
Chemical Resistance	Moderate	Good	Excellent	Fair	Good
Corrosion Resistance	Good	Good	Excellent	Moderate	Excellent
Density (g/cm³)	7.8	7.9	8.0	7.7	7.8
Magnetic Properties	Non-magnetic	Non-magnetic	Non-magnetic	Magnetic	Magnetic
Machinability	Excellent	Fair	Fair	Good	Moderate
Module of Elasticity (GPa)	193	193	193	200	190
Electrical Conductivity (MS/m)	Low	Low	Low	Low	Low
Coefficient of Thermal Expansion (µm/m°C)	16.5	16.0	15.9	9.9	10.8
Thermal Conductivity (W/mK)	16.3	16.2	16.2	24.9	15.3

Brass

Brass is an alloy of copper and zinc, known for its excellent corrosion resistance, machinability, and electrical conductivity. Due to its versatility and ease of machining, brass is widely used in CNC projects. It is commonly found in applications such as fittings, gears, valves, and decorative items. Brass is also valued for its smooth surface finish after machining, which reduces the need for extensive post-processing.

Grades and Applications:

• C360 Brass: Known as free-cutting brass, C360 is highly machinable and is commonly used in applications where a smooth finish and precision are necessary. It’s widely used for fasteners, gears, and fittings.
• C932 Brass (also known as Bearing Bronze): This alloy offers good strength and wear resistance, making it ideal for bearing and bushing applications. It is frequently used in pumps, valves, and hydraulic equipment.

Characteristics Table

Property	C360	C932
Temperature Resistance (°C)	200	315
Tensile Strength (MPa)	345	310
Yield Strength (MPa)	275	200
Elongation at Break (%)	50	10
Hardness (Rockwell B)	60	75
Chemical Resistance	Moderate	Moderate
Corrosion Resistance	Excellent	Good
Density (g/cm³)	8.4	8.7
Magnetic Properties	Non-magnetic	Non-magnetic
Machinability	Excellent	Good
Module of Elasticity (GPa)	110	110
Electrical Conductivity (MS/m)	26	15
Coefficient of Thermal Expansion (µm/m°C)	20	18
Thermal Conductivity (W/mK)	120	54

Copper

Copper is one of the most widely used metals in CNC machining due to its excellent electrical conductivity, thermal conductivity, and resistance to corrosion. It is commonly selected for applications in electronics, automotive components, and plumbing due to its durability and machinability. The high machinability of copper ensures a smooth surface finish, reducing the need for extensive post-processing. Copper alloys, such as C110, are frequently used in CNC machining projects.

Grades and Applications:

• C110 Copper (Electrolytic Tough Pitch Copper): Known for its high purity and excellent electrical conductivity, C110 is used in electrical wiring, transformers, and other components where conductivity is essential.

Characteristics Table

Property	C110 (Copper)
Temperature Resistance (°C)	260
Tensile Strength (MPa)	210
Yield Strength (MPa)	33
Elongation at Break (%)	45
Hardness (Rockwell B)	40
Chemical Resistance	Excellent
Corrosion Resistance	Excellent
Density (g/cm³)	8.9
Magnetic Properties	Non-magnetic
Machinability	Fair
Module of Elasticity (GPa)	110
Electrical Conductivity (MS/m)	58
Coefficient of Thermal Expansion (µm/m°C)	17
Thermal Conductivity (W/mK)	385

Bronze Alloys

Bronze alloys, a combination of copper and tin, are highly valued in CNC machining due to their strength, wear resistance, and ability to withstand harsh environmental conditions. These alloys are widely used in industries such as marine, aerospace, and manufacturing, where high-performance materials are needed. Bronze alloys are easy to machine, making them ideal for creating precision parts with complex geometries.

Grades and Applications:

• C932 Bronze (Bearing Bronze): This alloy is highly used for bearings, bushings, and heavy-duty mechanical components. Its excellent wear resistance and corrosion resistance make it a top choice for applications requiring durability.
• C954 Aluminum Bronze: This grade is commonly used for aerospace components, heavy-duty equipment, and pump parts due to its strength and resistance to seawater corrosion.

Characteristics Table

Property	C932 Bronze	C954 Aluminum Bronze
Temperature Resistance (°C)	250	315
Tensile Strength (MPa)	220	690
Yield Strength (MPa)	145	410
Elongation at Break (%)	15	12
Hardness (Brinell)	65-85	170-190
Chemical Resistance	Good	Excellent
Corrosion Resistance	Excellent	Excellent
Density (g/cm³)	8.9	7.5
Magnetic Properties	Non-magnetic	Non-magnetic
Machinability	Good	Fair
Module of Elasticity (GPa)	110	120
Electrical Conductivity (MS/m)	7.9	5.4
Coefficient of Thermal Expansion (µm/m°C)	18	17.5
Thermal Conductivity (W/mK)	60	42

Titanium

Titanium is an ideal material for CNC machining because of its high strength-to-weight ratio, excellent corrosion resistance, and ability to withstand extreme temperatures. Titanium is used in applications where weight reduction without compromising strength is essential, such as aerospace components and medical implants. Due to its toughness, titanium can be more challenging to machine than softer metals, but CNC machining allows for precise shaping of titanium parts.

Titanium comes in several grades, each offering distinct properties that make it suitable for specific applications.

Grades and Applications:

• Grade 2: Known as commercially pure titanium, Grade 2 is highly corrosion resistant and has moderate strength. It is commonly used in chemical processing equipment, marine components, and medical implants due to its biocompatibility.
• Grade 5 (Ti 6Al-4V): This is the most commonly used titanium alloy, offering excellent strength and heat resistance. Grade 5 titanium is used extensively in aerospace, automotive, and medical industries for parts that require high strength and durability, such as engine components, airframes, and orthopedic implants.

Characteristics Table for Titanium Grades

Property	Grade 2 Titanium	Grade 5 Titanium (Ti 6Al-4V)
Temperature Resistance (°C)	300	400
Tensile Strength (MPa)	344	895
Yield Strength (MPa)	275	828
Elongation at Break (%)	20	10
Hardness (Rockwell C)	20-30	36-38
Chemical Resistance	Excellent	Good
Corrosion Resistance	Excellent	Excellent
Density (g/cm³)	4.51	4.43
Magnetic Properties	Non-magnetic	Non-magnetic
Machinability	Fair	Poor
Module of Elasticity (GPa)	105	114
Electrical Conductivity (MS/m)	0.58	0.56
Coefficient of Thermal Expansion (µm/m°C)	8.6	8.6
Thermal Conductivity (W/mK)	22	6.7

Magnesium (AZ31B)

Magnesium alloys like AZ31B are ideal for CNC machining because they offer a high strength-to-weight ratio, excellent machinability, and good corrosion resistance. AZ31B is a wrought magnesium alloy, meaning it is worked into its final form through processes like rolling or extrusion, and is known for its ease of machining. It’s commonly used in aerospace, automotive, and electronics industries due to its lightweight properties and decent mechanical strength. In CNC machining, magnesium can be precision-machined into components like engine blocks, structural parts, and aerospace frames.

Grades and Applications:

• AZ31B: This is the most widely used magnesium alloy. It provides an excellent balance between strength, weight, and machinability. Its applications include parts in the aerospace and automotive industries, as well as electronics housings where lightweight materials are a priority.

Characteristics Table for Magnesium AZ31B

Property	AZ31B Magnesium
Temperature Resistance (°C)	150
Tensile Strength (MPa)	275
Yield Strength (MPa)	200
Elongation at Break (%)	12
Hardness (Brinell)	60
Chemical Resistance	Good
Corrosion Resistance	Good
Density (g/cm³)	1.78
Magnetic Properties	Non-magnetic
Machinability	Excellent
Module of Elasticity (GPa)	45
Electrical Conductivity (MS/m)	6.8
Coefficient of Thermal Expansion (µm/m°C)	26
Thermal Conductivity (W/mK)	96

Nickel Alloys (Inconel 625, Inconel 718)

Nickel alloys, especially Inconel grades, are known for their exceptional strength, heat resistance, and corrosion resistance. These properties make them ideal materials for CNC machining, particularly in projects where high-performance and durability are essential. Inconel 625 and Inconel 718 are two common grades used in a variety of industries.

Grades and Applications

• Inconel 625: Is a nickel-chromium alloy known for its excellent fatigue and oxidation resistance. It is often used in chemical processing, nuclear power plants, and marine applications due to its corrosion-resistant properties. It can withstand extreme temperatures and maintain its mechanical properties in harsh conditions.
• Inconel 718: Is another nickel-chromium alloy, but it includes significant amounts of niobium, which enhances its strength and resistance to high temperatures. This alloy is widely used in the aerospace industry for jet engine components, gas turbines, and rocket motors, where extreme heat and mechanical stress are common.

Characteristics Table for Inconel 625 and Inconel 718

Property	Inconel 625	Inconel 718
Temperature Resistance (°C)	Up to 982	Up to 700
Tensile Strength (MPa)	827	1035
Yield Strength (MPa)	414	720
Elongation at Break (%)	30	19
Hardness (Rockwell C)	30	38
Chemical Resistance	Excellent	Excellent
Corrosion Resistance	High	High
Density (g/cm³)	8.44	8.19
Magnetic Properties	Non-magnetic	Non-magnetic
Machinability	Moderate	Moderate
Module of Elasticity (GPa)	207	211
Electrical Conductivity (MS/m)	Low	Low
Coefficient of Thermal Expansion (µm/m°C)	13.3	13.0
Thermal Conductivity (W/mK)	9.8	11.4

Zinc Alloys

Zinc alloys are highly suited for CNC machining due to their excellent machinability, durability, and corrosion resistance. Zinc’s relatively low melting point, coupled with its good strength and ease of casting, makes it an attractive material for precision machining projects. Zinc alloys are often used in the production of high-precision components, where dimensional stability and wear resistance are essential. Additionally, zinc can be easily recycled, further reducing manufacturing costs and environmental impact.

Zinc alloys, such as Zamak and ZA series, are often chosen for parts like automotive components, electrical hardware, and consumer goods, where corrosion resistance and strength are critical. These alloys also offer high strength-to-weight ratios, making them an ideal choice in industries where both weight and durability are concerns.

Characteristics Table for Zinc Alloys

Property	Zinc Alloy (e.g., Zamak 3)
Temperature Resistance (°C)	Up to 380
Tensile Strength (MPa)	280
Yield Strength (MPa)	221
Elongation at Break (%)	10
Hardness (Brinell)	82
Chemical Resistance	Moderate
Corrosion Resistance	High
Density (g/cm³)	6.6
Magnetic Properties	Non-magnetic
Machinability	Excellent
Module of Elasticity (GPa)	83
Electrical Conductivity (MS/m)	17
Coefficient of Thermal Expansion (µm/m°C)	27.0
Thermal Conductivity (W/mK)	113

Plastics 

A variety of plastic materials are commonly used in CNC machining projects. Each offers unique characteristics that make them suitable for specific applications, providing solutions where metals may not be ideal. Below is a detailed look at one of the commonly used plastics in CNC machining.

ABS (Acrylonitrile Butadiene Styrene)

ABS is a widely used plastic in CNC machining due to its combination of strength, toughness, and easy machinability. It has excellent impact resistance, which makes it suitable for products that undergo constant wear and stress. Its low cost and flexibility also make it a go-to material for prototyping and production in industries such as automotive, consumer electronics, and medical devices.

ABS is valued for its ease of processing. It can be machined into complex shapes with a smooth surface finish, making it ideal for producing CNC machined parts that require both aesthetic appeal and functionality. Additionally, ABS’s ability to withstand temperature fluctuations without significant deformation ensures consistent performance in various conditions.

Common Grades of ABS:

• General Purpose ABS: Suitable for a variety of applications, including enclosures, consumer products, and everyday items.
• High-Impact ABS: Used in industries where high mechanical stress is involved, such as automotive parts, housings, and protective gear.
• Flame-Retardant ABS: Ideal for electrical components that need fire resistance and safety assurance.

Common Applications:

• Automotive dashboards, interior trim, and protective housings
• Consumer electronics enclosures
• Prototyping parts
• Medical device components
• Toys and everyday products

Characteristics Table for ABS:

Property	Value
Temperature Resistance (°C)	-20 to 80
Tensile Strength (MPa)	40-60
Yield Strength (MPa)	38-43
Elongation at Break (%)	10-30
Hardness (Rockwell)	R110
Chemical Resistance	Moderate
Corrosion Resistance	High
Density (g/cm³)	1.04
Magnetic Properties	Non-magnetic
Machinability	Excellent
Modulus of Elasticity (GPa)	2.0-2.5
Electrical Conductivity (S/m)	Insulator
Coefficient of Thermal Expansion (µm/m°C)	73
Thermal Conductivity (W/mK)	0.17

Polycarbonate (PC)

Polycarbonate (PC) is a thermoplastic polymer known for its toughness, optical clarity, and ability to withstand high impacts. It is an ideal material for CNC machining because it combines strength and flexibility, which is why it’s frequently used in applications where durability and precision are critical. PC has a relatively high resistance to heat and UV light, making it suitable for both indoor and outdoor applications.

Due to its transparency and toughness, PC is often used for safety equipment, optical lenses, and electronics enclosures. It also exhibits good dimensional stability, meaning it maintains its shape and size even after extensive machining processes.

Common Grades of Polycarbonate (PC):

• General-Purpose Polycarbonate: Used for a variety of applications, including optical lenses, electronics, and automotive parts.

• UV-Stabilized Polycarbonate: Suitable for outdoor applications where UV resistance is necessary, such as glazing and light covers.

• Flame-Retardant Polycarbonate: Ideal for electrical components that require safety in high-heat environments.

Common Applications:

• Optical lenses and visors
• Electronics enclosures
• Medical equipment
• Automotive parts
• Protective shields and barriers

Characteristics Table for Polycarbonate (PC):

Property	Value
Temperature Resistance (°C)	-40 to 120
Tensile Strength (MPa)	60-70
Yield Strength (MPa)	65-70
Elongation at Break (%)	100-150
Hardness (Rockwell)	R118
Chemical Resistance	Moderate
Corrosion Resistance	High
Density (g/cm³)	1.20
Magnetic Properties	Non-magnetic
Machinability	Good
Modulus of Elasticity (GPa)	2.3-2.4
Electrical Conductivity (S/m)	Insulator
Coefficient of Thermal Expansion (µm/m°C)	70-80
Thermal Conductivity (W/mK)	0.19

Polypropylene (PP)

Polypropylene (PP) is a thermoplastic polymer known for its excellent chemical resistance, impact resistance, and versatility. It is often chosen for CNC machined parts where durability and flexibility are critical. PP’s low density gives it a favorable strength to weight ratio, making it a lightweight option for many applications. It is also cost-effective and provides a smooth surface finish, which is beneficial for projects requiring dimensional stability and high precision.

Due to its mechanical properties, PP is commonly used in the manufacturing industry for products such as automotive parts, medical devices, and packaging components. Its ability to withstand high temperatures and resist moisture makes it suitable for machining projects that require both corrosion resistance and abrasion and wear resistance.

Common Grades of Polypropylene (PP):

• Homopolymer PP: Used for parts that require high stiffness and strength. Common applications include piping systems, containers, and automotive parts.
• Copolymer PP: More flexible and impact-resistant, ideal for components subjected to high stress, such as medical and automotive products.
• Flame Retardant PP: Used in environments where fire resistance is necessary, such as electrical enclosures and components.

Common Applications of PP:

• Automotive parts (bumpers, dashboards)
• Packaging containers
• Medical devices
• Electrical enclosures
• Pipes and fittings

Characteristics Table for Polypropylene (PP):

Property	Value
Temperature Resistance (°C)	-20 to 100
Tensile Strength (MPa)	30-40
Yield Strength (MPa)	35-40
Elongation at Break (%)	400-800
Hardness (Shore D)	50-65
Chemical Resistance	Excellent
Corrosion Resistance	High
Density (g/cm³)	0.90-0.91
Magnetic Properties	Non-magnetic
Machinability	Easy to machine
Modulus of Elasticity (GPa)	1.5-2.0
Electrical Conductivity (S/m)	Insulator
Coefficient of Thermal Expansion (µm/m°C)	100-150
Thermal Conductivity (W/mK)	0.22

POM (Acetal/Delrin)

POM (Acetal/Delrin) is a highly versatile thermoplastic known for its stiffness, low friction, and dimensional stability. These properties make it one of the most suitable materials for CNC machining. It is commonly used in applications that require precision and mechanical durability. POM’s low coefficient of friction allows for smooth machining and reduced wear during operation, which makes it perfect for moving components or precision gears.

This material is also corrosion-resistant and performs well in both low and high temperatures, offering dimensional stability in a variety of environmental conditions. Its ability to maintain mechanical properties, even in harsh environments, makes POM a reliable choice for machined parts.

Common Grades 

• Acetal Homopolymer (Delrin): Known for higher mechanical strength and rigidity. It is often used in precision parts like gears, bearings, and bushings.
• Acetal Copolymer: Offers better resistance to chemicals and moisture, ideal for use in environments with chemical exposure or higher humidity.
• Enhanced Lubricity Grades: These grades include additives to further reduce friction, which is useful in sliding or bearing applications.

Common Applications 

• Precision gears
• Bearings and bushings
• Electrical insulators
• Automotive components (valves, fuel systems)
• Industrial machinery parts

Characteristics Table for POM (Acetal/Delrin):

Property	Value
Temperature Resistance (°C)	-40 to 120
Tensile Strength (MPa)	60-70
Yield Strength (MPa)	63-70
Elongation at Break (%)	20-40
Hardness (Rockwell M)	85-90
Chemical Resistance	Good
Corrosion Resistance	High
Density (g/cm³)	1.41-1.42
Magnetic Properties	Non-magnetic
Machinability	Excellent
Modulus of Elasticity (GPa)	3.0-3.5
Electrical Conductivity	Insulator
Coefficient of Thermal Expansion (µm/m°C)	110-120
Thermal Conductivity (W/mK)	0.23

PTFE (Teflon)

PTFE, often referred to by its brand name Teflon, is a fluoropolymer known for its outstanding chemical resistance and very low friction, making it a popular choice in CNC machining materials. Its ability to withstand extreme temperatures, both high and low, makes it suitable for various industrial applications. PTFE is an excellent electrical insulator and offers great resistance to weathering, UV exposure, and moisture.

This material is highly inert, meaning it does not react with most chemicals, making it an ideal option for environments that involve corrosive substances. PTFE also has a smooth surface, allowing for machined parts with excellent surface finish and low wear. These properties make Teflon suitable for high-precision components that require durability and reliability over time.

Common Grades of PTFE (Teflon):

• Virgin PTFE: Pure, unfilled PTFE with high chemical resistance and electrical insulating properties. It is commonly used in seals, gaskets, and bearings.
• Glass-Filled PTFE: This grade contains glass fibers for enhanced wear resistance and improved dimensional stability, commonly used in structural applications.
• Carbon-Filled PTFE: Offers improved wear resistance and reduced deformation under load, suitable for parts that require high strength in friction-based applications.
• Bronze-Filled PTFE: Provides better compression strength and wear resistance, making it ideal for bearing and piston applications.

Common Applications of PTFE (Teflon):

• Seals and gaskets
• Electrical insulation components
• Chemical processing equipment
• Valve seats
• Bearings and bushings
• Pump housings

Characteristics Table for PTFE (Teflon):

Property	Value
Temperature Resistance (°C)	-200 to 260
Tensile Strength (MPa)	14-30
Yield Strength (MPa)	16-23
Elongation at Break (%)	150-400
Hardness (Shore D)	50-65
Chemical Resistance	Excellent
Corrosion Resistance	High
Density (g/cm³)	2.1-2.3
Magnetic Properties	Non-magnetic
Machinability	Good
Modulus of Elasticity (GPa)	0.5-0.7
Electrical Conductivity	Insulator
Coefficient of Thermal Expansion (µm/m°C)	100-200
Thermal Conductivity (W/mK)	0.25

Nylon 6 and Nylon 66

Nylon 6 and Nylon 66 are two common grades of nylon used in CNC machining projects. Both offer good mechanical properties, but they differ slightly in terms of heat resistance and toughness. Nylon 6 has better impact resistance and is easier to machine, while Nylon 66 offers higher heat resistance and rigidity, making it more suitable for high-temperature applications.

Common Applications of Nylon 6 and Nylon 66:

• Bushings and bearings
• Gears
• Structural components
• Electrical insulators
• Wear-resistant parts

Characteristics Table for Nylon 6 and Nylon 66:

Property	Nylon 6	Nylon 66
Temperature Resistance (°C)	-40 to 90	-40 to 120
Tensile Strength (MPa)	70-90	75-85
Yield Strength (MPa)	70	82
Elongation at Break (%)	100-150	50-80
Hardness (Shore D)	75	80
Chemical Resistance	Good	Good
Corrosion Resistance	High	High
Density (g/cm³)	1.13-1.15	1.14-1.16
Magnetic Properties	Non-magnetic	Non-magnetic
Machinability	Good	Good
Modulus of Elasticity (GPa)	2.8-3.0	3.2-3.5
Electrical Conductivity	Insulator	Insulator
Coefficient of Thermal Expansion (µm/m°C)	80-120	70-110
Thermal Conductivity (W/mK)	0.25-0.30	0.25-0.30

PEEK (Polyether Ether Ketone)

PEEK is known for its high performance in demanding applications. This material is chosen in industries like aerospace, medical devices, and automotive due to its ability to maintain its properties under extreme conditions. PEEK can withstand high temperatures and offers excellent chemical resistance, making it suitable for parts exposed to harsh environments. It is also resistant to wear and offers a low coefficient of friction, which enhances its usability in mechanical components like bearings and gears.

Common Applications of PEEK:

• Aerospace components
• Medical implants and devices
• High-temperature electrical insulators
• Gears and bearings
• Valve seats and seals
• Engine parts

Characteristics Table for PEEK:

Property	PEEK
Temperature Resistance (°C)	-50 to 250
Tensile Strength (MPa)	90-110
Yield Strength (MPa)	100
Elongation at Break (%)	20-30
Hardness (Shore D)	85
Chemical Resistance	Excellent
Corrosion Resistance	High
Density (g/cm³)	1.30-1.32
Magnetic Properties	Non-magnetic
Machinability	Good
Modulus of Elasticity (GPa)	3.6-4.0
Electrical Conductivity	Insulator
Coefficient of Thermal Expansion (µm/m°C)	47-50
Thermal Conductivity (W/mK)	0.25-0.30

PVC (Polyvinyl Chloride)

Polyvinyl Chloride (PVC) is a thermoplastic material widely used in various industries due to its durability and chemical resistance. It is easy to machine and offers great strength, making it ideal for CNC applications. PVC is available in two primary forms: rigid and flexible, each serving different purposes. Rigid PVC is preferred in construction for items like pipes and conduits, while flexible PVC is used in wiring insulation and medical tubing.

Common Grades of PVC and Applications:

• Rigid PVC (RPVC): Used for pipes, fittings, and window profiles.
• Flexible PVC: Used for tubing, hoses, and insulation.
• CPVC (Chlorinated Polyvinyl Chloride): Ideal for hot water pipes and industrial fluid handling.

Characteristics Table for PVC:

Property	Value
Temperature Resistance (°C)	-15 to 60
Tensile Strength (MPa)	48-55
Yield Strength (MPa)	55
Elongation at Break (%)	80-150
Hardness (Shore D)	80-85
Chemical Resistance	Excellent against acids, alkalis
Corrosion Resistance	High
Density (g/cm³)	1.38-1.40
Magnetic Properties	Non-magnetic
Machinability	Easy to machine
Modulus of Elasticity (GPa)	2.9-3.2
Electrical Conductivity	Insulator
Coefficient of Thermal Expansion (µm/m°C)	52-58
Thermal Conductivity (W/mK)	0.19-0.22

Acrylic (PMMA)

Acrylic (PMMA) is a transparent thermoplastic often used as a shatter-resistant alternative to glass. This plastic offers excellent mechanical properties and is easy to cut, mill, and drill, making it a popular choice in industries like consumer electronics, medical devices, and automotive components.

Acrylic’s machinability comes from its good dimensional stability, low moisture absorption, and ability to maintain a smooth surface finish after cutting. It can be machined into complex shapes without losing its optical clarity. Additionally, it provides good mechanical strength and high abrasion resistance, making it durable for a variety of applications.

Different Grades of Acrylic (PMMA) and Applications:

• General Purpose Acrylic: Used in display cases, signage, and lighting fixtures.
• Impact Modified Acrylic: Used in safety shields, automotive parts, and protective barriers.
• UV Resistant Acrylic: Commonly used in outdoor signage and skylights.

Characteristics Table for Acrylic (PMMA):

Property	Value
Temperature Resistance (°C)	-40 to 90
Tensile Strength (MPa)	65-80
Yield Strength (MPa)	55-70
Elongation at Break (%)	4-6
Hardness (Rockwell)	M95-M100
Chemical Resistance	Resistant to diluted acids
Corrosion Resistance	High
Density (g/cm³)	1.18-1.19
Magnetic Properties	Non-magnetic
Machinability	Easy to machine
Modulus of Elasticity (GPa)	3.2-3.5
Electrical Conductivity	Insulator
Coefficient of Thermal Expansion (µm/m°C)	70-75
Thermal Conductivity (W/mK)	0.17-0.19

Plastics

Plastics like UHMW PE have become highly regarded in CNC machining due to their adaptability, durability, and performance in various applications. UHMW PE specifically is recognized for its outstanding impact resistance and low coefficient of friction, making it suitable for machined components across various industries.

UHMW PE (Ultra-High Molecular Weight Polyethylene)

UHMW PE is a thermoplastic known for its extremely high molecular weight, which gives it impressive properties such as abrasion resistance, corrosion resistance, and low coefficient of friction. It’s commonly used in applications requiring wear resistance and smooth movement, such as machined components in industrial equipment, medical devices, and CNC machined parts for automotive use.

One of the key features that makes UHMW PE suitable for CNC machining is its excellent machinability and resistance to wear. It can endure heavy mechanical loads while maintaining its structural integrity, even under continuous friction or abrasive conditions. Additionally, its strength-to-weight ratio makes it an excellent choice for applications where lightweight yet durable materials are needed.

Different Grades of UHMW PE

• Virgin Grade UHMW PE: Commonly used in food processing and medical applications due to its high purity and FDA compliance.
• Reprocessed UHMW PE: Offers similar performance to virgin UHMW PE but is more cost-effective and used in industrial applications.
• High-Temperature UHMW PE: Designed for environments with elevated temperatures, offering enhanced heat resistance.

Common Applications of UHMW PE:

• Conveyor belts and guides in manufacturing lines
• Medical prosthetics and surgical devices
• Industrial wear strips and machine parts
• Automotive components like bushings and gears

Characteristics Table for UHMW PE:

 

Property	Value
Temperature Resistance (°C)	-260 to 82
Tensile Strength (MPa)	21-40
Yield Strength (MPa)	20-30
Elongation at Break (%)	300-400
Hardness (Shore D)	62-66
Chemical Resistance	Excellent resistance to chemicals
Corrosion Resistance	High
Density (g/cm³)	0.93-0.94
Magnetic Properties	Non-magnetic
Machinability	High
Modulus of Elasticity (GPa)	0.6-0.8
Electrical Conductivity	Insulator
Coefficient of Thermal Expansion (µm/m°C)	100-250
Thermal Conductivity (W/mK)	0.4-0.5

 

Foams

EVA Foam (Ethylene-Vinyl Acetate) is a durable and flexible material widely used in CNC machining. It is suitable for projects requiring shock absorption, cushioning, and thermal insulation. EVA foam’s soft and resilient properties make it an ideal material for creating components like packaging inserts, shoe soles, and custom padding.

Also, Polyurethane Foam is known for its versatility and resilience. It has excellent dimensional stability, making it suitable for CNC machining projects that require intricate cuts and details. This foam can be used for applications ranging from insulation to automotive seating.

Common Grades:

• Standard EVA Foam: Used in protective packaging, footwear, and padding.
• High-Density EVA Foam: Designed for applications needing enhanced durability and impact resistance, like automotive and sports equipment.
• Rigid Polyurethane Foam: Provides excellent thermal insulation and is commonly used in structural applications.
• Flexible Polyurethane Foam: Known for its cushioning properties, used in upholstery, automotive seating, and bedding.

Common Applications:

• Shoe soles and cushioning
• Packaging inserts and protective cases
• Automotive padding
• Medical padding and orthopedic devices
• Soundproofing and acoustic panels

Characteristics Table for EVA and Polyurethane Foam

Property	EVA Foam	Polyurethane Foam
Temperature Resistance (°C)	-40 to 70	-70 to 100
Tensile Strength (MPa)	0.6 – 2.5	0.2 – 1.5
Yield Strength (MPa)	Not applicable	0.3 – 1.0
Elongation at Break (%)	100 – 400	30 – 300
Hardness (Shore A)	25 – 60	20 – 80
Chemical Resistance	Good	Moderate
Corrosion Resistance	High	High
Density (g/cm³)	0.03 – 0.20	0.02 – 0.50
Magnetic Properties	Non-magnetic	Non-magnetic
Machinability	High	High
Modulus of Elasticity (GPa)	0.02 – 0.10	0.05 – 0.30
Electrical Conductivity	Insulator	Insulator
Coefficient of Thermal Expansion (µm/m°C)	200 – 300	150 – 250
Thermal Conductivity (W/mK)	0.03 – 0.04	0.02 – 0.05

Wood

Wood is an excellent material for CNC machining, thanks to its machinability and natural aesthetic qualities. It can be cut, shaped, and engraved with precision, making it a popular choice for furniture, decorative items, and custom prototypes. CNC machining can handle both hardwoods and softwoods, each offering unique characteristics for specific applications.

Hardwood

Hardwoods like Oak and Maple are dense, strong, and durable. These properties make them suitable for high-wear applications where strength and durability are essential. Hardwoods are typically used for furniture, cabinetry, and flooring.

Types of Hardwood:

• Oak: Known for its hardness, density, and resistance to fungal attacks.
• Maple: Valued for its fine grain and durability, often used in furniture and flooring.

Common Applications:

• High-quality furniture
• Cabinetry
• Hardwood flooring
• Decorative trim and molding

Softwood

Softwoods like Pine and Cedar are lighter and more flexible, making them easier to machine. These woods are ideal for projects that require intricate detailing or are cost-sensitive. Softwoods are commonly used in construction, paneling, and lightweight furniture.

Types of Softwood:

• Pine: Lightweight and easy to work with, often used in construction and furniture.
• Cedar: Known for its resistance to decay and aromatic qualities, making it ideal for outdoor furniture and closets.

Common Applications:

• Lightweight furniture
• Outdoor structures
• Paneling and siding
• Closets and storage units

Characteristics Table for Hardwoods and Softwoods

Property	Hardwood (Oak, Maple)	Softwood (Pine, Cedar)
Temperature Resistance (°C)	Moderate	Moderate
Tensile Strength (MPa)	90 – 100	40 – 50
Yield Strength (MPa)	50 – 70	20 – 30
Elongation at Break (%)	Low	Low
Hardness (Janka scale, lbf)	1200 – 1500 (Oak, Maple)	380 – 560 (Pine, Cedar)
Chemical Resistance	Moderate	Low
Corrosion Resistance	Low	Low
Density (g/cm³)	0.7 – 0.9	0.3 – 0.5
Magnetic Properties	Non-magnetic	Non-magnetic
Machinability	High	Very High
Modulus of Elasticity (GPa)	10 – 14	6 – 8
Electrical Conductivity	Insulator	Insulator
Coefficient of Thermal Expansion (µm/m°C)	5 – 6	4 – 5
Thermal Conductivity (W/mK)	0.15 – 0.20	0.10 – 0.15

Composites

Composites are engineered materials designed to perform better than the individual components that make them up. In CNC machining, composites are highly suitable because they can be tailored for specific applications requiring a mix of strength, lightweight, and durability. Composites are frequently used in the aerospace, automotive, and construction industries due to their dimensional stability and abrasion resistance.

Different Grades:

• Carbon Fiber-Reinforced Polymer (CFRP): This composite is lightweight but incredibly strong, offering high resistance to corrosion and excellent tensile strength. It is commonly used in the aerospace and automotive sectors.
• Glass Fiber-Reinforced Polymer (GFRP): Known for its strength and durability, GFRP is widely used in construction and electrical insulation applications. It is less expensive than carbon fiber composites but still offers excellent mechanical properties.
• Kevlar-Reinforced Composites: Kevlar composites are recognized for their high impact resistance and are commonly used in protective gear and automotive components.

Common Applications of Composite Materials:

• Aerospace frames
• Automotive panels
• High-performance sports equipment
• Wind turbine blades
• Protective helmets and armor

Characteristics Table for Composite Materials

Property	CFRP (Carbon Fiber)	GFRP (Glass Fiber)	Kevlar Composite
Temperature Resistance (°C)	200 – 300	150 – 250	250 – 400
Tensile Strength (MPa)	600 – 1000	450 – 900	2750
Yield Strength (MPa)	500 – 900	350 – 700	1500
Elongation at Break (%)	1.5 – 2.5	2 – 4	3.5
Hardness (Shore D)	85 – 90	70 – 85	60 – 80
Chemical Resistance	High	Moderate	High
Corrosion Resistance	High	Moderate	High
Density (g/cm³)	1.5 – 2.0	1.8 – 2.2	1.44
Magnetic Properties	Non-magnetic	Non-magnetic	Non-magnetic
Machinability	Moderate	Moderate	Difficult
Modulus of Elasticity (GPa)	70 – 120	35 – 55	60 – 130
Electrical Conductivity	Poor	Poor	Poor
Coefficient of Thermal Expansion (µm/m°C)	5 – 7	10 – 12	2 – 5
Thermal Conductivity (W/mK)	0.3 – 0.5	0.25 – 0.45	0.04 – 0.10

Carbon Fiber Reinforced Plastics (CFRP)

CFRP is a popular composite material in CNC machining projects, especially in high-performance industries like aerospace and automotive. This material is known for its high strength-to-weight ratio and excellent tensile strength. CFRP is highly favored in applications where both weight reduction and structural integrity are key. The combination of carbon fibers and a polymer matrix provides high resistance to corrosion and wear, making it ideal for parts exposed to extreme conditions.

Common Applications of CFRP:

• Aerospace components
• Automotive body panels and frames
• Sporting equipment like bicycles and tennis rackets
• Medical devices such as prosthetics
• High-performance marine parts

Grades of CFRP:

• Standard Modulus: Offers excellent strength and is used in general applications.
• Intermediate Modulus: Provides a balance between strength and flexibility.
• High Modulus: Offers superior stiffness, ideal for applications where rigidity is critical.

Property	Value
Temperature Resistance (°C)	200 – 300
Tensile Strength (MPa)	600 – 1000
Yield Strength (MPa)	500 – 900
Elongation at Break (%)	1.5 – 2.5
Hardness (Shore D)	85 – 90
Chemical Resistance	High
Corrosion Resistance	High
Density (g/cm³)	1.5 – 2.0
Magnetic Properties	Non-magnetic
Machinability	Moderate
Modulus of Elasticity (GPa)	70 – 120
Electrical Conductivity	Poor
Coefficient of Thermal Expansion (µm/m°C)	5 – 7
Thermal Conductivity (W/mK)	0.3 – 0.5

Fibreglass

Fiberglass, also known as Glass Fiber Reinforced Plastic (GFRP), is another composite material that offers an excellent balance of strength, weight, and corrosion resistance. It is widely used in both construction and consumer products, offering a cost-effective alternative to carbon fiber. Fiberglass is often chosen for its durability, making it ideal for applications that demand high abrasion resistance and dimensional stability.

Common Applications of Fiberglass:

• Building materials for construction
• Insulation panels
• Boat hulls and marine components
• Automotive parts
• Industrial and electrical enclosures

Grades of Fiberglass:

• E-Glass: Standard grade used in most applications, offering good strength and low cost.
• S-Glass: Provides higher strength and stiffness, ideal for demanding applications.
• C-Glass: Focuses on chemical resistance and is used in environments where corrosion is a concern.

Property	Value
Temperature Resistance (°C)	150 – 250
Tensile Strength (MPa)	450 – 900
Yield Strength (MPa)	350 – 700
Elongation at Break (%)	2 – 4
Hardness (Shore D)	70 – 85
Chemical Resistance	Moderate
Corrosion Resistance	High
Density (g/cm³)	1.8 – 2.2
Magnetic Properties	Non-magnetic
Machinability	Moderate
Modulus of Elasticity (GPa)	35 – 55
Electrical Conductivity	Poor
Coefficient of Thermal Expansion (µm/m°C)	10 – 12
Thermal Conductivity (W/mK)	0.25 – 0.45

Ceramics

Ceramics are a class of materials known for their extreme hardness and excellent thermal stability. These characteristics make them well-suited for industries like aerospace, medical, and automotive, where parts need to endure high stress and abrasive conditions without breaking down. CNC machining can handle ceramics, although it requires specialized cutting tools due to the brittle nature of these materials. Ceramics are often used when parts must resist wear, corrosion, and maintain dimensional stability under high temperatures.

Some of the most commonly machined ceramics include alumina (Al2O3), zirconia (ZrO2), and silicon carbide (SiC). These materials are favored because they maintain their mechanical properties even under extreme conditions.

Characteristics of Ceramics in CNC Machining:

Property	Value
Temperature Resistance (°C)	Up to 1600
Tensile Strength (MPa)	150 – 500
Yield Strength (MPa)	100 – 300
Elongation at Break (%)	0.1 – 0.5
Hardness (Vickers)	1200 – 1500
Chemical Resistance	High
Corrosion Resistance	High
Density (g/cm³)	3.5 – 6.0
Magnetic Properties	Non-magnetic
Machinability	Low
Modulus of Elasticity (GPa)	250 – 400
Electrical Conductivity	Poor
Coefficient of Thermal Expansion (µm/m°C)	5 – 10
Thermal Conductivity (W/mK)	20 – 30

Alumina

Alumina (Al2O3) is one of the most commonly used ceramics in CNC machining due to its high hardness and excellent thermal stability. It is frequently used in the production of wear-resistant parts, electrical insulators, and medical components. Alumina is available in various grades, with each grade offering slightly different properties to match specific machining projects.

Common Grades of Alumina:

1. 99.5% Alumina – High purity and used in medical devices and electrical insulation.
2. 96% Alumina – A lower-cost option for applications requiring corrosion resistance.
3. 85% Alumina – Used where mechanical strength is less critical but cost efficiency is important.

Common Applications:

• Medical devices such as dental implants and prosthetics
• Wear-resistant components in industrial machinery
• Electrical insulators in high-voltage equipment
• Precision parts in aerospace and automotive industries

Characteristics of Alumina in CNC Machining:

Property	Value
Temperature Resistance (°C)	Up to 1700
Tensile Strength (MPa)	260 – 300
Yield Strength (MPa)	N/A
Elongation at Break (%)	<0.1
Hardness (Vickers)	1500
Chemical Resistance	Excellent
Corrosion Resistance	High
Density (g/cm³)	3.9
Magnetic Properties	Non-magnetic
Machinability	Low
Modulus of Elasticity (GPa)	370 – 400
Electrical Conductivity	Poor (acts as an insulator)
Coefficient of Thermal Expansion (µm/m°C)	7 – 9
Thermal Conductivity (W/mK)	25 – 35

Silicon Nitride

Silicon nitride is a high-performance ceramic known for its excellent thermal shock resistance, high strength, and low coefficient of friction. This makes it a suitable material for high-stress environments, especially where corrosion resistance and the ability to withstand wear are necessary. It’s commonly used in applications such as bearings, turbine blades, and cutting tools.

Different Grades and Common Applications:

• Standard Silicon Nitride: Used for bearing components and turbine blades due to its ability to endure high loads and maintain dimensional stability.
• Sintered Silicon Nitride: Frequently found in cutting tools and engine parts because of its superior mechanical properties and abrasion resistance.

Characteristics of Silicon Nitride for CNC Machining

Property	Value
Temperature Resistance (°C)	Up to 1400
Tensile Strength (MPa)	700 – 1000
Yield Strength (MPa)	N/A
Elongation at Break (%)	<1
Hardness (Vickers)	1400 – 1800
Chemical Resistance	High
Corrosion Resistance	Excellent
Density (g/cm³)	3.2 – 3.4
Magnetic Properties	Non-magnetic
Machinability	Fair
Modulus of Elasticity (GPa)	290 – 310
Electrical Conductivity	Insulator
Coefficient of Thermal Expansion (µm/m°C)	2.8 – 3.2
Thermal Conductivity (W/mK)	18 – 25

 

Graphite

Graphite is widely used in CNC machining because of its thermal resistance and high machinability. It is commonly found in electrical components, molds, and tooling applications. Graphite’s ability to withstand high temperatures without deformation makes it an excellent choice for parts that must maintain their integrity under extreme conditions. Additionally, its low wear rate means that graphite parts last longer in demanding environments.

Common Applications:

1. Electrode material in electrical discharge machining (EDM) processes.
2. Mold-making for high-temperature applications.
3. Insulation components in furnaces and other high-temperature equipment.
4. Lubrication components in environments requiring low friction.

Characteristics of Graphite for CNC Machining

Property	Value
Temperature Resistance (°C)	Up to 3000
Tensile Strength (MPa)	20 – 65
Yield Strength (MPa)	N/A
Elongation at Break (%)	<0.5
Hardness (Mohs)	1 – 2
Chemical Resistance	High
Corrosion Resistance	High
Density (g/cm³)	1.7 – 2.3
Magnetic Properties	Non-magnetic
Machinability	Excellent
Modulus of Elasticity (GPa)	10 – 30
Electrical Conductivity	High
Coefficient of Thermal Expansion (µm/m°C)	4 – 8
Thermal Conductivity (W/mK)	100 – 200

What is the hardest material to CNC?

Tungsten carbide is often considered the hardest material to CNC machine. Its extreme hardness and wear resistance make it difficult to cut, requiring specialized cutting tools and methods. 

This material is commonly used in applications where high tensile strength and abrasion resistance are essential, such as cutting tools and wear-resistant parts.

What is the easiest material to CNC?

Aluminum is one of the easiest materials to CNC machine. It offers a great balance of strength to weight ratio, is easy to machine, and produces a smooth surface finish. 

Commonly used in aerospace and automotive industries, aluminum’s excellent machinability makes it ideal for prototyping and mass production projects. Its lightweight and low friction properties make it a top choice for many machining projects.

Which is the most durable material for CNC machining?

Stainless steel 316 (SS 316) is considered one of the most durable materials for CNC machining. 

Known for its corrosion resistance, tensile strength, and ability to withstand high temperatures, it is commonly used in medical devices, engine parts, and marine applications. SS 316 is ideal for parts requiring high durability and resistance to harsh environments.

What Materials Can Not Be CNC Machined?

Certain materials are not suitable for CNC machining due to their physical and chemical properties. These include materials that are too soft, brittle, or have poor heat resistance, which can cause deformation or breakage during the machining process. For example:

1. Rubber: Its elasticity makes it difficult to machine precisely, and it can lose its shape under pressure.
2. Foam: While foam may be cut for certain applications, it is not suitable for detailed CNC machining due to its lack of structural integrity.
3. Ceramics: Brittle ceramics can fracture under high-speed CNC cutting conditions, especially if not properly processed.

Other materials like glass and certain composites may also pose challenges for CNC machining, particularly when it comes to maintaining precision and avoiding cracking. 

Materials with extreme hardness, such as tungsten carbide, also resist standard CNC cutting tools, though specialized tools may be used in these cases.

What Are the Best Practices for Machining Specific Materials?

When working with different materials in CNC machining, it’s essential to adjust techniques to suit the properties of each material. 

Metals and plastics, for example, behave differently under cutting tools due to their thermal conductivity, hardness, and mechanical properties. Following best practices ensures precision and efficiency in every machining project.

For Metals

When machining metals, it’s essential to consider factors such as speed, feed rates, and coolant use to ensure precise results and avoid material damage. Below are some best practices for working with metals in CNC machining:

• Speed: The optimal speed for machining metals varies depending on the material. For softer metals like aluminum, higher speeds are generally better as they allow for smoother cuts. Stainless steel and harder metals require slower speeds to reduce heat buildup and tool wear. Using the right speed helps in achieving a smooth surface finish and maintaining the integrity of the material.
• Feed Rates: The feed rate determines how fast the tool moves through the material. Metals like carbon steel and alloy steel typically require slower feed rates to prevent overheating, while materials like aluminum alloys can handle faster feed rates due to their higher strength-to-weight ratio. Proper feed rates also ensure minimal tool wear and precision in production parts.
• Coolant Use: Coolant plays a vital role in machining metals. Its primary function is to reduce heat generated by friction, especially when machining harder metals like stainless steel. Using coolant also enhances the tool’s lifespan and improves the overall surface finish of machined components. For metals with high thermal conductivity, such as copper alloys, coolants can prevent overheating and maintain material properties.

For Plastics

Working with plastic materials requires careful attention to prevent issues like melting and ensure clean cuts.

• Preventing Melting: Plastics, such as polypropylene (PP), polyvinyl chloride (PVC), and polycarbonate (PC), have low melting points compared to metals. To avoid melting, it’s crucial to use slower cutting speeds and higher feed rates. Using a proper coolant or air blast can also help dissipate heat, especially in ultra-high molecular weight polyethylene (UHMW PE), which is often used in CNC machining materials due to its abrasion resistance and durability.
• Achieving Clean Cuts: To achieve clean cuts in plastics, sharp cutting tools are a must. Dull tools can lead to rough edges and poor surface finishes on plastic parts. Using the right tooling also prevents material warping. Materials like nylon and acetal are easy to machine, but care must be taken to avoid excessive tool pressure, which can distort the part. Ensuring a smooth surface finish enhances the quality of cnc machined parts, particularly in applications like consumer electronics or medical devices.

What Are Common Material Testing Protocols in CNC Machining?

In CNC machining, testing materials is essential to ensure they can withstand the machining process while maintaining their structural integrity. Common protocols include tensile testing to measure tensile strength, hardness tests, and corrosion resistance checks for materials like stainless steel 316 SS. These tests help in selecting the right CNC machining materials for specific applications, especially in industries where mechanical properties are critical, such as aerospace or automotive sectors.

What Are the Cost Implications of Different CNC Machining Materials?

When considering different materials for CNC machining, cost is a significant factor. Here’s a breakdown of the cost implications for commonly used materials over time:

• Aluminium: Affordable and easy to machine, but costs can rise with specific alloy grades like 6061.
• Stainless Steel: Higher initial costs due to its corrosion-resistant properties, making it ideal for long-term projects.
• Plastics (e.g., Polycarbonate): Lower material costs but may require additional machining to achieve a smooth surface finish.
• Carbon Steel: Economical for high-strength applications, but machining complexity can increase labor costs.
• Titanium: Expensive, both in raw material and machining costs, but excellent for high strength-to-weight ratio needs.

What Are Emerging Trends in CNC Machining Materials?

As technology advances, the materials used in CNC machining are evolving to meet new industry demands. Manufacturers are constantly searching for materials that offer enhanced mechanical properties while balancing cost and sustainability. Key trends are focusing on strength-to-weight ratio, corrosion resistance, and environmental impact. The push toward more efficient and durable materials is shaping the future of CNC machining materials.

Smart Materials

One of the most exciting developments in the field is the rise of smart materials. These materials can change their properties in response to external stimuli like temperature or pressure. 

For example, shape-memory alloys are gaining traction because of their ability to revert to a pre-defined shape after deformation. 

Smart materials have great potential in fields like aerospace and medical devices, where precision and adaptability are essential. Their use could revolutionize the design and functionality of CNC machined parts in these industries.

Sustainable Alternatives

Sustainability is another important focus in CNC machining. Traditional CNC machining materials, like aluminum and carbon steel, while efficient, have a significant environmental footprint. Increasingly, manufacturers are exploring sustainable alternatives such as bio-based composites and recycled plastics. 

These sustainable materials not only help reduce waste but also maintain the strength-to-weight ratio and abrasion resistance required for high-performance applications. 

Some plastic materials, such as polypropylene (PP), are already proving effective as eco-friendly options for many projects.

Conclusion

Whether you’re working with metals, plastics, or composites, selecting the right material for CNC machining is crucial to the success of your project. 

Before making a decision, it’s important to thoroughly assess each material’s strengths, tolerances, and potential limitations. As CNC machining continues to evolve, the focus is shifting toward smarter, more adaptive materials, with a growing emphasis on sustainability. 

Industries like aerospace, automotive, and consumer goods are driving demand for precision and durability, pushing further innovation in material choices. The future of CNC machining will depend on striking the right balance between cost, performance, and environmental responsibility.

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