Can Tungsten Carbide Be Welded to Steel? Industrial Practical Possibilities and Methods

In industrial production, there is often a need to combine wear-resistant tungsten carbide parts (such as wear liners, tool cutting edges) with high-strength steel components (such as equipment bases, brackets). This combination leverages the wear resistance of tungsten carbide and the toughness of steel. At this point, many people wonder: "Can tungsten carbide be directly welded to steel?" As an industry practitioner with years of experience addressing such issues, the clear answer is: Yes, it can be done, but it is not easy.

The significant differences in material properties between tungsten carbide and steel (e.g., melting point, thermal expansion characteristics) mean that common welding methods often lead to cracks. However, reliable bonding can be achieved by selecting the right welding process and mastering key techniques. This article explains the core reasons why welding is difficult, 3 feasible industrial methods, practical application scenarios, and precautions to avoid failure—all grounded in real factory experience, ensuring clarity and relevance for industrial use.

1. Core Reasons Why Welding Tungsten Carbide to Steel Is Difficult

The fundamental challenge in welding tungsten carbide (WC) to steel (e.g., carbon steel, stainless steel) stems from their distinct material properties, primarily in three aspects:

1.1 Large Differences in Melting Point and High-Temperature Stability

Steel typically has a melting point of 1,450–1,550°C, while tungsten carbide exhibits poor stability at high temperatures: above 1,300°C, it tends to decompose (releasing carbon) and even become brittle. The high temperatures of conventional welding (e.g., arc welding, which often exceeds 1,500°C) directly damage tungsten carbide, rendering it ineffective before a strong bond is formed.

1.2 Mismatched Thermal Expansion Coefficients

During welding, materials expand when heated and contract when cooled. Steel has a much higher thermal expansion coefficient than tungsten carbide: for example, carbon steel has a coefficient of approximately 12×10⁻⁶/°C, while tungsten carbide’s is only 5×10⁻⁶/°C. During cooling, steel contracts far more than tungsten carbide, creating massive thermal stress that causes weld cracks or tungsten carbide fracturing.

1.3 Inherent Differences in Material Nature

Steel is a ductile metal that can deform under stress without breaking. In contrast, tungsten carbide is a ceramic-like composite (composed of tungsten-carbon crystals and cobalt binders) and is inherently brittle. This difference means that after welding, steel’s deformation under load is directly transferred to tungsten carbide, leading to brittle fracture.

Industrial Case: A workshop once attempted to weld tungsten carbide blades to steel tool holders using conventional arc welding. During cooling, the thermal stress from the steel holder’s contraction caused the tungsten carbide blades to crack completely along the weld—rendering the entire batch of parts useless.

2. 3 Feasible Industrial Methods for Welding Tungsten Carbide to Steel (with Application Scenarios)

Despite the challenges, mature industrial solutions exist for this welding task. The core strategies are "controlling temperature to protect tungsten carbide" and "alleviating stress to avoid cracking." Below are the three most widely used methods:

2.1 Hard Brazing (Most Common, Low Cost)

Hard brazing does not rely on melting the base materials (tungsten carbide and steel). Instead, it uses a filler metal (e.g., copper-based or silver-based alloys) with a lower melting point than both materials. The filler is heated until molten (while the base materials remain solid), then flows into gaps between the surfaces to form a bond upon cooling.

• Process Principle: Heating temperatures are controlled between 800–1,100°C—high enough to melt the filler but low enough to prevent tungsten carbide decomposition or brittleness. When cooled, the solidified filler creates a mechanical and partial metallurgical bond.
• Advantages: Low equipment requirements (flame or resistance furnace heating works), low cost, suitable for mass production, minimal thermal damage to tungsten carbide, and high welding efficiency.
• Disadvantages: Lower bond strength than fusion welding, poor impact resistance, and unsuitable for high-load or high-frequency impact applications.
• Application Scenarios:
  • Wear liners for mining equipment (e.g., welding tungsten carbide blocks to steel crusher bases);
  • General cutting tools (e.g., joining tungsten carbide edges to steel woodworking planer bodies);
  • Wear rings for pumps (e.g., welding tungsten carbide rings to the inner walls of steel pump casings to enhance wear resistance).

Industrial Case: A concrete mixer manufacturer used copper-based brazing to attach small tungsten carbide blocks to steel mixer blades. The blades’ service life extended from 3 months to 12 months, with an overall cost reduction of approximately 30%.

2.2 Diffusion Bonding (High Strength, Suitable for Precision Parts)

Diffusion bonding involves pressing tungsten carbide and steel tightly together, then holding them at a specific temperature (600–1,000°C) and pressure (10–50MPa) for a period. Atomic diffusion occurs at the interface, allowing atoms of the two materials to interpenetrate and form a metallurgical bond.

• Process Principle: The combination of low temperature and high pressure prevents tungsten carbide decomposition while promoting atomic diffusion. No filler metal is needed—bonding relies on atomic movement within the materials themselves, resulting in weld strength close to that of the base materials.
• Advantages: Extremely high bond strength, no visible weld interface, excellent sealing, suitable for precision parts or high-strength requirements, and minimal impact on material properties post-welding.
• Disadvantages: High equipment investment (specialized high-temperature, high-pressure diffusion furnaces are required), long production cycles (each weld takes several hours), high cost, and unsuitability for large or irregular parts.
• Application Scenarios:
  • Spools for hydraulic valves (e.g., welding tungsten carbide sealing surfaces to steel spools for leak-free performance);
  • Precision mold inserts (e.g., joining tungsten carbide punches to steel cold stamping die frames for dimensional accuracy);
  • High-strength aerospace components (requiring both steel’s toughness and tungsten carbide’s wear resistance, with strict reliability demands).

2.3 Laser Welding (Flexible, Suitable for Complex Shapes and Repairs)

Laser welding uses a high-energy laser beam (e.g., fiber laser) focused on the weld area of tungsten carbide and steel. The localized temperature rises rapidly to melt the materials, while a specialized filler metal (e.g., nickel-cobalt alloy wire) is added to form a molten pool. Upon cooling, the filler and base materials solidify to create a metallurgical bond.

• Process Principle: The laser’s concentrated energy limits heating to a small area (molten pool diameter typically 0.5–2mm), allowing precise control of temperature and heat input. This minimizes thermal stress. The filler metal compensates for material differences between tungsten carbide and steel, improving weld compatibility.
• Advantages: Fast welding speed, small heat-affected zone, ability to weld complex shapes (e.g., curved surfaces, small hole edges), suitable for small-batch production or part repairs, and aesthetic weld appearance.
• Disadvantages: High equipment cost (fiber laser welders are expensive), high skill requirements for operators (precise control of laser focus is needed), and unsuitability for extra-large parts.
• Application Scenarios:
  • Repair of worn parts (e.g., welding tungsten carbide layers to restore dimensions of worn steel shafts);
  • Manufacturing of irregular tools (e.g., joining tungsten carbide cutting heads to steel刀柄 for custom milling cutters);
  • Small precision parts (e.g., welding tungsten carbide wear points to steel valve cores with diameters ≤10mm).

3. 4 Key Operational Tips to Avoid Welding Failure

Even with the right welding method, improper operation can lead to weld cracks, tungsten carbide detachment, or other issues. Based on industrial experience, focus on these four critical steps:

3.1 Pre-Weld Surface Preparation: Ensure Cleanliness and Roughness

Oil, oxide layers, or rust on the weld surfaces will impair filler metal wetting or atomic diffusion, leading to bond failure. Specific steps:

• Tungsten carbide surface: Sand with 800–1,000-grit sandpaper to remove oxides until a uniform metallic luster is visible. Wipe with alcohol or acetone to remove sanding dust and oil.
• Steel surface: Remove rust with a wire brush or acid pickling, then sand to create a rough surface (roughness Ra 1.6–3.2μm) to improve adhesion with filler metal. Finally, clean with acetone using a lint-free cloth.

Negative Case: A workshop failed to fully remove oil from a steel base before hard brazing. While initial inspections showed a good bond, the tungsten carbide block detached after 1 week of operation—due to poor adhesion between the filler metal and oil-contaminated steel.

3.2 Strictly Control Welding Temperature and Time

Temperature and time are critical to welding quality; adjust them based on the method and material type:

• Hard brazing: Keep temperatures between 800–1,100°C (avoid exceeding 1,100°C to prevent tungsten carbide decomposition). Heating time should be just enough to melt the filler and fill gaps (typically 10–30 seconds per part).
• Diffusion bonding: Maintain temperatures at 600–1,000°C and uniform pressure (to avoid tungsten carbide fracturing from localized stress). Hold time depends on part thickness (usually 1–3 hours for full atomic diffusion).
• Laser welding: Adjust laser power based on part thickness (typically 500–1,500W). Use pulse heating (heat-pause-heat cycles) with 1–2 seconds per pulse to prevent overheating.

3.3 Use a Transition Layer to Alleviate Thermal Stress

To address mismatched thermal expansion, insert a transition layer (e.g., nickel alloy sheet, copper alloy sheet) between tungsten carbide and steel. Its thermal expansion coefficient lies between the two materials, acting as a buffer to reduce cooling stress:

• Implementation: Cut the transition layer to match the weld area size, sandwich it between tungsten carbide and steel, and weld the assembly together. The layer thickness should be 0.1–0.5mm (excessive thickness reduces overall bond strength).
• Result: A mining equipment manufacturer reduced weld crack rates from 40% to below 8% by adding a nickel alloy transition layer when welding tungsten carbide wear liners.

3.4 Post-Weld Slow Cooling: Release Internal Stress

Rapid cooling after welding (e.g., quenching in water) exacerbates thermal stress and causes cracking. Use slow cooling to release stress:

• Natural slow cooling: Place welded parts in a dry, wind-free environment and let cool naturally for over 24 hours. Avoid exposure to low temperatures or drafts.
• Low-temperature tempering: When possible, place parts in a tempering furnace, hold at 200–300°C for 2–4 hours, then cool with the furnace to room temperature. This further releases internal stress and improves bond stability.

4. Common Misconceptions Clarified

4.1 "The Higher the Weld Strength, the Better"

Pursuing excessive weld strength is counterproductive. Tungsten carbide’s inherent brittleness means that an overly strong bond will transfer steel deformation directly to tungsten carbide, causing it to fracture. A good weld balances "reliability" and "stress buffering" to avoid brittle failure.

4.2 "All Tungsten Carbide Can Be Welded"

Cobalt content significantly affects weldability. Tungsten carbide with low cobalt content (<5%) has poor adhesion to fillers or base metals, leading to welding failure. Choose grades with 8–15% cobalt for better compatibility.

4.3 "No Post-Weld Inspection Is Needed"

Inspection is critical to ensure quality. After welding, perform visual checks (for cracks, porosity), mechanical tests (tensile, impact tests), and sealing tests (for sealed parts) to avoid faulty parts causing equipment breakdowns.

Conclusion

Welding tungsten carbide to steel is entirely feasible, but it requires selecting the right method based on part purpose, size, and performance requirements:

• Choose hard brazing for mass production and moderate strength needs;
• Choose diffusion bonding for precision parts and high-strength demands;
• Choose laser welding for complex shapes or repairs.

By strictly following surface preparation, temperature control, transition layer use, and slow cooling, you can avoid cracks and detachment, achieving a reliable bond that combines tungsten carbide’s wear resistance and steel’s toughness.

If your parts involve special working conditions (e.g., extra-large size, ultra-high pressure, strong corrosion), and you are unsure about the suitable welding process, feel free to reach out. We can provide customized solutions and even conduct sample welding tests to ensure the final product meets industrial requirements.