If you work with heavy machinery, mining tools, or industrial components, you’ve likely heard of both tungsten and tungsten carbide. They sound similar—after all, tungsten is a key ingredient in tungsten carbide—and people often wonder: “Which one is stronger?” As someone who’s sourced and tested both for industrial applications (think drill bits, seal rings, and high-heat parts), I can tell you: It depends on what “stronger” means. Tungsten carbide outperforms pure tungsten in hardness and wear resistance—critical for tools that grind through rock or seal high-pressure pumps. But pure tungsten shines in extreme heat and has unique metallic toughness. In this post, I’ll break down their strengths (literally) in simple terms, with real-world examples from factories and mines. No confusing jargon—just clear answers to help you pick the right material for the job.
First: What’s the Difference Between Tungsten and Tungsten Carbide?
Before we compare “strength,” let’s clarify what these materials are. They’re related but totally different:
- Pure tungsten is a naturally occurring metal (symbol: W on the periodic table). It’s dense, silvery, and one of the hardest pure metals on Earth. You might find it in high-temperature parts like furnace filaments or rocket nozzles.
- Tungsten carbide (WC) is a composite: It’s made by combining tungsten powder with carbon, then adding a metal “binder” (usually cobalt) to hold it all together. It’s not a pure metal—it’s more like a super-strong mix of metal and ceramic-like crystals. You’ll see it in drill bits, seal rings, and wear-resistant liners.
Think of it like this: Pure tungsten is like a solid steel bar, while tungsten carbide is like reinforced concrete—same base ingredients (tungsten/cement) but mixed with other materials (carbon/cobalt vs. gravel/steel) to boost specific strengths.
“Stronger” Means Different Things—Here’s How They Compare
In industry, “strength” isn’t one-size-fits-all. We care about hardness (resistance to scratches), wear resistance (how long it lasts under friction), toughness (ability to take impacts), and heat resistance. Let’s break down who wins where:
1. Hardness: Tungsten Carbide Crushes Tungsten
Hardness is about resisting scratches or indentation. On the Mohs hardness scale (where diamond = 10), pure tungsten scores around 7.5. Tungsten carbide? It hits 8.5–9—close to diamond, and way harder than pure tungsten.
Why this matters: For parts that rub against other materials (like a seal ring pressing against a pump shaft, or a drill bit grinding through stone), hardness = longer life. A pure tungsten drill bit would dull quickly in granite, but a tungsten carbide one stays sharp for weeks.
Real example: A mining client once tried pure tungsten liners in their ore crushers. The liners scratched and wore down in 2 weeks. Switching to tungsten carbide liners extended that to 6 months—all because of the extra hardness.
2. Wear Resistance: Tungsten Carbide Lasts Longer Under Friction
Wear resistance is about withstanding constant rubbing, scraping, or erosion. Tungsten carbide dominates here, too. Its tight crystal structure (tungsten + carbon) and cobalt binder create a material that’s hard to chip, grind down, or erode.
Pure tungsten, while hard for a metal, is still “softer” at the microscopic level. Under constant friction (like a valve stem rubbing against a seat), its surface wears away gradually.
Industrial use case: In chemical pumps, seal rings face nonstop friction from rotating shafts and corrosive fluids. Tungsten carbide seal rings last 5–10x longer than pure tungsten ones because they resist wear from both the shaft and the fluid.
3. Toughness (Impact Resistance): It’s a Tie—But Depends on the Job
Toughness is about resisting breaks when hit or dropped. Here, things get trickier:
- Pure tungsten is a metal, so it bends slightly before breaking (think of a thick steel wire—you can bend it, but it won’t shatter). This makes it tough against sudden impacts.
- Tungsten carbide is more brittle by nature (thanks to its crystal structure), but the cobalt binder helps. A well-made tungsten carbide part (with 10–15% cobalt) can take moderate impacts, but a heavy hit (like dropping a tool) might crack it.
When to choose which: For parts that get banged around (like mining tools dropped in rough terrain), pure tungsten’s toughness is better. For parts under steady pressure (like a seal ring in a pump), tungsten carbide’s wear resistance matters more than extreme impact toughness.
4. Heat Resistance: Pure Tungsten Wins at Extreme Temperatures
Tungsten has the highest melting point of any pure metal: 3,422°C (that’s hotter than lava!). Tungsten carbide, while heat-resistant, starts to break down around 1,400–1,600°C (its binder melts or oxidizes).
Why this matters: In furnaces, rocket engines, or welding equipment, where temperatures exceed 2,000°C, pure tungsten is irreplaceable. But for most industrial jobs (pumps, drills, factories), temperatures stay below 500°C—so tungsten carbide’s lower heat resistance isn’t a problem.
A Quick Comparison Chart
| Property | Pure Tungsten | Tungsten Carbide (with cobalt binder) |
|---|---|---|
| Hardness (Mohs scale) | 7.5 | 8.5–9 |
| Wear Resistance | Good (for a metal) | Excellent (outlasts most materials) |
| Impact Toughness | High (bends before breaking) | Moderate (can crack under heavy hits) |
| Melting Point | 3,422°C | ~1,500°C (binder fails at high temps) |
| Best For | High-heat parts, impacts | Wear-resistant tools, seals, grinders |
Why Tungsten Carbide Is More Popular in Industrial Tools
You’ll see tungsten carbide in most wear-heavy jobs (drills, seals, liners) because its key strengths—hardness and wear resistance—solve the biggest industrial headaches: downtime from replacing worn parts.
Pure tungsten, while impressive in heat and toughness, is softer than tungsten carbide, so it wears out faster in high-friction jobs. It’s also more expensive to shape into complex parts (like seal rings) compared to tungsten carbide, which is made via powder metallurgy (easier to mold into custom shapes).
3 Myths About Tungsten vs. Tungsten Carbide
Let’s clear up common mix-ups:
-
Myth: “Tungsten carbide is just ‘stronger tungsten.’”
Fact: They’re different materials. Tungsten carbide’s strength comes from its composite structure (tungsten + carbon + binder), not just “tougher tungsten.” -
Myth: “Tungsten carbide works everywhere tungsten does.”
Fact: No—at extreme temperatures (over 2,000°C), tungsten carbide fails, but pure tungsten thrives. -
Myth: “Tungsten is ‘weaker’ because it’s softer.”
Fact: “Softness” here is relative. Pure tungsten is still one of the hardest metals—just not as hard as tungsten carbide. Its strength lies in heat resistance and toughness, not hardness.
Final Takeaway: Choose Based on Your “Strength” Needs
Tungsten carbide is “stronger” than pure tungsten in the ways that matter most for most industrial tools: it’s harder, resists wear better, and lasts longer in high-friction jobs like drilling, sealing, or crushing. But pure tungsten is stronger in extreme heat and handles impacts better.
The next time you’re choosing between them, ask: What’s my part doing? If it grinds, seals, or scrapes, go with tungsten carbide. If it faces 2,000°C+ heat or heavy impacts, pure tungsten is better.
Need help picking for your specific equipment (pump seals, mining drills, furnace parts)? Reach out—we’ll match you to the right material with real-world test data, not just specs.