Cold-drawn steel pipes, due to their high precision, high surface quality, and excellent mechanical properties, are widely used in machinery manufacturing, hydraulic systems, mold processing, and other fields. When facing high hardness requirements, the choice of material directly determines the product’s performance, service life, and processing feasibility.

First, what are the core principles for material selection in high-hardness cold-drawn steel pipes?
The requirement for high hardness is not a single-indicator pursuit; it requires careful consideration of multiple dimensions, including processing technology, usage environment, and load-bearing conditions. The core principles are as follows:
- Hardness and toughness matching: High hardness is often accompanied by increased brittleness. It is necessary to ensure that the material possesses sufficient toughness while achieving the target hardness to prevent breakage during use.
- Cold working adaptability: Cold drawing is a cold plastic process. The material must have good cold deformation capabilities to avoid defects such as cracking and uneven wall thickness during cold drawing.
- Heat treatment strengthening potential: Most high-hardness requirements require subsequent heat treatment. The material must possess excellent hardenability and tempering stability.
- Environmental adaptability: Based on the corrosive media and temperature range of the usage scenario, materials with corresponding corrosion resistance and high-temperature resistance should be selected.
- Economy and feasibility: Under the premise of meeting performance requirements, priority should be given to materials that are easy to procure and have low processing costs, while also considering the feasibility of mass production.

Second, what are the mainstream cold-drawn steel pipe materials and characteristics for high-hardness requirements?
Based on the characteristics of the cold-drawing process and the need for high hardness strengthening, the mainstream suitable materials are mainly concentrated in two categories: high-quality carbon structural steel and alloy structural steel. Stainless steel or mold steel can be used in some special scenarios. The following is a detailed analysis of each material:
(I) High-quality carbon structural steel cold-drawn steel pipes are the first choice for medium-to-low hardness requirements (HRC 25-40). This type of material has a moderate carbon content, good cold working performance, and can achieve medium hardness through appropriate heat treatment. It is relatively inexpensive and suitable for general high-hardness scenarios where extreme hardness requirements are not necessary, while maintaining toughness.
- 45# steel core characteristics: Carbon content 0.42%-0.50%, it is the most widely used high-quality carbon steel. After cold drawing, a certain hardness can be obtained directly. After quenching and high-temperature tempering, the hardness can be increased to HRC 30-35, while also possessing good comprehensive mechanical properties. It has excellent cold-drawing machinability and can be processed into high-precision thin-walled or thick-walled cold-drawn steel pipes.
Applicable Scenarios: General mechanical parts, low-pressure piston rods in hydraulic systems, automotive steering knuckles, and other components requiring moderate hardness.
Precautions: Hardenability is average. For cold-drawn steel pipes with a wall thickness >15mm, the core hardness may not meet the requirements, necessitating wall thickness control or selection of materials with better hardenability. Weldability is average; preheating is required before welding.
- 50# Steel Core Characteristics: Carbon content 0.47%-0.55%, higher than 45# steel. Slightly higher hardness after cold drawing (HRC 22-28). After quenching and tempering, hardness can reach HRC 35-40. Strength is superior to 45# steel, but toughness is slightly lower. Good cold working performance, suitable for manufacturing parts requiring slightly higher strength and hardness.
Applicable Scenarios: Cold-drawn steel pipe base material for high-strength mechanical transmission shafts, gear shafts, crane hooks, and other components.
Precautions: Cold deformation resistance is greater than 45# steel; deformation must be controlled during cold drawing to avoid cracking. Quenching temperature must be strictly controlled during heat treatment to prevent overheating and increased brittleness.
(II) Cold-drawn alloy structural steel pipes are the core choice for medium-to-high hardness requirements (HRC 40-60). By adding alloying elements such as chromium, manganese, molybdenum, and nickel, the hardenability, tempering stability, and comprehensive mechanical properties of the material are improved. After heat treatment, high hardness can be achieved while maintaining good toughness, making it suitable for key components with high hardness and strength requirements.
- 40Cr core characteristics: Carbon content 0.37%-0.44%, with the addition of 1.00%-1.30% chromium. Hardenability is significantly better than 45# steel. High hardness (HRC 45-52) can be obtained through quenching + low-temperature tempering, while also possessing good strength and wear resistance. It has good cold-drawing machinability and can be strengthened by tempering or quenching after cold drawing.
Applications: High-pressure hydraulic piston rods, precision machine tool spindles, automotive half-shafts, gears, and other critical components; it is one of the preferred materials for medium-to-high hardness cold-drawn steel pipes.
Precautions: The deformation during cold drawing should not be too large (single deformation is recommended to be ≤15%), otherwise work hardening may occur, leading to difficulties in subsequent processing; timely tempering is necessary after heat treatment to eliminate internal stress.
- 20CrMnTi Core Characteristics: Carbon content 0.17%-0.23%, with added chromium, manganese, and titanium alloying elements; good hardenability; after carburizing, quenching, and low-temperature tempering, the surface hardness can reach HRC 58-62, and the core hardness remains at HRC 30-40, possessing excellent surface wear resistance and core toughness. Good cold-drawing machinability, suitable for manufacturing high-precision thin-walled cold-drawn steel pipes.
Applications: Components requiring high surface hardness and high core toughness, such as gear bushings, mold guide pillars, and precision transmission components.
Precautions: Carburizing treatment requires controlled temperature and time to avoid excessively thick or uneven carburized layers; normalizing treatment is necessary before cold drawing to refine the grain and improve cold workability.
- 42CrMo Core Characteristics: Contains 0.38%-0.45% carbon, with added chromium and molybdenum alloying elements. It has excellent hardenability, ensuring core hardening even in thick-walled cold-drawn steel pipes (wall thickness ≤ 50mm). After quenching and tempering, the hardness can reach HRC 45-55, possessing high strength, high toughness, and excellent tempering stability. It has good cold drawing machinability and is suitable for manufacturing high-hardness components subjected to heavy loads and impacts.
Applicable Scenarios: High-pressure hydraulic system high-pressure oil pipes, engineering machinery piston rods, large machinery drive shafts, mold templates, and other components requiring extremely high hardness and strength.
Precautions: The hardness is high after cold drawing; subsequent processing requires annealing to reduce hardness. The quenching temperature during heat treatment should not be too high to prevent cracking.
- 35CrMo core characteristics: Carbon content 0.32%-0.40%, alloy element content slightly lower than 42CrMo, good hardenability, hardness can reach HRC 40-50 after quenching and tempering, balanced comprehensive mechanical properties, better cold workability and weldability than 42CrMo, and relatively low cost.
Applicable scenarios: Medium and high-pressure hydraulic systems, automotive gearbox shafts, mechanical connecting rods, and other components requiring a balance of hardness and toughness.
Precautions: Suitable for manufacturing medium and thick-walled cold-drawn steel pipes. When the wall thickness is too large, it is necessary to ensure that the heat treatment process is matched to avoid insufficient core hardness.
(III) Cold-drawn steel pipes of special materials are suitable for extreme scenarios (HRC ≥60)
For scenarios with extremely high hardness requirements (such as wear-resistant parts of molds, high-hardness parts in corrosive environments), stainless steel or mold steel materials should be selected. These materials are more difficult to cold work and require special processing techniques.
- Cr12MoV (Die Steel) Core Characteristics: Carbon content 1.45%-1.70%, high chromium, molybdenum, and vanadium alloy content. After quenching and low-temperature tempering, the hardness can reach HRC 60-65, possessing extremely high hardness and wear resistance. It has poor cold workability; spheroidizing annealing treatment is required before cold drawing to reduce hardness, and the amount of deformation during cold drawing must be strictly controlled (single deformation ≤8%).
Applicable Scenarios: Parts requiring extreme hardness and wear resistance, such as die guide sleeves, wear-resistant bushings, and high-precision gauges.
Precautions: Cold drawing is difficult and costly, suitable only for special high-hardness applications; it is relatively brittle after heat treatment and should be protected from impact loads.
- Core characteristics of 304/316 stainless steel: Austenitic stainless steel. Its hardness can be increased through work hardening after cold drawing (304 can reach HRC 30-35 after cold drawing, and 316 can reach HRC 32-38). For even higher hardness (HRC 40-45), solution aging treatment can be performed. It possesses excellent corrosion resistance and is suitable for use in corrosive environments such as humid and acidic/alkaline conditions.
Applicable scenarios: High-hardness components in corrosive environments, such as hydraulic pipes in chemical equipment and transmission components in marine engineering.
Precautions: Excessive cold drawing deformation can easily lead to material embrittlement; processing technology must be controlled. Austenitic stainless steel has poor hardenability and cannot achieve high hardness through conventional quenching.

Third, the selection process and precautions for high-hardness cold-drawn steel pipes
(I) Selection process for cold-drawn steel pipes
Identify core requirements: Determine the target hardness range, load-bearing conditions, operating environment, and specifications of the cold-drawn steel pipe;
Preliminary material screening: Match the material type according to hardness requirements, and exclude materials with excessively high costs based on economic considerations;
Verify. Process compatibility: Confirm whether the cold-drawing workability and heat treatment strengthening potential of the selected material meet the production process requirements, especially for thick-walled cold-drawn steel pipes, which require verification of hardenability.
Sample testing: Process samples of the selected cold-drawn steel pipes, testing indicators such as hardness, toughness, and dimensional accuracy to verify whether they meet the requirements.
Mass production: Optimize the processing technology based on the sample test results, and determine the final material and production parameters.
(II) Key Considerations for Cold-Drawn Steel Pipes
Avoid blindly pursuing high hardness: Excessive hardness can lead to decreased material toughness, increasing the risk of breakage during use. A balance must be found between hardness and toughness.
Emphasis on matching heat treatment processes: Material selection must be coordinated with subsequent heat treatment processes. Different materials have significantly different quenching temperatures, tempering temperatures, and holding times. A reasonable heat treatment plan must be developed based on the material characteristics.
Control cold-drawing processing parameters: Parameters such as cold-drawing deformation, drawing speed, and lubrication conditions affect the processing quality and final hardness of cold-drawn steel pipes. Parameters must be optimized based on the cold-working characteristics of the selected material.
Consider the feasibility of material procurement: Some special materials have long procurement cycles and high costs. Supply chain stability must be confirmed before mass production.
Consider subsequent processing needs: If cold-drawn steel pipes require subsequent processes such as welding and machining, materials with good welding and machinability should be selected to avoid difficulties in subsequent processing.

In summary, the material selection for cold-drawn steel pipes requiring high hardness should focus on “performance matching, process adaptability, and economic balance.” Priority should be given to material types based on hardness range: for medium to low hardness (HRC 25-40), 45# and 50# high-quality carbon steel are suitable; for medium to high hardness (HRC 40-60), alloy structural steels such as 40Cr and 42CrMo are preferred; for extremely high hardness (HRC ≥60) or corrosive environments, Cr12MoV die steel or 304/316 stainless steel are suitable. Simultaneously, factors such as processing technology, usage environment, and cost must be comprehensively considered, and the rationality of the selection should be verified through sample testing to ensure that the final product meets the usage requirements.