Internal Keyway Archives - Gisstec Broaching Tools

Live Broaching Units are In: Why Aerospace, Aviation, Gear-Making and Automative Industries are Switching

Posted on 02/01/2025 by gisstec

In industries as diverse as aerospace, aviation, machinery, automative and gear-making, the quest for high precision and efficiency never stops. From jet engine components to gear assemblies, manufacturing processes are evolving to decrease cycle times, increase automation all the while keeping to the strict quality standards.

One such development is the live broaching unit—a compact driven tool that can transform a standard lathe with a C-axis into a versatile keyway-broaching powerhouse.

If your operation regularly needs precise internal keyways or spline profiles, this broaching technology could be a pivotal addition to your manufacturing lineup.

Below, we explore how a live broaching unit stacks up against traditional broaching machines and why it’s increasingly becoming the method of choice in demanding manufacturing environments.

Quick Refresher: What Is Keyway Broaching?

Let’s start with the fundamentals. “Broaching” is a material-removal process most commonly associated with cutting keyways. A keyway is a slot, typically inside a gear or rotor, designed to accommodate a “key” that locks onto a shaft. This prevents slippage and provides the robust connection needed for transferring torque — crucial in applications like aircraft engines, power turbines, and industrial gearboxes.

The classic approach to cutting these slots involves a long, multi-tooth keyway broach. During a single pass, each successive tooth removes material until the keyway is fully formed.

Dedicated broaching machines have long been the standard for this operation—especially in high-volume manufacturing. However, they come with specific drawbacks that have spurred many organizations to seek more flexible solutions.

Some companies without a dedicated linear broaching machine or a live broaching tool use broaching services from contract manufacturers which offer tailored solutions to meet specific client needs.

Broaching Machines and Processes

Broaching machines are specialized machine tools designed to perform the cutting process, which involves broaching precise shapes or profiles into workpieces. There are several types of broaching machines, each tailored to specific applications and varying in their mechanism of operation. The most common types include vertical and horizontal broaching machines.

Vertical broaching machines are ideal for applications requiring high precision and are often used for internal broaching tasks. On the other hand, horizontal broaching machines are designed for surface broaching and are typically used for larger workpieces that require extensive material removal.

By understanding the specific advantages and applications of each type of broaching machine, manufacturers can select the most suitable equipment for their needs, ensuring optimal efficiency and precision in their machining processes.

The Traditional Path: Dedicated Vertical Broaching Machines

Single-Purpose Operation

Conventional broaching machines are engineered with one function in mind: broaching. If your line is running large batches of identical parts a dedicated machine may still be a worthwhile choice.

But in modern manufacturing, variety is the new norm. When your product mix changes frequently or you need to produce parts of varying sizes and shapes, moving back and forth between a lathe (for turning, boring, or milling) and a separate broaching machine can become time-consuming. Each part has to be re-fixtured and realigned, introducing more opportunities for dimensional inaccuracies.

High Cost and Maintenance

Industrial broaching equipment is not just large in physical scale; it often comes with a hefty price tag and ongoing maintenance requirements.

In broaching operations, both pull and push methods are employed, each suited to specific applications.

Pull Broaching

Pull broaching, where the broach is drawn through the workpiece, is generally more prevalent, especially for internal broaching tasks. This method allows for longer broaches and is capable of handling more substantial cuts with higher precision.

Pull broaching is commonly utilized in horizontal broaching machines, which are often used for internal broaching of small to medium-sized and heavy workpieces.

Push Broaching

Push broaching involves pushing the broach through or over the workpiece. This technique is typically applied to shorter workpieces or those requiring less material removal, as push broaches are subjected to compressive loads and are made shorter in length to avoid buckling.

Push broaching is commonly used on broaching presses and is suitable for sizing holes and cutting keyways.

Specialized repairs, large-scale hydraulic or mechanical components, and the constant wear on multi-tooth broaches all factor into the total cost of ownership. And multi-tooth broaches are notoriously unforgiving—if a single tooth breaks or chips, the entire broach may need replacing.

Limited to Through Holes

An important limitation for many broaching machines is that they can typically only broach through holes. In aerospace and aviation applications especially, blind holes are often part of complex component designs.

Traditional machines that rely on pulling or pushing a broach through the entire workpiece generally aren’t equipped to handle those partial-depth requirements.

The New Approach: Live Broaching Units on a Lathe

Compact and Flexible

A live broaching unit is a specialized driven tool for linear broaching that mounts directly onto a CNC lathe’s turret or tool post. It’s compact, easy to mount, and doesn’t require the additional floor space of a standalone broaching machine.

This is particularly relevant in high-volume manufacturing lines where every square foot of space counts—or in advanced facilities where multiple processes must be consolidated to shorten production times.

Internal spline broaching gear cutting — Internal spline profile broached with a Gisstec Live Broaching Head on a lathe

Seamless Workflow

One of the most compelling advantages is the ability to perform everything—turning, boring, drilling, and broaching—on the same machine.

This means fewer setups, reduced part handling, and minimal risk of misalignment. Whether you’re machining precision engine components for aircraft or specialized gears for heavy equipment, having all your operations in one place can significantly streamline production.

Cost-Effective Insert-Based Broaching Tools

Where traditional machines rely on large, multi-tooth broaches, live broaching units generally use single-tooth or indexable inserts.

These inserts are economical, can be swapped out easily when worn or chipped, and allow for quick adaptation to different keyway sizes or shapes. Broach tools are versatile and have specific applications in machining processes, making them essential for achieving accurate finishes and efficient material removal across various materials like alloy steel, cast iron, aluminum, bronze.

If you’re producing diverse runs—like different gear diameters or varied aerospace components—this approach can be a major money-saver. The days of scrapping an entire multi-tooth broach because one tooth is damaged are over.

Blind Hole Capability

Unlike most dedicated broaching setups, a live broaching unit can cut keyways into blind holes. All you need is a small relief groove to allow chip evacuation at the profile’s end, and you’re set.

This opens the door for more intricate part designs common in turbines, pump systems, and rotor assemblies, where partial-depth keyways are often critical for performance.

Simplifying Complex Designs

Engineers have historically been forced to design around the constraints of through-hole machining, sometimes resulting in overly complex or hard-to-manufacture parts.

Now, with advancements such as live broaching units and improved tooling technology, designs can be approached more freely, allowing blind holes and partial length keyways and involute spline profiles to be incorporated without compromising manufacturability.

This flexibility not only simplifies the production process but also opens the door for innovative component designs that were previously impractical.

Advantages Across Industries

Faster Turnaround with Reduced Handling

Every time a part is transferred from one machine to another, there’s a chance for error or damage. In aerospace or aviation manufacturing, where tolerances can be extremely tight, minimizing re-fixturing is essential. Live broaching keeps the workpiece in the lathe chuck, ensuring consistent alignment and rapid part processing.

Lower Overall Investment

Dedicated broaching machines can command a significant upfront investment, not to mention the operating and maintenance costs.

A live broaching unit, on the other hand, is typically far less expensive and makes use of your existing equipment and infrastructure.

This more flexible setup can be appealing if you’re balancing the purchase of other specialized machinery—like 5-axis CNC mills or advanced inspection systems—needed for cutting-edge aviation or aerospace projects.

Scalable for Large or Small Batches

Some industries—such as gear-making for large-scale construction equipment—might deal with extensive production runs. Others, like custom aerospace component manufacturers, may see smaller, highly specialized batches.

Live broaching units adapt easily to both situations. When you’re producing keyways across various part sizes, simply swap out the inserts as needed. This adaptability keeps machine downtime to a minimum, allowing you to respond quickly to changing production orders.

Integrated Programming and Automation

Modern CNC lathes often come with sophisticated software that can handle complex tool paths, and integrating a broaching operation is typically a straightforward add-on.

The manufacturing process can be automated using the same G-code routines you employ for turning and milling, simplifying training and reducing the risk of human error.

In sectors where process validation and repeatability are paramount—like aerospace—this level of control can significantly improve quality assurance.

Improved Floor Space Utilization

Whether you’re building jet engines or heavy industrial gearboxes, the manufacturing floor is always at a premium. By attaching a broaching unit to your lathe, you avoid having to carve out space for a standalone broaching system.

That’s good news for sprawling factory setups where multiple production lines operate simultaneously, as well as for more constrained facilities that are constantly juggling machine placement.

How About Rotary Braoching?

Rotary broaching is a unique machining process designed to efficiently create precise internal and external profiles by simultaneously rotating both the cutting tool and the workpiece.

This technique is widely used in applications requiring polygonal shapes such as hexagon holes, square holes, or splines, often found in fasteners, gears, and other mechanical components.

How Does Rotary Broaching Work?

In rotary broaching, the cutting tool is mounted at a slight angle (typically 1°) relative to the workpiece axis. As the tool and workpiece rotate, the angled broach applies pressure to cut the desired profile.

The key to this process is the synchronized rotation of the tool and workpiece, which reduces cutting resistance and enables the broach to carve out the profile with precision and minimal stress.

Key Benefits of Rotary Broaching

Efficiency: It completes the profile in a single pass, significantly reducing cycle times compared to multi-step broaching processes.
Versatility: The process can be applied to a wide range of materials, including steel, aluminum, and titanium, making it suitable for industries such as aerospace, automotive, and medical devices.
Compact Setup: Internal broaching and external broaching can be performed on standard CNC lathes, turning machines, machining centers or mills with the appropriate tool holders.

Limitations of Rotary Broaching

While rotary broaching offers numerous advantages, it is not without its limitations:

High Cutting Forces: The process requires substantial cutting forces, limiting the size and depth of the profiles that can be created. Very deep or large profiles may exceed the capacity of rotary broaching tools. That’s where live broaching tools come in.
Material Hardness: Extremely hard materials may pose challenges for rotary broaching, as the required cutting forces increase significantly.
Complex Profiles: While excellent for simple polygonal shapes, rotary broaching is not ideal for creating highly intricate or non-uniform profiles.

Applications of Rotary Broaching

Rotary broaching is a go-to process for a variety of industries and applications :

Fasteners: Manufacturing hexagonal, square or torx sockets for bolts, screws, and other fasteners.
Gears and Splines: Producing internal splines or other profiles used in power transmission components.
Medical Devices: Machining precise internal features in surgical instruments and implants.

Important Considerations Before Making the Switch

Lathe Requirements

Not all lathes are created equal. Your lathe needs to be rigid enough and have sufficient horsepower to handle the forces generated during broaching—especially for larger or tougher materials frequently used in aerospace (think titanium or high-strength steel).

Always consult the manufacturer’s recommended guidelines for spindle power, tool pressure, and cutting speeds.

Live Broaching Tool Gisstec Slotting Keyway Cutting — Gisstec Live Broaching Unit

Monitoring Tool Wear

Broaching, like any machining operation, puts stress on cutting edges. If you’re working with exotic aerospace alloys or hardened gear steels, tool wear can accelerate. Regular inspection and routine insert changes will help maintain quality.

Adhering to recommended speeds, feeds, and lubrication protocols also prolongs tool life.

Safety and Training

Proper training is non-negotiable. While attaching and using a live broaching unit isn’t overly complex, it does require a solid understanding of both lathe operations and broaching fundamentals.

Employees should be aware of clearance settings, proper clamping procedures, and safety measures like protective eyewear and guarding.

Conclusion

From aerospace engine shafts to massive gears in heavy machinery, keyways are integral to ensuring reliable power transmission. While traditional broaching machines have served this purpose for decades, the rise of live broaching units is reshaping how companies approach the task.

They’re flexible, cost-effective, and efficient, making it easier than ever to integrate keyway broaching right on the production floor—no additional machine required.

If your organization is grappling with tight deadlines, space constraints, or a diverse product mix, consider a live broaching unit. You’ll save on tooling, speed up production, and open the door to new design possibilities such as blind hole keyways.

Dedicated broaching machines may still hold their ground in certain high-volume or specialized scenarios. But for many operations across aerospace, aviation, machinery, and gear-making, the adaptability and efficiency of live broaching can be a game-changer.

In the high-stakes world of advanced manufacturing—where efficiency, precision, and innovation converge—every competitive edge counts.

By integrating a live broaching unit into your lathe-driven workflow, you can expand your capabilities, reduce overhead, and maintain the high quality your clients demand.

Whether you’re building the next generation of jet engines or large industrial gear trains, live broaching could be the key to elevating your production processes to new heights.

FAQ

1. What is a live broaching unit?

A live broaching unit is a compact, driven tool that attaches to a lathe, transforming it into a keyway-broaching powerhouse. This attachment enables efficient cutting of keyways, involute spline profiles, and other intricate shapes directly on the lathe, eliminating the need for separate broaching machines.

2. How does a live broaching unit work?

Live broaching units use single-tooth or indexable inserts mounted on a lathe’s turret or tool post. The unit applies precise cutting forces to create keyways or splines while the workpiece is held in place. This process reduces setup time and ensures consistent results in a single machine setup.

3. What are the advantages of live broaching units compared to traditional broaching machines?

Space-saving: Live broaching units eliminate the need for a separate broaching machine.
Cost-effective tooling: They use replaceable inserts, reducing the cost of tooling compared to multi-tooth broaches.
Flexibility: They allow for blind hole broaching, enabling complex designs.
Time efficiency: Operations like turning, boring, and broaching can be performed in one setup, reducing handling and cycle times.

4. Can live broaching units handle blind holes?

Yes, live broaching units can cut keyways into blind holes. By incorporating a small relief groove at the bottom of the hole, chip evacuation is made possible, overcoming the limitations of traditional broaching machines that can only handle through holes.

5. What types of broaching processes are commonly used?

Pull Broaching: The broach is pulled through the workpiece, ideal for internal broaching with high precision.
Push Broaching: The broach is pushed through or over the workpiece, suitable for smaller cuts and shallow profiles.
Rotary Broaching: The tool and workpiece rotate simultaneously, perfect for creating polygonal shapes like hexagons and squares in one pass.

6. What are the limitations of traditional broaching machines?

They are generally limited to through holes.
High equipment costs and maintenance needs.
Limited flexibility for low-volume or highly varied production runs.
Multi-tooth broaches are expensive and can become unusable if a single tooth is damaged.

7. What are the key benefits of rotary broaching?

Rotary broaching is highly efficient for creating profiles such as hexagons and squares. It completes the profile in a single pass and is versatile enough for a wide range of materials, including steel, aluminum, and titanium. However, it requires substantial cutting forces and is less suitable for large or intricate profiles.

8. How do live broaching units impact manufacturing flexibility?

Live broaching units allow engineers to design freely without being constrained by the limitations of through-hole broaching. Features like blind holes and partial-depth keyways can now be incorporated without compromising manufacturability, enabling more innovative and cost-effective designs.

9. What industries benefit most from live broaching units?

Industries such as aerospace, aviation, machinery, gear-making, and medical device manufacturing benefit from live broaching units due to their ability to handle precision components efficiently while maintaining high quality.

10. What factors should be considered before using a live broaching unit?

Lathe capability: Ensure your lathe is rigid enough and has sufficient power for broaching.
Tool wear: Regularly inspect and replace inserts to maintain quality.
Training: Operators must understand the process and safety measures for successful implementation.

11. Why are live broaching units more cost-effective?

Live broaching units use affordable, replaceable inserts instead of expensive multi-tooth broaches. This reduces tooling costs significantly, especially for varied production runs or applications requiring frequent insert changes.

12. What are the best applications for live broaching units?

Live broaching units are ideal for:

Keyways in blind and through holes.
Internal spline profiles for gear systems.
Aerospace and automotive components requiring tight tolerances and complex features.

13. Can rotary broaching be performed on a standard CNC lathe?

Yes, rotary broaching can be performed on standard CNC lathes or mills equipped with the appropriate tool holders, making it a versatile option for creating polygonal shapes in fasteners, gears, and other components.

14. How do live broaching units improve production efficiency?

By combining turning, boring, and broaching in a single machine setup, live broaching units reduce part handling, minimize re-fixturing, and speed up production cycles while maintaining precision.

15. How do live broaching units simplify complex designs?

Engineers no longer need to design around through-hole constraints. Live broaching units allow for the seamless inclusion of blind holes, partial-depth keyways, and intricate profiles, making previously challenging designs more feasible to manufacture.

Keywords: Live broaching unit, driven broaching tool, push broaching, pull broaching, rotary broaching, continuous broaching

Top 7 Internal Keyway Cutting Methods: How To Choose the Right One

Posted on 11/05/2023 by gisstec

Keyways play a crucial role in mechanical systems, enabling power transmission between shafts and other machine elements. Cutting an internal keyway can be a challenging task, but with the right method and tools, it can be done with precision and efficiency.

In this comprehensive guide, we will discuss seven popular internal keyway cutting methods. We will explore the advantages and limitations of each method, provide use case examples, and offer best practices to help you make an informed decision.

7 Methods for Cutting Internal Keyways

Broaching
Inserted broaching tools
Driven broaching heads (Live broaching tools)
Shaping / Slotting
Keyseating
Milling
Wire-Cut EDM

1. Broaching

What you need

Machine: A Broaching machine
Tooling: Keyway Broaches

Introduction

Broaching is a widely used method for cutting internal keyways, involving the use of a broach—a specialized cutting tool with a series of progressively larger teeth. The broach is clamped on the broaching machine and either pulled or pushed through the workpiece to broach the keyway.

Advantages

High precision and accuracy: Broaching can cut keyways with tight tolerances and excellent repeatability.
Surface finish: The progressive cutting action of a broach results in a smooth surface finish.
Suitable for high-volume production: Broaching is a fast and efficient method, making it ideal for mass production.

Limitations

Expensive tooling and machinery: Broaching machines and custom broaches can be costly investments.
No blind holes: The broach has to go through the workpiece for this method.
The workpiece cannot be finished on one machine and needs to be reclamped. Because only the broaching operation can be done with this method.
Limited to certain material types: Broaching is generally suited to softer materials and may struggle with harder or more abrasive materials.
Less flexible due to custom tooling requirements: Broaches are designed for specific keyway geometries, making it difficult to accommodate design changes or multiple keyway profiles.

Use case examples

Automotive industry: Transmission gears and components, such as synchromesh assemblies.
Aerospace: Turbine engine components, including compressor and turbine disks.
Heavy machinery: Gearboxes, shaft couplings, and power transmission components.

Best practices

Ensure proper alignment of the broach and workpiece: Accurate alignment is crucial to avoid tool deflection and ensure consistent internal keyway dimensions.
Use the correct broach size and type for the desired keyway geometry: Selecting the appropriate broach will ensure optimal cutting performance and extend tool life.
Regularly inspect and maintain the broaching tool to prevent wear and damage: Keeping the cutting edges sharp and free of damage will improve cutting performance and extend tool life.

2. Keyway Cutting with Inserted Broaching Tools

What you need

Machine: One of the following: CNC Lathe, CNC Machining Center, Slotter Machine (Slotting Machine), Shaping Machine, Conventional Lathe, Milling Machine

Tooling: Keyway Cutting Insert, Insert Holder

Introduction to Inserted Broaching Tools

Cutting keyways with inserted broaching tools is a modern broaching method, using a tool holder with replaceable cutting inserts. These keyway cutting tools can be used on CNC machines and a variety of other machines for slotting and shaping. This offers greater flexibility and reduced tooling costs compared to traditional broaching.

Keyway cutting using this method on a CNC lathe or machining center eliminates the need to reclamp the tool on a separate machine in order to broach the keyway.

In this method, first the workpiece is clamped in position. Then the keyway is cut by the tool through a series of successive passes. The tool removes an equal amount of material with each pass until the required size of the keyway is achieved.

It’s also called static broaching tools since the Z-axis movement necessary for chip removal comes from the machine itself. On the other hand, a driven broaching unit generates the back-and-forth movement in Z-axis by itself. (See third method for details)

Advantages of Inserted Broaching Tools

One of the lowest cost methods for cutting an internal keyway while maintaining excellent precision: The use of replaceable inserts eliminates the need for expensive custom broaches or specialized machines.
Cuts keyways in blind holes: Allows for cutting keyways inside blind holes with or without a relief groove
Enhanced flexibility with interchangeable inserts: Multiple keyway profiles and tolerances can be machined using a single tool holder and a variety of cutting inserts.
Improved tool life and easier maintenance: Cutting inserts can be replaced when worn or damaged, extending the life of the tool holder and reducing maintenance costs.
Cutting inserts can have their lifespan extended by resharpening them multiple times, allowing for their reuse.
Works with a wide range of material types: Can be used to machine keyways in both soft and hard materials, including cast iron, steel, titanium and non-ferrous alloys.

Limitations

Slower process compared to traditional broaching: Multiple passes are required to create the keyway. So, it’s more efficient overall for small batches.
Less suitable for high-volume production: While inserted broaching tools offer greater flexibility, they are not as efficient as some of the other methods for large-scale production.

Use case examples

Small-scale production: Gears, pulleys, and other components requiring precise keyways.
Prototyping: Testing new keyway designs or validating component fit and function.
Repair and maintenance: Retrofitting existing components with new keyways or correcting worn or damaged keyways.

Best practices

Use the appropriate cutting insert for the material being machined: Different materials require specific cutting geometries and coatings for optimal performance and tool life.
Ensure proper tool holder alignment with the workpiece: Accurate alignment is essential to maintain consistent keyway dimensions and prevent tool deflection. Use appropriate tools to correct any axis errors.
Regularly inspect and replace worn cutting inserts: Timely replacement of cutting inserts will ensure optimal cutting performance, surface quality and extend tool life.

3. Keyway Cutting with Driven Broaching Heads

What you need

Machine: CNC Lathe with a C-axis or a CNC Machining Center
Tooling: Driven Broaching Unit

Introduction to Driven Broaching Tools

Driven broaching heads (live broaching units) are specialized tools that can be mounted on CNC lathes with C-axis or CNC milling machines. These driven tools convert the rotary motion from the turret/spindle to linear motion to drive an inserted broaching tool through the workpiece.

This high-speed broaching method is commonly used on CNC lathes. It creates keyways similarly to the second method, which utilizes static broaching tools. However, driven broaching tools are remarkably faster, exceeding the speed of static tools by over 10 times.

Advantages

Fastest method without a dedicated keyway cutting machine: It enables the finishing of the workpiece without unclamping and setting it up on a separate machine.
Enhanced flexibility: Driven broaching heads can be used with existing CNC equipment, eliminating the need for dedicated broaching machines.
Cuts keyways in blind holes: Allows for cutting internal keyways in blind holes
High precision and accuracy: Driven broaching heads can produce keyways with tight tolerances and excellent repeatability.
Excellent choice for medium to large production volumes: Combines the efficiency of dedicated broaching machines with the convenience of finishing the operation on the same machine, streamlining your production process.
Works with a wide range of material types: Can be used to machine keyways in both soft and hard materials, including cast iron, steel, titanium and non-ferrous alloys.
Some driven broaching heads come with advanced error correction features, which allows for quick troubleshooting.

Limitations

Although investing in a driven broaching tool can provide a rapid return on investment for larger production batches, it may not be the most cost-effective solution if you only occasionally require broaching operations.
The size of the workpiece is limited to the capacity of the CNC lathe being used.
Driven broaching heads have a limited stroke usually going up to around 65mm (~2.5”)
Maximum keyway width is limited depending on the material, but is generally not larger than 16mm (~5/8”)

Use case examples

Medium and large-scale production: Components such as gears, pulleys, and couplings requiring precise keyways.
Leveraging existing CNC machines: Manufacturers looking to expand their keyway cutting capabilities without investing in dedicated broaching machines.

Best practices

Use the correct broaching head and cutting tool for the desired keyway dimensions and material type: Selecting the appropriate tooling will ensure optimal cutting performance and extend tool life.
Ensure proper alignment of the driven broaching head and workpiece: Accurate alignment is crucial to avoid tool deflection and maintain consistent keyway dimensions.
Regularly inspect and maintain the cutting tool and broaching head to prevent wear and damage: Keeping the cutting edges sharp and free of damage will improve cutting performance and extend tool life.

4. Keyway Cutting by Shaping / Slotting

What you need

Machine: Shaping machine, Slotter/Slotting machine
Tools: Keyway cutting tools / Internal keyway cutter

Introduction to Shaping and Slotting

Shaping or slotting is a method that involves using a reciprocating single-point cutting tool to remove material and create the keyway. The cutting tool moves horizontally or vertically along the workpiece, gradually cutting the internal keyway with each pass.

The operation is performed on dedicated machines such as a shaper or a slotter. As for cutting tools, either integral keyway cutting tools or inserted broaching tools as in the second method can be used. An adapter might be necessary to clamp the tools depending on the machine type.

Advantages of Shaping / Slotting

Low tooling and machinery costs: Shaping machines and cutting tools are typically less expensive than dedicated broaching or keyseating equipment.
Simple setup and operation: The shaping process is straightforward, making it accessible to operators with varying levels of experience.
Cuts keyways in blind holes: Allows for cutting keyways inside blind holes
Works with a wide range of material types: Shaping can be used to machine keyways in both soft and hard materials, including cast iron, steel, and non-ferrous alloys.

Limitations

Limited precision and accuracy: Shaping may produce less accurate keyway dimensions and require more skill to achieve consistent results.
Slower cutting process: The reciprocating motion of the shaping tool can be less efficient than the continuous cutting action of a broach or the electrical discharge process of Wire-Cut EDM.
Poor surface finish compared to other methods: Shaping may produce rougher surface finishes, requiring secondary operations to achieve desired results.

Use case examples

General engineering: Pulleys, sprockets, and couplings used in a variety of industries and applications.
Low-volume production: Custom or unique components requiring keyways, where the expense of dedicated broaching or keyseating equipment is not justified.
Educational institutions: Training and teaching purposes, where students can learn fundamental machining techniques and principles.

Best practices

Use the appropriate shaping tool for the desired keyway dimensions: Selecting the correct cutting tool will ensure optimal performance and extend tool life.
Ensure proper alignment of the shaping tool and workpiece: Accurate alignment is essential for maintaining consistent keyway dimensions and preventing tool deflection.
Regularly inspect and maintain the cutting tool to prevent wear and damage: Keeping the cutting edges sharp and free of damage will improve cutting performance and extend tool life.

5. Milling Internal Keyways

What you need

Machine: CNC Machining Center, Milling Machine
Tooling: Angle head, cutting tool e.g. end mill

Introduction to Milling Keyways

Milling an internal keyway requires the cutting tool, e.g. an end mill to to cut at 90º along the bore length. This kind of operation will usually require an angle head to dive into the bore vertically. The keyway is machined by removing material with the rotating cutting tool which is clamped to the angle head.

During the machining operation the lower body of the angle head needs to dive into the bore to cut the internal keyway. So this method is suited for workpieces with a bore large enough to accommodate the angle head.

This process can be performed on a variety of milling machines, including manual, CNC, and multi-axis machines.

Advantages of Milling an Internal Keyway

Suitable for a wide range of material types: Milling can machine keyways in soft and hard materials, including cast iron, steel, and non-ferrous alloys.
Can create keyways with varying depths and widths: Milling allows for greater control over keyway dimensions and can accommodate design changes more easily than dedicated broaching equipment.
Compatible with CNC machines for automated and precise keyway cutting: Milling can be integrated into CNC machining processes, offering improved accuracy, repeatability, and efficiency.
Can machine keyways in blind holes.

Limitations

Requires specialized tooling for internal keyways: Milling an internal keyway often requires an angle head. So it might be more suitable for higher-value or higher-volume milling parts in order to justify the investment.
Limited to certain keyway geometries: Milling may struggle with complex keyway profiles or non-standard shapes, particularly when using standard cutting tools.
Slower process compared to broaching: Milling can be less efficient than dedicated broaching machines, especially for high-volume production.

Use case examples

General engineering: Gears, sprockets, and couplings used in various industries and applications.
Automotive industry: Transmission components, such as gears and shafts, requiring precise keyways for power transmission.
Prototyping and small-scale production: Custom or unique components requiring keyways, where the flexibility of milling is advantageous over dedicated broaching equipment.

Best practices

Use the appropriate milling cutter for the desired keyway dimensions and material type: Selecting the correct cutting tool will ensure optimal performance and extend tool life.
Ensure proper alignment of the milling cutter and workpiece: Accurate alignment is essential for maintaining consistent keyway dimensions and preventing tool deflection.
Regularly inspect and maintain the cutting tool to prevent wear and damage: Keeping the cutting edges sharp and free of damage will improve cutting performance and extend tool life.

6. Keyseating

What you need

Machine: A Keyseating Machine
Tooling: Keyseater Tools / Internal keyway cutter

Keyseating is a method that uses a reciprocating cutting tool, called a keyseater or keyway cutter, to cut the keyway. The cutting tool is mounted vertically in the machine and moves up and down while the workpiece remains stationary.

Advantages of Keyseating

Low tooling and machinery costs: Keyseating machines and cutting tools are generally less expensive than dedicated broaching equipment.
Suitable for large workpieces and deep keyways: Keyseating machines can accommodate larger components and create deeper keyways than many other methods.
Works with a wide range of material types: Keyseating can be used to machine keyways in both soft and hard materials, including cast iron, steel, and non-ferrous alloys.

Limitations

Slower cutting process: The reciprocating motion of the keyseater tool can be less efficient than the continuous cutting action of a broach or the high-speed cutting of a driven broaching head.
Limited precision and surface finish: Keyseating may produce rougher surface finishes and less accurate keyway dimensions compared to broaching or Wire-Cut EDM.
Requires skilled operators: Achieving consistent results with keyseating requires experience and skill, particularly when working with harder materials or complex keyway profiles.

Use case examples

Large-scale components: Industrial gearboxes, couplings, and other power transmission elements in heavy machinery.
Shipbuilding: Propeller shaft keyways and components for marine propulsion systems.
Power generation: Turbine and generator shaft keyways in hydroelectric, nuclear, and fossil fuel power plants.

Best practices

Use the correct keyseater tool for the desired keyway dimensions: Selecting the appropriate cutting tool will ensure optimal performance and extend tool life.
Ensure proper alignment of the keyseater and workpiece: Accurate alignment is essential for maintaining consistent keyway dimensions and preventing tool deflection.
Regularly inspect and maintain the cutting tool to prevent wear and damage: Keeping the cutting edges sharp and free of damage will improve cutting performance and extend tool life.

7. Cutting Keyways with Wire-Cut EDM

What you need

Machine: Wire EDM

Introduction to Wire-Cut EDM Keyway Cutting

Wire-Cut EDM (Electrical Discharge Machining) is a process of cutting electrically conductive materials with high precision. It uses a thin, electrically charged wire to cut the required keyway by eroding material via electrical discharge.

This process is highly accurate and can be used to machine intricate keyway profiles in conductive materials. In addition, it is particularly effective in cutting precise keyways when working with hard materials.

Advantages of Wire-Cut EDM

High precision and accuracy: Wire-Cut EDM can produce keyways with tight tolerances and excellent repeatability, making it ideal for high-precision applications.
No mechanical forces exerted on the workpiece: The non-contact cutting process eliminates the risk of tool deflection or workpiece distortion.
Can cut hard materials and complex geometries: Wire-Cut EDM can machine keyways in hardened materials, such as tool steels, and create intricate profiles that may be difficult or impossible with other methods.
Excellent surface finish: The controlled electrical discharge process results in a smooth surface finish, often eliminating the need for secondary operations.

Limitations

Slower process compared to other methods: Wire-Cut EDM can be time-consuming, particularly for deep keyways or large workpieces.
Higher operational costs: Wire-Cut EDM machines and consumables, such as wire and dielectric fluid, can be expensive.
Only suitable for electrically conductive materials: Non-conductive materials, such as ceramics or certain polymers, cannot be machined using Wire-Cut EDM.

Use case examples

Machining hardened materials: Tool and die manufacturing, where keyways must be cut in hardened materials or components.
Complex geometries: Intricate keyway profiles and shapes, such as non-standard or curved keyways, that cannot be machined using conventional methods.

Best practices

Use the appropriate wire type and size for the material being machined: Wire selection is critical to achieving optimal cutting performance and minimizing wire breakage or wear.
Ensure proper alignment of the wire and workpiece: Accurate alignment is essential to maintain consistent keyway dimensions and prevent wire deflection.
Regularly maintain and clean the Wire-Cut EDM machine to ensure optimal performance: Timely maintenance, such as replacing worn wire guides or cleaning the dielectric fluid system, is crucial to the overall efficiency and longevity of the machine.

Conclusion

Cutting internal keyways is an essential task in many industries, and selecting the most appropriate method for a particular application is critical to achieving the desired results efficiently.

Broaching, keyway cutting with inserted broaching tools, keyseating, Wire-Cut EDM, shaping, milling, and keyway cutting with driven broaching heads each offer unique advantages and limitations.

The ultimate choice will depend on the size and geometry of the workpiece, keyway dimensions and quantity. By understanding these factors and applying best practices, manufacturers can make informed decisions and optimize their keyway cutting processes to maximize efficiency, precision, and overall performance.