What Is Spring Steel and Why Does It Matter?
“Can you machine spring steel?”
That was the exact question I asked myself years ago when I got handed a drawing for a small part with ridiculous tolerances—and the word “spring steel” stamped across the title block. I’d machined a lot of tool steels before, but spring steel? That was something else.
So I went deep into the specs, called some old mentors, tried different methods on the shop floor, and made every mistake you could make. Eventually, I figured out what worked and what didn’t. That’s what I’m going to share here.
If you’re an engineer trying to spec the right material, or a machinist trying not to kill another carbide insert, this guide is for you. Let’s break it down.
Overview of Spring Steel
Spring steel is a broad term for a group of steels known for their high yield strength, resilience, and fatigue resistance. These are the materials that “spring back” when bent or twisted, hence the name.
🔍 Common Types of Spring Steel:
| Material Grade | Standard | Type | Properties | Typical Use Case |
|---|---|---|---|---|
| 65Mn | GB/T | Carbon steel | High hardness, good wear resistance | General-purpose springs |
| 1075 / 1095 | AISI | High-carbon | High tensile strength, easy to heat treat | Blades, spring clips |
| 5160 | AISI | Alloy | Chrome alloy, very tough | Automotive leaf springs |
| SUS301 | ASTM/JIS | Stainless Steel | Corrosion resistant, decent elasticity | Electronic spring contacts |
| EN42 / EN45 | BS | Carbon/alloy | Good toughness and formability | Arched springs, leaf springs |
| SK5 | JIS | Carbon steel | Similar to 1095, high precision | Saws, knives, precision spring parts |
📌 Key Mechanical Properties:
| Property | Range | Notes |
|---|---|---|
| Yield Strength | 800 – 1600 MPa | High yield is critical for elasticity |
| Tensile Strength | 1000 – 2000 MPa | High load-bearing capability |
| Hardness (after HT) | HRC 40 – 60 | Depending on grade and quenching method |
| Elongation | 5–20% | Limited ductility due to high strength |
| Modulus of Elasticity | ~200 GPa | Similar to other steels |
Spring steel is used everywhere from car suspensions to electrical connectors to precision surgical devices. It has the strength to take a hit and the memory to return to its shape. That’s why it’s so popular—and why it’s so difficult to machine if you don’t treat it right.
Can Spring Steel Be Machined?
Short answer? Yes.
But the longer answer is: it depends on the condition, the grade, and your tooling setup.
Spring steel can be machined, but it’s not as forgiving as mild steel or even standard tool steels. I’ve broken inserts, smoked drills, and scrapped parts when I treated it like a “normal” metal.
Here’s what I’ve learned through hands-on experience.
🛠️ Machinability Depends on Condition:
Spring steel typically comes in two states:
- Annealed (soft): Easier to machine, better for CNC
- Hardened (heat treated): Very hard, often requires grinding or EDM
When I get material in the annealed state, I machine the part close to final shape, then send it for heat treatment. If the material is already hardened, I skip conventional cutting and go straight to grinding or wire EDM.
⚠️ Machining Challenges with Spring Steel:
| Challenge | Description |
|---|---|
| Tool wear | Even annealed spring steel is abrasive on cutters |
| Work hardening | If you pause or rub, the surface gets tougher |
| Vibration | The elastic nature of the metal can cause chatter |
| Heat buildup | Poor thermal conductivity = fast tool degradation |
| Deformation after HT | The part might warp post-machining and hardening |
So yes, you can machine spring steel—but you need to know what you’re dealing with and plan accordingly.
Spring Steel Machining Methods Compared
There’s no one-size-fits-all way to machine spring steel. I’ve worked on parts where CNC milling made sense, and others where we had no choice but to use EDM or go back to stamping. In this section, I’ll compare all the common methods I’ve either used myself or seen others use on the shop floor.
📊 Machining Methods Comparison Table
| Method | Machinability | Best For | Notes |
|---|---|---|---|
| CNC Milling/Turning | ⚠️ Medium | Complex geometries in soft state | Use only in annealed condition; hard on tools |
| Wire EDM | ✅ High | Hardened parts, tight tolerances | Best for detailed profiles, doesn’t generate stress |
| Laser Cutting | ✅ Medium | Thin sheet profiles, fast protos | Heat-affected zone (HAZ) may need post-processing |
| Waterjet Cutting | ✅ Medium | Heat-sensitive parts, prototyping | Cold cutting, no HAZ, slower than laser |
| Stamping | ✅ Very High | Flat parts, high-volume jobs | Requires tooling, not suitable for low-volume custom work |
| Grinding | ✅ High | Final tolerances, hardened steel | Essential for post-HT precision |
| Manual Machining | ❌ Low | One-off parts | Tool wear too high, generally not worth the effort |
🧰 1. CNC Milling and Turning
CNC is usually the first method that comes to mind for machinists. I’ve machined spring steel on a 3-axis mill and also on a CNC lathe, and here’s what I found:
- Only machine in annealed state. If you try to cut it post-heat-treatment, you’re asking for pain.
- Use carbide tools with proper coatings (TiAlN works well).
- Keep feeds conservative and don’t dwell. Dwelling causes work hardening.
- Spring steel can cause chatter due to its elasticity, so ensure rigid setups.
In my experience, machining 65Mn or 1075 in annealed form is manageable, but tool life is still a concern.
⚡ 2. Wire EDM
This is my favorite way to cut hardened spring steel.
- I’ve used EDM to cut hardened 1095 spring clips with micrometer-level accuracy.
- It doesn’t care if the steel is heat treated or not.
- No physical contact = no stress = no deformation.
- Downside? It’s slow and best suited to thin profiles and internal cutouts.
🔥 3. Laser Cutting
Laser cutting works well for thin sheets (<3mm) of spring steel. It’s fast, affordable, and widely available.
But:
- It creates a heat-affected zone (HAZ) that can harden the edges.
- Post-processing like grinding or annealing the edge might be needed.
- Can cause edge micro-cracking if not handled correctly.
If you’re prototyping spring clips or decorative parts, it’s often good enough.
💧 4. Waterjet Cutting
For thicker parts or when avoiding heat distortion, waterjet cutting is excellent. It doesn’t alter the steel’s properties and keeps the edges stress-free.
I once had a project with 6mm thick spring steel, and the laser shop refused the job. A waterjet cut it clean in under 20 minutes.
Drawbacks?
- Slower than laser.
- Kerf width is larger.
- Surface finish is rougher—might require secondary ops.
⚙️ 5. Stamping
If you’re making hundreds or thousands of spring parts, this is king. Stamping spring steel is fast, precise (with proper tooling), and extremely cost-effective.
- Tooling is expensive up front.
- Ideal for parts like clips, washers, shims, flat springs.
In mass production, I’ve seen stamping take part cost down by over 70% compared to CNC.
🧽 6. Grinding
When I want tight tolerances after heat treatment, grinding is essential. Especially for hardened spring steel with hardness above HRC 50, nothing else cuts clean.
- Surface grinding gives excellent flatness.
- Cylindrical grinding works for shafts or round parts.
- Tooling is expensive but pays off in high-precision environments.
❌ 7. Manual Machining
Just don’t.
Unless you’re making one part for testing and love sharpening drill bits, manual machining spring steel isn’t worth the time or tool wear.
Even with the best coolant and HSS tools, it’s an uphill battle. Trust me—I’ve tried. I ended up buying more inserts than I used.
🧩 Choosing the Right Method
Let me simplify it for you:
| Part Type | Recommended Method |
|---|---|
| Hardened, small profile | Wire EDM |
| Thin flat parts, large qty | Stamping |
| Thick flat parts, proto | Waterjet or Laser |
| Small batches, custom shape | CNC in annealed condition |
| Post-HT final dimensions | Grinding |
Recommended Tools and Speeds for Machining Spring Steel
When I first tried cutting spring steel, I underestimated just how tough it is on tools. Even in its annealed state, it behaves differently from mild or even tool steel. If you’re not using the right tooling, you’ll burn through inserts faster than you’d like.
So here’s everything I’ve learned—tested across CNC mills and lathes—with spring steel grades like 65Mn, 1075, and 1095.
🛠️ Best Tool Materials for Spring Stee
From experience, carbide is the baseline. HSS tools wear out too quickly, especially with spring steel’s abrasive nature and tendency to work harden.
Here’s a breakdown:
| Tool Material | Suitability | Notes |
|---|---|---|
| HSS | ❌ Poor | Wears out fast; causes heat buildup and hardening |
| Carbide (uncoated) | ⚠️ Medium | Better than HSS, but needs cooling |
| Coated Carbide | ✅ Great | TiAlN, AlTiN coatings help with heat and wear |
| CBN (Boron-based) | ✅ Excellent | Best for hardened spring steel, but very expensive |
| Ceramic Tools | ⚠️ Specialized | For high-speed dry cutting, not commonly used here |
My go-to setup on a Haas CNC uses TiAlN-coated carbide end mills for most jobs. For longer runs, I switch to micro-grain carbide to extend tool life.
⚙️ Recommended Cutting Parameters
Now, let’s talk numbers. Here are ballpark figures I’ve had success with:
| Grade | Condition | Tool Type | Speed (SFM) | Feed (IPT) | Depth of Cut (DOC) | Notes |
|---|---|---|---|---|---|---|
| 65Mn | Annealed | Carbide End Mill | 200–300 | 0.002–0.004 | 0.02–0.04 in | Use flood coolant; avoid dwell |
| 1075 | Annealed | Carbide Drill | 100–150 | 0.002–0.003 | 0.05 in per pass | Peck drilling helps chip evacuation |
| 1095 | Hardened | CBN Insert | 100–200 | 0.001–0.002 | Light passes | Use for finish turning only |
| SUS301 | Annealed | TiN-Coated Mill | 150–250 | 0.002–0.005 | 0.03 in | Watch for work hardening |
| 5160 | Annealed | Carbide Rougher | 250–400 | 0.005 | 0.05–0.08 in | Decent machinability in soft state |
⚠️ NOTE: Always adjust based on machine rigidity, part geometry, and coolant setup. The above numbers are starting points.
💧 Coolant & Lubrication Tips
Spring steel tends to build heat fast and has low thermal conductivity, so keeping things cool is critical.
Here’s what’s worked well for me:
- Flood coolant for most CNC jobs
- Mist systems when you’re working with less rigid setups
- Peck drilling to avoid heat accumulation in deep holes
- Avoid dry cutting unless you’re running high-end ceramics or CBN on hard steel
I once skipped coolant during a profile cut on annealed 65Mn just to save cleanup time. Ended up melting the insert coating and dulling the edge in one pass. Lesson learned.
🔄 Roughing vs Finishing
Always plan your toolpaths accordingly:
- Roughing: Use high-feed, low-speed with tougher inserts
- Finishing: Lighter DOC and lower feed to maintain surface integrity
If you don’t finish cleanly, spring steel will bite back—you’ll see burrs, microcracks, and surface tension zones that may ruin your tolerances after heat treatment.
🧠 Personal Lessons Learned
- Spring steel isn’t impossible, but it punishes sloppy setups.
- I’ve had the best luck with rigid fixturing and shorter tools.
- When in doubt, go conservative on speeds and let the tool last longer.
- Don’t forget to stress-relieve parts before final finishing if tight tolerances matter.
Heat Treatment Considerations
If you’re working with spring steel, you’re going to deal with heat treatment at some point—there’s no getting around it. The properties we love spring steel for (its springiness, strength, and fatigue resistance) come from how it’s treated, not just what it’s made of.
But the big question is: Should I machine spring steel before or after heat treatment?
Here’s what I’ve found after doing it both ways—sometimes the right way, sometimes the hard way.
🔥 Why Heat Treatment Matters in Spring Steel
Spring steel gets its elasticity and strength from a combination of:
- Quenching – rapidly cooling the steel to trap the hard martensitic structure
- Tempering – reheating to a lower temperature to balance toughness and hardness
Here’s a breakdown of how heat treatment changes the material:
| Condition | Hardness (HRC) | Machinability | Usage |
|---|---|---|---|
| Annealed | ~20–30 HRC | ✅ Easy to machine | Pre-machining state |
| Quenched (as-hardened) | ~55–65 HRC | ❌ Very difficult | High-strength, but brittle |
| Tempered | ~45–55 HRC | ⚠️ Very limited | Final use condition for springs |
So if you’re cutting hardened spring steel and don’t have CBN or EDM, you’re in for a rough time.
📌 My Machining Strategy (Real-World Practice)
In 90% of cases, I machine spring steel in the annealed state first.
Here’s the general process I follow:
- Rough machine in soft state.
- Leave 0.1–0.2 mm allowance for finishing.
- Send for heat treatment (quench and temper).
- Finish grind or EDM cut critical surfaces.
If I try to skip step 4 and go straight to final machining after heat treatment, I usually regret it. The surface becomes hard, prone to cracking, and nearly impossible to finish cleanly with traditional tools.
🧪 Heat Treatment Process (Typical Flow)
| Step | Temperature Range | Duration | Notes |
|---|---|---|---|
| Annealing | 700–750°C | 1–3 hrs | Softens material, stress relief |
| Quenching | 830–880°C | Oil/water quench | Induces hardness, creates martensite |
| Tempering | 400–550°C | 1–2 hrs | Adjusts toughness/hardness balance |
I usually request a two-stage tempering cycle from our heat treat vendor for parts under stress, especially for components like spring clips or clamps. It helps with dimensional stability.
⚠️ Things to Watch Out For
- Warping after heat treat – I’ve had flat parts turn into potato chips after quenching. Use symmetric designs and leave stock for post-HT grinding.
- Decarburization – Heat treatment can reduce surface hardness. Always remove 0.1 mm from the surface after HT if precision matters.
- Internal stress – Especially on laser- or stamped parts. Always stress relieve before final grinding.
💡 Practical Tip:
If you’re sourcing spring steel that’s already hardened (some vendors sell it pre-hardened), plan to avoid machining entirely. Either:
- Use EDM or grinding
- Or redesign the part to be made from annealed stock and heat-treated later
🧩 Summary
Heat treatment is essential to unlock the true mechanical properties of spring steel, but it also limits your machining options. My advice is: machine soft, finish hard. That balance has saved me time, tooling, and scrap more times than I can count.
Surface Finishing Options for Spring Steel
Once the machining is done and the part has gone through heat treatment, your job isn’t finished. Spring steel parts usually operate under high stress and repetitive motion, so surface finish isn’t just about appearance—it directly affects performance and fatigue life.
Over the years, I’ve tested several surface treatments on spring steel parts. Some made a huge difference. Others… just added cost without real benefit.
Let’s break down what works, and when to use it.
🧽 Deburring & Edge Treatment
Spring steel is notorious for producing tough burrs during machining, especially in drilling and profiling operations. Left untreated, these burrs can lead to:
- Stress risers
- Premature cracking
- Assembly issues
Here’s how I handle deburring depending on the part and its function:
| Deburring Method | Use Case | Notes |
|---|---|---|
| Manual deburring (hand tools) | Low-volume, large edges | Simple but labor-intensive |
| Tumbling / Vibratory | Small spring clips, batch parts | Efficient for high-volume small parts |
| Electrochemical deburring | Complex geometries | Expensive, but best for internal burrs |
| Laser deburring | Sheet metal parts post-cutting | Leaves minimal edge deformation |
| Chamfering in CNC code | Large, visible edges | Do it during machining if possible |
Pro tip: Always deburr before heat treatment. The material is softer and easier to work with—and it avoids stress risers from being baked into the part.
🔩 Polishing & Grinding
Spring steel parts—especially those in high-cycle fatigue environments—benefit from surface refinement after machining.
I usually use one of the following depending on the required finish:
| Method | Surface Roughness (Ra) | Best For |
|---|---|---|
| Surface grinding | 0.2–0.8 µm | Hardened parts, tight flatness |
| Lapping | 0.05–0.2 µm | Precision spring contacts |
| Belt polishing | 0.8–1.6 µm | Decorative or wear-resistant parts |
| Shot blasting | ~3–6 µm | Surface strengthening |
On some aerospace parts I worked on, we polished the edges of spring steel to a mirror finish. It reduced micro-cracks and extended fatigue life dramatically.
🛡️ Surface Treatments and Coatings
Some people think of coatings as cosmetic. But with spring steel, surface protection can be critical—especially for parts exposed to corrosion, friction, or impact.
Here are common treatments I’ve applied or seen applied on various parts:
| Coating/Treatment | Purpose | Notes |
|---|---|---|
| Black oxide | Anti-corrosion, low cost | Minimal dimensional change, widely used |
| Zinc plating | Stronger corrosion resistance | Slight dimensional growth, can reduce fatigue |
| Phosphate coating | Lubricity and corrosion resistance | Often used before assembly |
| PVD (TiN, TiAlN) | Wear and heat resistance | Great for tooling parts, expensive |
| Shot peening | Improve fatigue resistance | Induces compressive stress to reduce cracking |
| Passivation | For stainless spring steel (e.g., SUS301) | Improves corrosion resistance without coating |
If you’re dealing with electronic contacts or small mechanical linkages, go for phosphate or black oxide. If you’re working in an outdoor or corrosive environment, zinc plating is usually worth the extra step.
⚠️ Watch Out For…
- Coating buildup can throw off tight tolerances. I once had a zinc-coated flat spring that wouldn’t fit its slot after finishing—0.02 mm too thick, and it cost us hours of rework.
- Some coatings, like phosphate, can absorb oil or moisture. Factor that into your assembly or storage plan.
- Always confirm post-treatment hardness if you’re doing heat + surface treatment. Some treatments involve elevated temps that could reduce spring tension if not done properly.
🧩 Summar
Surface finishing for spring steel isn’t optional—it’s part of the performance equation. Whether you’re reducing friction, fighting fatigue, or just avoiding rust, the right finishing method ensures your parts live up to their name: flexible, strong, and dependable.
Supplier & Material Selection Tips
I’ve learned the hard way that bad spring steel stock ruins good machining—and sometimes even your reputation. Once, I received a batch of so-called “65Mn” that behaved more like soft mild steel. Turned out it was mislabeled. The parts looked fine until they failed in a vibration test.
So if you’re working with spring steel, choosing the right supplier and verifying the material isn’t just smart—it’s essential.
📦 Sourcing Spring Steel: What to Look For
Start by knowing what you actually need. There are dozens of spring steel grades, but most projects only require a few:
| Application Type | Recommended Grade | Notes |
|---|---|---|
| General-purpose springs | 65Mn, 1075 | Widely available, easy to machine in annealed state |
| High-strength components | 1095, 5160 | Good for wear and stress, but harder to machine |
| Corrosion resistance | SUS301, SUS304 | Best for outdoor or humid environments |
| Automotive applications | EN45, 50CrV4 | Excellent shock absorption and fatigue strength |
Once you’ve settled on the grade, call suppliers directly. Don’t just trust the listing on a website. I always ask for:
- Heat treatment condition (annealed, hardened, tempered?)
- Material certification (mill test report, or MTR)
- Origin of steel (domestic vs. imported)
- Surface condition (scaleless, oiled, pickled?)
🧾 Certifications You Should Ask For
A reputable supplier should be able to provide an MTC (Mill Test Certificate) or similar, detailing:
| Certificate Field | Why It Matters |
|---|---|
| Material Grade | Confirms alloy content |
| Hardness / HRC | Validates machinability or final usage |
| Yield/Tensile Strength | Essential for mechanical performance |
| Heat Treatment State | Tells you whether to machine or grind |
| Standards Compliance | ASTM, GB, JIS, etc. |
I’ve worked with steel that had no certs, and even when it machined fine, I couldn’t use the parts in certified assemblies. Don’t skip this.
🛒 Recommended Sources (From Experience)
While availability varies by region, I’ve sourced good quality spring steel from:
- Thyssenkrupp – Reliable European grades, fully certified
- BaoSteel (China) – Especially good for 65Mn and 60Si2Mn
- McMaster-Carr – Great for small batches and prototyping in the U.S.
- Penn Stainless / Ulbrich – For stainless spring steels like SUS301/302
- Online Metals / Alro Steel – Small quantities, wide selection
If you’re buying in bulk or for long-term production, build a direct relationship with the mill or service center. You’ll get better pricing, faster answers, and fewer surprises.
❗ Watch Out For:
- Inconsistent flatness or thickness in hot-rolled stock.
- Imported spring steel without certificates—could be mislabeled or improperly treated.
- Too much surface scale can ruin small features in CNC parts.
- Fake “spring steel” sold on some marketplaces—usually mild steel with no real spring properties.
📋 Material Selection Checklist
| ✅ Checkpoint | Why It Matters |
|---|---|
| Correct grade | Mechanical properties |
| Condition (annealed or hardened) | Affects machinability |
| MTC / Certification | Quality assurance |
| Surface condition | Impacts finish and handling |
| Origin / Manufacturer | Traceability and long-term quality |
🧩 Summary
If there’s one lesson I’d pass on here, it’s this: never treat spring steel like commodity steel.
Take the time to verify the specs, ask for certs, and understand the material state before you even cut your first chip. Good material makes everything downstream easier—bad material just multiplies problems.
Design for Machinability Tips
Even the best tooling, machine, and operator won’t save you from a part that’s poorly designed for spring steel. I’ve been there—machining ultra-thin spring arms with tight corners, only to watch them warp like potato chips after heat treatment.
So in this section, I’m sharing the rules I’ve developed to make spring steel parts that are actually machinable and stay in spec.
🧠 Design Principles That Make Spring Steel Easier to Machine
| Design Tip | Why It Helps |
|---|---|
| Avoid sharp internal corners | Reduces stress risers and tool breakage |
| Use generous radii on edges | Prevents cracking during forming or hardening |
| Keep wall thickness consistent | Helps minimize distortion post heat treatment |
| Avoid deep thin slots | Hard to machine and tend to warp under stress |
| Design for fixturing | Add tabs, holes, or flat edges to help during CNC or EDM operations |
| Plan stock allowance for finishing | Especially important for grinding after heat treatment |
| Limit overly small features pre-HT | They might get damaged or deformed during quenching |
When I design a spring steel part, I try to think two steps ahead—how am I going to fixture this? How will it behave after heat treat?
🖊️ Spring Steel CAD Design Dos & Don’ts
| ✅ Do This | ❌ Avoid This |
|---|---|
| Use slots over blind holes | Thin blind holes often deform in HT |
| Maintain symmetry when possible | Prevents uneven stress during quenching |
| Add relief cuts to reduce stress | Sharp corners trap heat and crack |
| Chamfer or round exposed edges | Improves fatigue resistance |
| Add machining tabs if EDM is used | Makes it easier to hold tiny features |
🔄 Tolerancing for Post-Machining Stability
Machining spring steel before heat treatment means you have to account for distortion. Even small parts can move significantly if they aren’t stress relieved.
Here’s what’s worked for me:
- Leave 0.1–0.2 mm for grinding on critical surfaces
- Use symmetric profiles to even out heat absorption
- Pre-bend or pre-crown parts if you know how they’ll move
For example, in one part I made—a small flat spring plate—I had to design it 0.15 mm concave, because I knew heat treatment would cause it to dome upward. Got it right on the second try.
🧰 EDM-Friendly Design Tips
If you plan to use wire EDM on spring steel (especially hardened stock), a few smart design tweaks will save hours:
- Add a start hole for the EDM wire
- Keep edges clean and open for flushing
- Design tabs for part removal or repositioning
- Make internal features large enough for the wire to enter (min ~0.2 mm gap)
I’ve done jobs where we couldn’t start the EDM cut because the customer’s drawing had no entry feature. We ended up drilling and re-fixturing everything. Not ideal.
🔧 Fixturing Considerations
You can design even the best part, but if you can’t hold it securely, it won’t machine well.
What I do:
- Design flat surfaces for clamping
- Add temporary “fixture tabs” to the part that can be ground off later
- For thin parts, I’ll use sacrificial backplates or adhesive setups to minimize vibration
🧩 Summary
Designing for machinability isn’t just about saving time in CAM or CNC—it’s about anticipating how spring steel behaves under stress. Keep geometry simple, allow for movement, and always design with post-processes in mind.
You’ll avoid warping, tooling issues, and rejected parts—and your machinist will probably thank you too.
Industry Use Cases
Over the years, I’ve worked on dozens of parts made from spring steel, across a wide range of industries. It’s one of those materials that shows up everywhere once you know what to look for—from the suspension system in your carto the metal clip inside your laptop.
Let me walk you through some real-world examples of how spring steel is used across different sectors, the challenges involved, and what I learned from making parts for each.
🚗 Automotive Industry
Spring steel is everywhere in cars, especially in:
- Leaf springs
- Suspension arms
- Retaining clips
- Clutch springs
- Brake hardware
Material: 5160, 65Mn, EN45
Why spring steel? High strength, fatigue resistance, and shock absorption.
I once worked on a batch of retaining clips for a truck’s drum brake system. The spec called for 65Mn, quenched and tempered. The hard part wasn’t cutting it—it was keeping the shape after heat treatment. We ended up redesigning the part slightly for better symmetry, and it reduced scrap by over 40%.
Key considerations:
- Parts must withstand constant vibration and pressure
- Surface treatments (like phosphate coating) are usually required for corrosion protection
- Tolerances can be tight, especially for fit into assemblies
💻 Electronics & Consumer Devices
In phones, laptops, and wearables, spring steel is used in:
- Battery contacts
- Button domes
- Ejector pins (like SIM card trays)
- Small latching or locking springs
Material: SUS301, SUS304 (for corrosion resistance and formability)
Typical thickness: 0.1–0.5 mm
I’ve done projects where we had to EDM-cut tiny spring arms from SUS301 sheets. The tolerances were brutal—±0.01 mm—and any burr could cause electrical interference. We polished those parts under a microscope.
Challenges:
- Ultra-thin materials require extremely stable fixturing
- EDM and laser cutting are preferred over mechanical machining
- Burrs must be eliminated completely
✈️ Aerospace & Defense
Aerospace loves spring steel for:
- Fastener locks
- Retaining rings
- Jet engine seals
- Precision springs in instruments
Material: Custom alloys, 1095, or even titanium spring metals
These are high-performance parts. I once saw a batch of spring retainers for an aircraft canopy system—machined from 1095, then EDM’d and shot-peened. They had to survive extreme G-forces and temperature shifts.
Key considerations:
- Fatigue life and surface finish are critical
- Every part gets serialized and traceable back to the material batch
- Usually paired with surface treatments like shot peening or PVD
🩺 Medical Devices
In surgical tools and implants, spring steel is used for:
- Tension clips
- Surgical scissors and blades
- Implant retention mechanisms
Material: 17-7PH, 420SS, sometimes heat-treated 316
Medical parts are often made in small batches, and I’ve machined tools that had zero room for surface defects. We used passivation and ultrasonic cleaning after finishing to remove any contaminants.
Challenges:
- Absolute cleanliness
- Dimensional repeatability for interchangeable tools
- Strict material documentation and compliance (ISO 13485, FDA)
🛠️ Tooling and Industrial Applications
Spring steel plays a role in:
- Snap-fit tooling
- Die springs
- Custom clamps and fixtures
- Measuring tools (like tape measures)
Material: 1075, 1095, 65Mn
Common processes: CNC + HT + grind
In my shop, we’ve made custom die return springs that cycle millions of times. Here, it’s all about balancing strength and cost—getting the right heat treatment makes or breaks the part’s life cycle.
📊 Spring Steel Industry Application Summary
| Industry | Common Parts | Materials Used | Processing Notes |
|---|---|---|---|
| Automotive | Leaf springs, clips, brakes | 65Mn, 5160, EN45 | Needs good corrosion resistance + fatigue testing |
| Electronics | Contacts, ejectors, hinges | SUS301, SUS304 | Burr-free finish, ultra-thin stock |
| Aerospace | Retainers, seals, locking devices | 1095, custom alloys | High traceability and fatigue strength required |
| Medical | Clips, blades, tools | 420SS, 17-7PH | Clean room processing and passivation required |
| Tooling | Dies, clamps, measuring tools | 1075, 65Mn | Often requires grinding post heat treatment |
🧩 Summary
Spring steel’s use cases span industries because of one simple trait: it returns to shape under stress.
Whether it’s holding a SIM card in place or suspending a 3-ton truck, the same principles apply—and so do the same machining, material, and finishing challenges.
The more I’ve worked with spring steel, the more I’ve appreciated how versatile—and demanding—it can be.
FAQ
Can You Machine Spring Steel? A Complete Guide for Engineers and Machinists
Over the years, I’ve been asked dozens of questions about machining spring steel—by engineers, by machinists, by purchasing teams. So here’s a no-fluff FAQ that gets to the point, based on real situations I’ve faced (and sometimes messed up).
1. Can spring steel be CNC machined?
Yes—but only reliably in its annealed (soft) state. Hardened spring steel is best handled using EDM or grinding.
2. What’s the best tool for machining spring steel?
TiAlN-coated carbide tools work best for CNC. For hardened parts, consider CBN inserts or go straight to wire EDM.
3. Should I heat treat spring steel before or after machining?
Machine first, heat treat later. Then perform final finishing (grinding or EDM) to meet tight tolerances.
4. Is 65Mn a good choice for spring applications?
Yes. It’s widely used, affordable, and performs well under fatigue. It’s also one of the more machinable spring steels in annealed form.
5. Can I drill and tap holes in spring steel?
Yes, but do it in the annealed state. Use coated carbide drills and taps, and keep pecking cycles short to avoid heat buildup.
6. What’s the main machining challenge with spring steel?
It work-hardens quickly, wears tools fast, and distorts easily during and after heat treatment.
7. What’s the ideal surface finish for spring steel parts?
For functional parts: Ra 0.4–0.8 µm. For high-stress components, go finer—polishing and shot peening can improve fatigue life.
8. Can laser cutting be used on spring steel?
Yes—for thin sheets (<3mm). Be mindful of the heat-affected zone (HAZ), which can harden the edges.
9. What’s the difference between 1075 and 1095 spring steel?
1095 has higher carbon content → harder, stronger, less ductile. Better for wear parts; 1075 is easier to form and machine.
10. How do I prevent tool wear when machining spring steel?
Use:
- High-quality carbide
- Proper feeds/speeds
- Flood coolant
And avoid rubbing or dwelling—those will kill your tools.
11. What happens if I machine spring steel after it’s hardened?
Expect tool breakage, chatter, and poor finish. Unless you’re using EDM or grinding, it’s not worth the trouble.
12. What kind of spring steel is corrosion-resistant?
Use stainless spring steels like SUS301, SUS304, or 17-7PH. You can also apply zinc plating or black oxide for protection.
13. Can I use waterjet cutting for spring steel?
Yes—especially for thicker parts or when heat from lasers would be an issue. It’s slower but avoids heat distortion.
14. What tolerances should I expect post-heat treatment?
Plan for 0.1–0.2 mm of distortion. Leave finishing stock and grind or EDM afterward.
15. Can I use spring steel for 3D-printed hybrid parts?
Not directly. But spring steel can be combined with printed parts for clips, inserts, or flexible elements.
16. What’s the best way to deburr spring steel?
For small parts: tumbling or vibratory finishing. For tight-feature components: manual or laser deburring.
17. Should I passivate or coat spring steel?
For stainless grades, passivation is ideal. For carbon grades, go with black oxide, phosphate, or zinc depending on the environment.
Further Reading & Authoritative References
- Overview of Factors Contributing to Steel Spring Performance and Failure
This comprehensive study delves into the chemistry, heat treatment, residual stress, and fatigue failure of leaf and coil springs, offering insights into the complexities of spring steel performance.
📄 ResearchGate - Tailoring the Microstructure Using Quenching and Partitioning Processing in a Commercial Mn-Si-Cr Spring Steel
This research explores advanced heat treatment techniques to enhance the tensile properties of AISI 9260 spring steel, focusing on microstructural optimization.
📄 ResearchGate - Simulations and Experiments in Punching Spring-Steel Devices
This paper presents finite element simulations and experimental results on the blanking cycle of spring steel sheets, providing valuable data on cutting processes.
📄 ScienceDirect - Engineering ToolBox – Material Properties
A reliable resource offering detailed technical data and calculations for various materials, including spring steel, aiding engineers and designers in their applications.
🌐 Engineering ToolBox - Compression Spring – An Overview
This topic provides an overview of compression springs, discussing their design, applications, and the role of spring steel in their functionality.
📄 ScienceDirect Topics - Laser-Assisted Shearing of Spring Steel: Reduction of Cutting Forces
An insightful study on how laser-assisted shearing can reduce cutting forces in spring steel, enhancing the efficiency of manufacturing processes.
📄 ResearchGate
