Comparison of 1.2344 and 1.2343 tool steels|Best factory - FCSSTEEL

Choosing between 1. tool steel and 1. tool steels can greatly affect your project. They both work great.But they excel in different areas like heat resistance, wear, or machinability. Are you unsure which steel to use for your next heavy-duty job? One of these could be just what you need. However, there’s one important factor to consider that might change your decision.

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Chemical Composition

Tool steels’ composition works like a secret formula. This formula decides how well they perform and what jobs they handle best. Take grades 1. and 1.. Their carbon, vanadium, and other element ratios create the right balance for specific tasks. I find it’s like selecting the proper tool. Each grade has unique strengths and features made for particular challenges.1. has much more vanadium (0.85-1.15%) than 1. (0.30-0.50%). Vanadium boosts strength at high temperatures. It also improves wear resistance and hot hardness.

Composition of 1. (X37CrMoV5-1) and 1. (X40CrMoV5-1)

Steel Grade Carbon (C) Silicon (Si) Manganese (Mn) Chromium (Cr) Molybdenum (Mo) Vanadium (V) 1. (X37CrMoV5-1) 0.33-0.41% 0.80-1.20% 0.25-0.50% 4.80-5.50% 1.10-1.50% 0.30-0.50% 1. (X40CrMoV5-1) 0.37-0.45% 0.80-1.20% 0.25-0.50% 4.80-5.50% 1.20-1.50% 0.85-1.15%

How These Differences Matter

When it comes to tough tasks, 1.’s extra vanadium is like a shield, giving it incredible wear resistance. I’d definitely recommend it for the heavy-duty work where things are bound to get rough. It can take the heat—literally—thanks to the added vanadium and carbon, standing strong even under extreme conditions. On the other hand, 1. has a bit less vanadium and carbon, which makes it tougher, like a reliable companion that bends without breaking. It’s perfect for jobs where you need that balance of flexibility and strength. So, if you’re facing high heat or wear-and-tear, go for 1.. But if toughness and flexibility are the stars of the show, 1. has got you covered.

Properties and Performance

Comparing 1. and 1. tool steels shows clear differences in four areas: Toughness.Heat resistance .Hardness.Wear resistance. They’re like two strong competitors. Both last long, but each has strengths that decide success based on the job. I think small property changes strongly affect results in sudden heat situations or extended use. From my experience, it’s like picking between two good options. One handles heat slightly better. The other holds up against friction and abrasion over time.

Hardness

After heat treatment, both 1. and 1. tool steels become very hard. They reach 46 to 54 HRC. I’ve used both steels for tooling jobs, and they perform well in real-world situations.But let’s talk about heavy workloads. During high-speed cutting or molding tasks, I’ve noticed differences. 1. handles sudden impacts better because it bends more easily. 1. works differently—it keeps tools sharp longer and stays strong even when heated. This makes it better for jobs involving friction or heat.Need impact resistance? Pick 1.. Want something that lasts longer under friction? Choose 1.. Both steels deliver reliable results depending on your needs.

Toughness

The toughness of 1. is better, which is suitable to withstand the alternating cold and hot conditions. 1. pays more attention to the balance of strength and hardness.

Tool Steel Grade Elongation Impact Toughness/Tensile Strength Features 1. about 10 – 15% 14 – 18 J/cm² Has good plasticity and resistance to cold and heat fatigue 1. Slightly lower (about 20%) – MPa Toughness is slightly less than 1., but adjustable by tempering

Heat Resistance

1. tool steel has a wide range of heat-resistant temperatures. It is recommended to use a hardness of 40-50 HRC to maintain high temperature stability 1. heat cracking performance is outstanding. High temperature strength is higher. Suitable for long-term work in 500-600℃ environment (such as aluminum die casting mold). Both are suitable for high temperature scenarios, but 1. has better thermal cracking resistance and oxidation resistance at extreme high temperatures.

Service Life

In tough environments like die-casting, 1. lasts longer than other materials. It can handle extreme heat and wear better than most. I saw this myself in a steel forging plant last year. The 1. dies performed well under high temperatures, while others started to wear down. It keeps going even when conditions are tough. This durability in heat and friction is why it’s trusted for heavy-duty tasks, making it perfect for jobs that require both strength and precision.

Machinability

For shaping and cutting tool steels, 1. machines better than 1.. I’ve worked with both grades and prefer 1.’s lower alloy content – it processes smoother for detailed tool shapes. Last month, we made a die-casting mold using 1.. The material’s predictable behavior helped us finish faster and under budget while keeping quality high. This matters most for budget-driven jobs where speed and efficiency decide success.

Cost

1. is more cost-effective than 1., mainly due to its lower alloy content. From my experience, this makes it an excellent option for projects that demand budget-conscious decisions. I’ve worked on several manufacturing jobs where cost was a major factor, and in those cases, 1. came through perfectly. Its reduced alloy mix doesn’t sacrifice essential performance, making it a reliable steel choice when financial flexibility is limited. The practical advantages of 1. lie in its balance—offering great toughness at a lower price point without compromising key features.

Applications

1. and 1. tool steels are dependable in tough conditions. They excel in high-pressure environments like die casting, forging, and plastic molding. These steels perform well under extreme heat, where precision and durability matter most. Both have their own advantages but are designed to succeed in the most demanding industrial tasks.

Steel Grade Applications 1. (H11) Die casting tools for aluminum, magnesium, and zinc alloys
Forging dies and inserts
Extrusion tools for light metals
Hot work punches and mandrels
Plastic injection molds
Ejector pins
Tool holders and chucks 1. (H13) Die casting dies for aluminum and magnesium at higher temperatures
Forging dies for steel and titanium
Extrusion tools for steel and high-temperature alloys
Hot trimming tools
Hot shear blades
Pressure die casting tools

Key Differences in Application

1. is selected for more demanding high-temperature applications due to its superior hot hardness and wear resistance.

1. is better suited for larger dies or tools with complex geometries, offering improved toughness.

1. is favored for high production volumes and longer run times, particularly in severe service conditions.

Both steels are commonly used in similar industries, but 1. is typically chosen for applications that require higher performance and tool longevity, often influenced by operational temperature, production scale, and cost factors.

Availability

Both grades are sold globally through major suppliers. From my experience, 1. is easier to get immediately, while 1. often needs advance planning for custom orders or rare sizes. I recommend ordering early if you need special treatments like heat processing or certifications – these add time to deliveries for both steels.

1. (H11) Availability

Property Details Stock Availability More frequently stocked than 1. Price Costs less than 1. in most cases Size Options Round bars (8 – 400mm), plates (16 – 500mm), and slabs Delivery Time Standard sizes ship in 1 – 4 weeks Monthly Supply Major suppliers can deliver up to tons

1. (H13) Availability

Property Details Stock Availability Limited stock, requires more careful checking of supplier inventories Price Priced higher than 1. Delivery Time Some sizes take 2 – 6 weeks to ship Monthly Supply Major suppliers offer up to tons

summary

Imagine a material that offers exceptional durability, thermal stability, and versatility across various demanding industrial applications. DIN 1. Steel, also known as X37CrMoV5-1, stands out as a top choice for engineers and manufacturing professionals seeking reliable performance in die casting, forging, and extrusion. But what exactly makes this tool steel so remarkable? In this comprehensive guide, we’ll delve into the key properties that set DIN 1. apart, explore its heat treatment processes, and compare it to other tool steels like AISI H11. Curious about how this steel can revolutionize your manufacturing processes? Let’s uncover the secrets behind DIN 1.’s enduring success.

Material Properties

Chemical Composition

DIN 1. steel, also known as X37CrMoV5-1, boasts a well-balanced chemical composition that enhances its performance in demanding applications. The typical composition includes:

• Carbon (C): 0.33-0.41%
• Silicon (Si): 0.90-1.20%
• Manganese (Mn): 0.30-0.50%
• Chromium (Cr): 4.8-5.5%
• Molybdenum (Mo): 1.10-1.50%
• Vanadium (V): 0.25-0.50%
• Phosphorus (P): ≤0.03%
• Sulfur (S): ≤0.03%

These elements work together to enhance the steel’s strength, toughness, and resistance to thermal fatigue.

Physical Properties

With a density of approximately 7.80 x 10^3 kg/m³ and an elastic modulus around 216 x 10^3 MPa, this steel provides a solid foundation for high-temperature applications. Additionally, DIN 1. steel has moderate thermal conductivity, essential for managing heat during high-temperature operations, and a controlled coefficient of thermal expansion, reducing the risk of thermal fatigue.

Mechanical Properties

The mechanical properties of DIN 1. steel are critical for its performance in tool and die applications:

• Hardness: After heat treatment, this steel can achieve a hardness of up to 52 HRc, ensuring excellent wear resistance.
• Tensile Strength: The steel offers high tensile strength, vital for maintaining integrity under stress.
• Toughness: Known for its exceptional toughness, DIN 1. can withstand heavy impact and stress without fracturing.
• Resistance to Thermal Shock: The steel’s ability to resist thermal shock makes it ideal for applications involving rapid temperature changes.

Thermal Stability

DIN 1. steel retains its mechanical properties even at high temperatures, making it ideal for hot work applications. Its resistance to softening at elevated temperatures ensures that tools and components maintain their hardness and wear resistance under prolonged heat exposure.

Wear Resistance

The combination of chromium, molybdenum, and vanadium enhances the wear resistance of DIN 1. steel. This property is crucial for applications where the steel is subjected to abrasive conditions, such as in die casting and extrusion tools.

Machinability and Weldability

DIN 1. steel is relatively easy to machine with the appropriate tooling and techniques. Its machinability can be further improved by preheating and using cutting fluids to reduce tool wear. Welding this steel requires specific procedures to maintain its properties, including preheating and post-weld heat treatment to avoid cracking and ensure structural integrity.

Corrosion Resistance

Although not primarily known for its corrosion resistance, the chromium content provides some protection against oxidation and corrosion, making it more durable in certain environments compared to other tool steels without chromium.

By understanding these material properties, engineers and manufacturers can make informed decisions on the best applications for DIN 1. steel, ensuring optimal performance and longevity of the tools and components made from this versatile material.

Heat Treatment Processes

Annealing

Annealing is an essential heat treatment process for DIN 1. steel that softens the material, enhances machinability, and relieves internal stresses. This process helps in preparing the steel for further machining operations by making it more manageable and less prone to cracking during subsequent processing.

Process Parameters

• Temperature: 750-790°C or 843-898°C (-°F)
• Cooling: Furnace cooling to achieve a hardness of around 229 HB or less than 235 HB

Stress Relief Annealing

Stress relief annealing removes leftover stresses from machining or manufacturing. This step is essential for maintaining dimensional stability and preventing distortion.

Process Parameters

• Temperature: 600-650°C
• Cooling: Furnace cooling

Hardening

Hardening boosts the steel’s hardness and wear resistance, making it ideal for high-stress uses like die casting and forging dies.

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Process Parameters

• Preheating: Initial preheating at 350-400°C, followed by a second preheating at 750-850°C
• Hardening Temperature: -°C
• Quenching: Options include air, oil, pressure gas (N2), or hot bath

Typically, hardening achieves a hardness range of 52-56 HRC, enhancing the steel’s durability and resistance to wear.

Tempering

Tempering follows hardening to reduce brittleness and increase toughness. This involves reheating the steel to a lower temperature and then cooling it.

Process Parameters

• Temperature: 500-600°C
• Duration: At least 3 hours, with additional cycles at lower temperatures if needed

Benefits of Heat Treatment

The heat treatment processes described above confer several benefits to DIN 1. steel:

• Enhanced Hardness: Essential for wear resistance and durability in tool applications.
• Improved Toughness: Critical for absorbing impacts and preventing fractures.
• Stress Relief: Ensures dimensional stability and prevents distortion during use.
• Machinability: Easier to machine and shape into desired forms.

By carefully controlling these heat treatment processes, manufacturers can tailor the properties of DIN 1. steel to meet specific application requirements, ensuring optimal performance and longevity of the tools and components made from this versatile material.

Equivalents and Standards

Equivalents of DIN 1. Steel

DIN 1. steel is known for its high performance in demanding applications, and it has several international equivalents that offer similar properties.

United States (AISI H11)

In the U.S., DIN 1. is equivalent to AISI H11, which is renowned for its toughness and heat resistance. This steel is commonly used in applications requiring high thermal stability.

Japan (SKD6)

In Japan, the equivalent material is SKD6, standardized under JIS G. SKD6 shares similar chemical compositions and properties, making it suitable for hot work applications.

United Kingdom (BH11)

The British equivalent for DIN 1. steel is BH11, specified under BS . BH11 is utilized in applications requiring high thermal resistance and toughness.

China (4Cr5MoV)

In China, the equivalent to DIN 1. is 4Cr5MoV, according to GB/T . This material is used in similar applications, offering comparable performance characteristics.

Standards Compliance

DIN 1. steel meets various international standards, ensuring its suitability for global applications. It complies with DIN standards in Germany, ASTM A681 in the United States, JIS G in Japan, BS in the United Kingdom, and GB/T in China. Adhering to these standards guarantees the steel’s quality and performance.

• DIN Standards (Germany): Ensures consistent quality and performance.
• ASTM Standards (U.S.): ASTM A681 specifies requirements for tool steels.
• JIS Standards (Japan): JIS G outlines properties and testing methods for tool steels.
• BS Standards (UK): BS specifies requirements for tool steels.
• GB/T Standards (China): GB/T defines chemical composition and mechanical properties.

Importance of Equivalents and Standards

Understanding the equivalents and standards for DIN 1. steel is crucial for manufacturers and engineers. It allows for the selection of appropriate materials that meet specific performance requirements, ensuring compatibility in international projects. Standards compliance guarantees that the steel will perform reliably, providing confidence in its use for critical applications.

Applications and Uses

Die Casting and Forging Tools

DIN 1. steel is widely used in manufacturing die casting and forging tools because of its excellent thermal stability and resistance to wear. Its ability to withstand high temperatures and thermal shocks makes it ideal for:

• Die Casting Molds and Forging Dies: Ideal for casting light alloys like aluminum and magnesium and essential for hot forging applications due to their ability to withstand repeated heating and cooling cycles.

Processing Aluminum and Other Metals

This steel’s robustness and resistance to wear make it suitable for processing aluminum and other non-ferrous metals. Common applications include:

• Extrusion Tools: Such as liners, extrusion stems, and dies that require high durability.
• Press Tools: Utilized in forming and shaping non-ferrous metals.

Plastic Molding

DIN 1. is also used in plastic molding applications where high polish and toughness are required. Typical uses include:

• Plastic Molds and Injection Molding: Used for high-quality surface finishes and precision in mold inserts, providing durability and resistance to thermal fatigue.

Extruder Components

The steel’s excellent wear resistance and toughness make it suitable for extruder components, ensuring long-lasting performance. Applications include:

• Extruder Screws: Used in plastic and rubber extrusion processes.
• Barrels: Providing a durable lining to withstand the abrasive nature of the extrusion process.

General Engineering

In general engineering, DIN 1. steel is valued for its high performance and durability in various demanding applications. It is used in:

• High-Performance Components: Including gears, shafts, and other parts that require a blend of strength, toughness, and wear resistance.

Guides for Using DIN 1. Steel in Manufacturing

Selection of DIN 1. Steel

When selecting DIN 1. steel for manufacturing purposes, it’s crucial to consider its unique properties and suitability for specific applications. This steel is particularly well-suited for high-temperature environments and applications requiring excellent wear resistance and toughness.

Machining Guidelines

Machining DIN 1. steel requires careful consideration of its hardness and wear resistance. Here are some guidelines to ensure optimal results:

• Preheating: Heat the steel to 300-400°C before machining to prevent thermal shock and make it easier to work with.
• Cutting Fluids: Use high-quality cutting fluids to minimize tool wear and enhance the surface finish.
• Tooling: Employ high-speed steel (HSS) or carbide tools to handle the hardness of DIN 1..

Welding Considerations

Welding DIN 1. steel can be challenging due to its high alloy content. To achieve successful welds, follow these steps:

• Preheating and Technique: Preheat the steel to 300-400°C, use low-hydrogen electrodes, and control heat input to prevent cracking and reduce thermal stress.
• Post-Weld Heat Treatment: Perform stress relief annealing at 600-650°C to alleviate residual stresses and restore toughness.

Heat Treatment Processes

Heat treatment is essential for optimizing the properties of DIN 1. steel. The following processes are recommended:

Annealing

• Process: Gently heat the steel to 750-790°C or 843-898°C, then allow it to cool slowly in the furnace.
• Objective: Soften the material and relieve internal stresses for improved machinability.

Hardening

• Process: First, preheat the steel to 350-400°C, then increase the temperature to 750-850°C. For hardening, heat it to -°C and quench it in air, oil, or nitrogen.
• Objective: Increase hardness and wear resistance for tool applications.

Tempering

• Process: Reheat the hardened steel to 500-600°C and hold for at least three hours. Multiple tempering cycles may be necessary for optimal toughness.
• Objective: Reduce brittleness and enhance toughness.

Application-Specific Tips

Die Casting

• Mold Design: Ensure proper cooling channels to manage thermal loads and reduce the risk of thermal fatigue.
• Surface Treatment: Consider surface treatments like nitriding to enhance wear resistance and extend tool life.

Forging

• Tool Preparation: Preheat the forging tools to operating temperatures to minimize thermal shock.
• Maintenance: Inspect and maintain forging dies regularly to prevent wear and extend their service life.

Plastic Molding

• Polishing: Achieve a high-quality surface finish on mold cavities to ensure smooth and defect-free plastic parts.
• Temperature Control: Maintain consistent mold temperatures to avoid warping and ensure dimensional accuracy.

Quality Control

Implementing rigorous quality control measures is vital for ensuring the performance and longevity of tools made from DIN 1. steel:

• Inspection: Regularly inspect tools for wear, cracks, and other signs of damage.
• Testing: Perform hardness and toughness tests to verify the effectiveness of heat treatment processes.
• Maintenance: Schedule regular maintenance to address wear and prevent unexpected tool failures.

By following these guidelines, manufacturers can effectively utilize DIN 1. steel in various applications, ensuring optimal performance and durability of their tools and components.

Frequently Asked Questions

Below are answers to some frequently asked questions:

What are the key properties of 1. Steel?

DIN 1. steel, also known as X37CrMoV5-1, is a chromium-molybdenum-vanadium alloyed hot work tool steel characterized by excellent mechanical properties and high performance in elevated temperature environments. It boasts high tensile strength, good yield strength, and hardness typically ranging from 46 to 54 HRC after appropriate heat treatment. The steel exhibits outstanding thermal shock and fatigue resistance, making it suitable for applications such as die casting tools, forging tools, extrusion dies, and plastic molds. Its density is around 7.85 g/cm³, and it has a thermal conductivity of approximately 25.3 W/mK at room temperature.

How does DIN 1. compare to other tool steels like AISI H11?

DIN 1. (X37CrMoV5-1) and AISI H11 are both hot work tool steels with similar chemical compositions and properties, including good thermal shock resistance and high-temperature strength. They differ slightly in vanadium content, with AISI H11 having higher toughness and slightly reduced wear resistance compared to DIN 1.. Both steels are used in die-casting and high-temperature applications, with AISI H11 also being utilized in aerospace components. They offer comparable hardenability and machinability, making them both suitable for demanding manufacturing processes.

What are the applications of DIN 1. Steel?

DIN 1. steel is used in various industries due to its excellent thermal properties and durability. Key applications include die casting tools, where its thermal stability and resistance to thermal fatigue are beneficial; forging tools, thanks to its wear resistance; and extrusion plants for producing tools like liners and mandrels. Additionally, it is used in plastic molds for injection molding because of its high polishability and toughness, in seamless tube production as mandrel bars, and in general engineering applications requiring high strength and durability.

How is 1. Steel heat treated?

1. Steel is heat treated through a multi-step process. Initially, the steel is annealed at 843–898°C and then slowly cooled to 538°C to reduce hardness and residual stresses. Stress relieving is done at 650–700°C to mitigate mechanical stress. For hardening, the steel is preheated to 350–400°C, then 750–850°C, and finally heated to 980–°C before quenching in air, oil, or water. Tempering follows, typically at 550–600°C for at least three hours, which may be repeated to achieve the desired hardness and toughness.

Can DIN 1. Steel be used in die casting?

Yes, DIN 1. steel can be used in die casting. It is a versatile hot work tool steel known for its excellent thermal stability, toughness, and wear resistance, making it ideal for high-temperature processes like die casting. This steel maintains its mechanical properties under elevated temperatures, provides good resistance to thermal fatigue and cracking, and achieves suitable hardness after heat treatment. As a result, it is commonly used for die casting tools and molds, particularly in high-pressure die casting applications, contributing to longer tool lifetimes and reduced maintenance costs.

What are the wear resistance properties of DIN 1. Steel?

DIN 1. steel, also known as X37CrMoV5-1, is renowned for its high wear resistance, particularly in medium temperature environments. This is due to its excellent toughness, oxidation resistance, and thermal fatigue resistance, which help maintain structural integrity under fluctuating conditions. The steel’s chemical composition, which includes chromium, molybdenum, and vanadium, further enhances its wear resistance. These properties make DIN 1. steel ideal for demanding applications such as hot punches, forging dies, extrusion tooling, and mold components where durability against wear and fatigue is crucial.