M35 Steel (HSS): Properties and Key Applications
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Table Of Content
Table Of Content
M35 steel, classified as a high-speed steel (HSS), is primarily utilized in the manufacturing of cutting tools and dies. This steel grade is known for its excellent hardness, wear resistance, and ability to retain its hardness at elevated temperatures, making it a preferred choice for high-performance applications. M35 steel is an alloyed tool steel that typically contains significant amounts of tungsten and cobalt, which enhance its properties.
Comprehensive Overview
M35 steel is classified as a high-speed steel, specifically a cobalt high-speed steel, which is designed to withstand high temperatures and maintain hardness during cutting operations. The primary alloying elements in M35 include:
- Tungsten (W): Enhances hardness and wear resistance.
- Cobalt (Co): Improves high-temperature performance and toughness.
- Molybdenum (Mo): Contributes to strength and hardenability.
The unique combination of these alloying elements results in a steel that exhibits exceptional hardness, typically reaching values of 62-65 HRC after heat treatment. M35 steel also demonstrates good toughness, making it less prone to chipping and breaking under stress.
Advantages:
- High Hardness: Retains hardness at elevated temperatures, making it suitable for high-speed cutting applications.
- Wear Resistance: Excellent resistance to wear, extending tool life.
- Versatility: Can be used for various cutting tools, including drills, taps, and milling cutters.
Limitations:
- Cost: Higher alloy content leads to increased material costs compared to standard tool steels.
- Machinability: More challenging to machine than lower alloy steels due to its hardness.
- Brittleness: While tough, it can be brittle if not properly heat-treated.
M35 steel holds a significant position in the market for high-speed steels, often used in industries requiring precision cutting tools. Its historical significance lies in its development as a response to the need for materials that could withstand the rigors of high-speed machining.
Alternative Names, Standards, and Equivalents
| Standard Organization | Designation/Grade | Country/Region of Origin | Notes/Remarks |
|---|---|---|---|
| UNS | T31535 | USA | Closest equivalent to M2 with cobalt addition |
| AISI/SAE | M35 | USA | Commonly used in tool manufacturing |
| ASTM | A600 | USA | Specification for high-speed steels |
| DIN | 1.3243 | Germany | Minor compositional differences |
| JIS | SKH55 | Japan | Similar properties, but with different heat treatment recommendations |
The differences between M35 and its equivalents, such as M2 or SKH55, often lie in the cobalt content and heat treatment processes, which can significantly affect performance in high-speed applications. For instance, the addition of cobalt in M35 enhances its ability to withstand thermal fatigue, making it preferable for specific high-performance applications.
Key Properties
Chemical Composition
| Element (Symbol and Name) | Percentage Range (%) |
|---|---|
| C (Carbon) | 0.90 - 1.05 |
| W (Tungsten) | 5.50 - 6.75 |
| Mo (Molybdenum) | 4.00 - 5.00 |
| Co (Cobalt) | 4.00 - 5.00 |
| Cr (Chromium) | 3.75 - 4.50 |
| Mn (Manganese) | 0.20 - 0.40 |
| Si (Silicon) | 0.20 - 0.40 |
The primary role of the key alloying elements in M35 steel includes:
- Carbon: Provides hardness and strength through the formation of carbides.
- Tungsten: Enhances wear resistance and maintains hardness at high temperatures.
- Cobalt: Improves toughness and thermal stability, allowing for better performance in high-speed applications.
Mechanical Properties
| Property | Condition/Temper | Typical Value/Range (Metric) | Typical Value/Range (Imperial) | Reference Standard for Test Method |
|---|---|---|---|---|
| Tensile Strength | Annealed | 850 - 1000 MPa | 123 - 145 ksi | ASTM E8 |
| Yield Strength (0.2% offset) | Annealed | 600 - 800 MPa | 87 - 116 ksi | ASTM E8 |
| Elongation | Annealed | 5 - 10% | 5 - 10% | ASTM E8 |
| Hardness (HRC) | Quenched & Tempered | 62 - 65 HRC | 62 - 65 HRC | ASTM E18 |
| Impact Strength | Room Temperature | 20 - 30 J | 15 - 22 ft-lbf | ASTM E23 |
The combination of high tensile and yield strength, along with excellent hardness, makes M35 steel suitable for applications involving significant mechanical loading and structural integrity requirements. Its ability to withstand high temperatures without losing hardness is particularly beneficial in high-speed machining environments.
Physical Properties
| Property | Condition/Temperature | Value (Metric) | Value (Imperial) |
|---|---|---|---|
| Density | Room Temperature | 8.2 g/cm³ | 0.297 lb/in³ |
| Melting Point/Range | - | 1400 - 1450 °C | 2552 - 2642 °F |
| Thermal Conductivity | Room Temperature | 25 W/m·K | 14.5 BTU·in/h·ft²·°F |
| Specific Heat Capacity | Room Temperature | 460 J/kg·K | 0.11 BTU/lb·°F |
| Electrical Resistivity | Room Temperature | 0.000015 Ω·m | 0.000015 Ω·in |
Key physical properties such as density and thermal conductivity are crucial for applications where weight and heat dissipation are concerns. The relatively high density of M35 steel contributes to its robustness, while its thermal conductivity allows for effective heat management during cutting operations.
Corrosion Resistance
| Corrosive Agent | Concentration (%) | Temperature (°C/°F) | Resistance Rating | Notes |
|---|---|---|---|---|
| Chlorides | 3-5 | 20-60 °C (68-140 °F) | Fair | Risk of pitting |
| Acids | 10-20 | 20-40 °C (68-104 °F) | Poor | Susceptible to corrosion |
| Alkaline Solutions | 5-10 | 20-60 °C (68-140 °F) | Fair | Moderate resistance |
M35 steel exhibits moderate resistance to corrosion, particularly in chloride environments, where it may be susceptible to pitting. Compared to other high-speed steels like M2, M35's cobalt content provides slightly better resistance to oxidation at elevated temperatures, but it is still not recommended for applications in highly corrosive environments.
Heat Resistance
| Property/Limit | Temperature (°C) | Temperature (°F) | Remarks |
|---|---|---|---|
| Max Continuous Service Temp | 600 °C | 1112 °F | Retains hardness at high temps |
| Max Intermittent Service Temp | 650 °C | 1202 °F | Short-term exposure only |
| Scaling Temperature | 700 °C | 1292 °F | Risk of oxidation beyond this temp |
| Creep Strength considerations | 500 °C | 932 °F | Begins to lose strength |
M35 steel performs well at elevated temperatures, maintaining its hardness and strength. However, prolonged exposure to temperatures above 600 °C can lead to oxidation and scaling, which may compromise its integrity.
Fabrication Properties
Weldability
| Welding Process | Recommended Filler Metal (AWS Classification) | Typical Shielding Gas/Flux | Notes |
|---|---|---|---|
| MIG | ER70S-6 | Argon + CO2 | Preheat recommended |
| TIG | ER80S-D2 | Argon | Requires careful control |
| Stick | E7018 | - | Not recommended for thick sections |
M35 steel is generally not recommended for welding due to its high hardness and potential for cracking. Preheating and post-weld heat treatment are essential to minimize these risks. The choice of filler metal is critical to ensure compatibility and maintain mechanical properties.
Machinability
| Machining Parameter | M35 Steel | AISI 1212 | Notes/Tips |
|---|---|---|---|
| Relative Machinability Index | 60 | 100 | More difficult to machine |
| Typical Cutting Speed (Turning) | 30-40 m/min | 80-100 m/min | Use carbide tools |
M35 steel has a lower machinability index compared to more common steels like AISI 1212, making it more challenging to machine. Optimal cutting speeds and tooling are essential to achieve desired results without excessive wear.
Formability
M35 steel is not particularly suited for forming processes due to its high hardness and brittleness. Cold forming is generally not feasible, while hot forming may be possible with careful temperature control. Work hardening can occur, necessitating consideration of bend radii and forming techniques.
Heat Treatment
| Treatment Process | Temperature Range (°C/°F) | Typical Soaking Time | Cooling Method | Primary Purpose / Expected Result |
|---|---|---|---|---|
| Annealing | 800 - 850 °C (1472 - 1562 °F) | 1 - 2 hours | Air | Reduce hardness, improve machinability |
| Hardening | 1200 - 1250 °C (2192 - 2282 °F) | 30 - 60 minutes | Oil | Increase hardness |
| Tempering | 550 - 600 °C (1022 - 1112 °F) | 1 hour | Air | Reduce brittleness, increase toughness |
The heat treatment of M35 steel involves austenitizing, quenching, and tempering to achieve the desired hardness and toughness. The metallurgical transformations during these processes significantly impact the microstructure, leading to the formation of fine carbides that enhance wear resistance.
Typical Applications and End Uses
| Industry/Sector | Specific Application Example | Key Steel Properties Utilized in this Application | Reason for Selection (Brief) |
|---|---|---|---|
| Aerospace | Cutting tools for aircraft manufacturing | High hardness, wear resistance | Precision and durability |
| Automotive | Drill bits and taps | Retains hardness at high temperatures | Efficiency in machining |
| Metalworking | Milling cutters | Toughness and wear resistance | Long tool life |
Other applications include:
- Tooling: M35 is widely used for manufacturing high-performance tooling due to its hardness and wear resistance.
- Machining: Ideal for high-speed machining operations where tool longevity is critical.
M35 steel is chosen for these applications due to its ability to maintain performance under extreme conditions, ensuring precision and efficiency in manufacturing processes.
Important Considerations, Selection Criteria, and Further Insights
| Feature/Property | M35 Steel | M2 Steel | HSS Grade X | Brief Pro/Con or Trade-off Note |
|---|---|---|---|---|
| Key Mechanical Property | High hardness | Good toughness | Excellent wear resistance | M35 offers better high-temp performance |
| Key Corrosion Aspect | Moderate resistance | Fair resistance | Good resistance | M35 is less resistant to acids |
| Weldability | Poor | Fair | Poor | M35 requires careful welding techniques |
| Machinability | Low | Moderate | Moderate | M35 is harder to machine |
| Formability | Poor | Good | Fair | M35 is not suitable for forming |
| Approx. Relative Cost | High | Moderate | Moderate | M35's alloying elements increase cost |
| Typical Availability | Moderate | High | High | M35 may be less common than M2 |
When selecting M35 steel, considerations include its cost-effectiveness, availability, and specific application requirements. While it offers superior performance in high-speed applications, its higher cost and lower machinability may necessitate careful evaluation against alternatives like M2 steel or other high-speed steels.
In conclusion, M35 steel is a high-performance material that excels in demanding applications, particularly in the manufacturing of cutting tools. Its unique properties, while advantageous, also require careful handling and processing to maximize its potential.