Threading On A Lathe

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Tools for turning threads have benefited from the same improvements in coatings and material grades that have improved turning tools overall. In addition, there have been design improvements in thread turning inserts resulting in better chip control. In spite of these changes, however, manufacturing engineers tend to spend little time optimizing their threading operations, seeing the thread machining process as a &#;black box&#; that doesn&#;t lend itself to incremental improvement.

In fact, the thread machining process can be engineered for better efficiency. The first step is to understand some basic topics in thread machining.

Why Thread Turning Is Demanding

Thread turning is more demanding than normal turning operations. Cutting forces are generally higher, and the cutting nose radius of the threading insert is smaller and therefore weaker.

In threading, the feed rate must correspond precisely to the pitch of the thread. In the case of a pitch of 8 threads per inch (tpi), the tool has to travel at a feed rate of 8 revolutions per inch, or 0.125 ipr. Compare that to a conventional turning application, which may have a typical feed rate of around 0.012 ipr. The feed rate in thread turning is 10 times greater. And the corresponding cutting forces at the tip of the threading insert can range from 100 to 1,000 times greater.

The nose radius that sees this force is typically 0.015 inch, compared to 0.032 inch for a regular turning insert. For the threading insert, this radius is strictly limited by the allowable radius at the root of the thread form as defined by the relevant thread standard. It&#;s also limited by the cutting action required, because material can&#;t be sheared the way it can be in conventional turning or else thread distortion will occur.

The result of both the high cutting force and the more narrow concentration of force is that threading inserts see much more stress than what is typical for a turning insert.

Partial Versus Full Profile Inserts

Partial profile inserts, sometimes referred to as &#;non topping&#; inserts, cut the thread groove without topping or cresting the thread. One insert can produce a range of threads, down to the coarsest pitch&#;that is, the smallest number of threads per inch&#;that is permitted by the strength of the nose radius of the insert.

This nose radius is designed to be small enough that the insert can machine various pitches. For small pitches, the nose radius will be undersize. This means the insert will have to penetrate deeper. For example, a partial profile insert machining an 8-tpi thread requires a thread depth of 0.108 inch, while the same thread produced with a full profile insert requires only the specified depth of 0.081 inch. The full profile insert therefore produces a stronger thread. What&#;s more, the full profile insert may produce the thread in up to four fewer machining passes.

Multi-Tooth Inserts

Multi-tooth inserts feature multiple teeth in series, with a given tooth cutting deeper into the thread groove than the tooth that went before it. With one of these inserts, the number of passes required to produce a thread can be reduced by up to 80 percent. Tool life is considerably longer than that of single-point inserts because the final tooth machines away only one half or one third of the metal in a given thread.

However, because of their high cutting forces, these inserts are not recommended for thin-wall parts&#;chatter can result. Also, the design of a workpiece machined with one of these inserts needs to have a sufficient amount of thread relief to allow all of the teeth to exit the cut.

Infeed Per Pass

The depth of cut per pass, or infeed per pass, is critical in threading. Each successive pass engages a larger portion of the cutting edge of the insert. If the infeed per pass is constant (which is not recommended), then the cutting force and metal removal rate can increase too dramatically from one pass to the next.

For example, when producing a 60-degree thread form using a constant 0.010-inch infeed per pass, the second pass removes three times the amount of metal as the first pass. And with each subsequent pass, the amount of metal removed continues to grow exponentially.

To avoid this increase and maintain more realistic cutting forces, the depth of cut should be reduced with each pass.

Infeed Methods

At least four infeed methods are possible. Few recognize how much impact the choice among these methods can have on the effectiveness of the threading operation.

Radial infeed 

While this is probably the most common method of producing threads, it is also the least recommended. Since the tool is fed radially (perpendicular to the workpiece centerline), metal is removed from both sides of the thread flanks, resulting in a V-shaped chip. This form of chip is difficult to break, so chip flow can be a problem. Also, because both sides of the insert nose are subjected to high heat and pressure, tool life will generally be shorter with this method than with other infeed methods.

Flank infeed 

In this method, the infeed direction is parallel to one of the thread flanks, which normally means the tool feeds in along a 30-degree line. The chip is similar to what is produced in conventional turning. Compared to radial infeed, the chip here is easier to form and guide away from the cutting edge, providing better heat dissipation. However, with this infeed, the trailing edge of the insert rubs along the flank instead of cutting. This burnishes the thread, resulting in poor surface finish and perhaps chatter.

Modified flank infeed (recommended) 

This method is similar to flank infeed except that the infeed angle is less than the angle of the thread&#;that is, less than 30 degrees. This method preserves the advantages of the flank infeed method while eliminating the problems associated with the insert&#;s trailing edge. A 29½-degree infeed angle will normally produce the best results, but in practice any infeed angle between 25 and 29½ degrees is probably acceptable.

Alternating flank infeed 

This method alternately feeds the insert along both thread flanks, and therefore it uses both flanks of the insert to form the thread. The method delivers longer tool life because both sides of the insert nose are used. However, the method also can result in chip flow problems that can affect surface finish and tool life. This method is usually only used for very large pitches and for such thread forms as Acme and Trapeze.

Clearance Angle Compensation

Some threading insert and toolholder systems provide the ability to precisely tilt the insert in the direction of the cut by changing the helix angle. This feature provides a higher quality thread because it tends to prevent the insert from rubbing against the flank of the thread form. It also provides a longer tool life because the cutting forces are evenly distributed over the full length of the cutting edge.

An insert that is not tilted in this way&#;one that holds the cutting edge parallel to the centerline of the workpiece&#;creates unequal clearance angles under the leading and trailing edges of the insert. Particularly with coarser pitches, this inequality can cause the flank to rub.

If you are looking for more details, kindly visit threading in lathe machine.

Adjustable systems permit the angle of the insert to be tilted by changing the orientation of the toolholder&#;s head, generally using shims. Precise adjustment results in leading and trailing edge angles that are equivalent, ensuring that edge wear will develop uniformly.

Miniaturization And Specialization

Inserted tools are available to permit internal thread turning of bores down to about 0.3 inch in diameter. Producing the threads for these small bores through turning offers many advantages. The quality of the thread formed is usually higher, the insert design allows chips to flow out of the bore with little damage to the thread, and the ability to index the tooling results in a lower cost for tooling.

The carbide used for these applications is generally a grade that permits machining at low surface speeds. For an internal threading application in a small hole, machine tool limitations generally leave anything other than a low surface speed out of the question.

Technology improvements have expanded the application range of thread turning tools, and the move to internal thread turning of small bores is one example of this. In spite of the expanded range of standard tools, however, manufacturers continue to encounter special problems that justify custom tooling. Special tooling developed in cooperation with the tool supplier is an option that shouldn&#;t be overlooked when searching for the right threading tool for a particular job.

About the authors: Stuart Palmer is a marketing consultant to cutting tool maker Vargus Ltd. of Nahariya, Israel. Mike Kanagowski is the general manager of VNE Corp., a sister company of Vargus in Janesville, Wisconsin.

In the intricate manufacturing world, threads are crucial in providing the necessary coupling and connection between components. Understanding the nuances of thread machining is essential for producing high-quality products with optimal strength and durability. In this guide, we will study the fundamentals of machining threads, exploring different types of threads, terminology, methods for machining, key design tips, surface finishing techniques, and more.

Types of Threads:

Threads come in various forms, including internal and external threads. Internal threads within fasteners like nuts are machined using specific threading tools or taps. External threads, seen on bolts and screws, are created using lathes or die-cutting methods. Understanding the distinction between these types is crucial for effective thread machining.

Internal Threads:

Internal threads inside fasteners like nuts are machined using specialized tools such as taps, thread mills or single-tip threading tools. These threads accept screws and secure them within the workpiece. Select a tool with the appropriate nominal size to machine internal threads and fix the hole diameter according to the end-use application. Remove the actual threads from the CAD drawing during CNC machining, leaving only the major diameter profile. To calculate the minor diameter before tapping, consult hole size charts. It is critical to understand the percentage of thread that you will be tapping. A target is 70%, but different applications require different hole sizes. Also note that cut taps require different hole sizes than form taps.. After locating the center and drilling the hole to the calculated core-hole diameter, tap the hole&#;s edge with a tap tool and chamfer it with a 90-degree countersink.

External Threads:

External threads, which run along the outside of a fastener&#;s shaft like bolts, are typically produced using lathes. Any cylindrical rod can be turned in to create external thread profiles, with the tool selection based on the required pitch depth. External thread cutting begins with clamping the threading die, typically a round die, to the lathe machine. Before cutting, file and chamfer the edges at a 45-degree angle. Then, touch the workpiece edge with a cutting tool before revolving it along its length to create a continuous thread.

Terminology in Threads Machining:

Special taps offer several advantages over standard taps in certain applications:

• Root

  : The bottom surface of a thread groove, formed by two adjustable threads, can be either flat or rounded.

• Crest: 

  The outermost surface of a thread, created by the two sides of the thread, is known as the crest.

• Flank

  : The surface that connects a thread&#;s root and crest, making contact with its counterpart, is called the flank.

• Thread angle: 

  The angle formed by two adjacent flanks of two threads in the axial plane is called the thread angle.

• Thread depth: 

  The axial distance between a thread&#;s crest and root is defined as thread depth.

• Pitch: 

  The distance between two identical threads is known as the pitch.

• Helix angle: 

  The angle between the thread&#;s helix and a line that is normal to the axis of rotation is called the helix angle.

• Major diameter: 

  The diameter of the imaginary co-axial cylinder that touches the crest of the external thread (or root of the internal thread) is termed the major diameter.

• Minor diameter: 

  The diameter of the imaginary co-axial cylinder that touches the root of the external thread (or crest of the internal thread) is called the minor diameter.

• Pitch Diameter: 

  The average of the major and minor diameters is the pitch diameter.

Methods for Machining Threads:

Thread cutting is a fundamental process in creating screwed connections between components. Whether machining internal or external threads, ensuring they are securely inserted and locked together during assembly is crucial. Selecting the most suitable method for thread cutting involves considering various factors such as technical complexity, cost-effectiveness, time efficiency, accuracy, and tool availability.

CNC Milling:

CNC milling is a versatile method capable of cutting internal and external threads. It utilizes the circular motion of threading tools to create threads in a single lateral movement. This technique is particularly effective for larger holes, providing a high surface finish and precise dimensional consistency.

Thread Machining with Milling:

In thread milling, two popular tools are solid carbide and indexable tools. These tools feature parallel cutting teeth, unlike taps with helical setups. Multi-tooth thread machines can cut threads to deeper layers in a single turn around a hole. While carbide tools are preferred for smaller hole sizes due to their precision, indexable tools offer a cost-effective solution as only the cutter needs replacement.

Threads Machining with Lathe:

A single-point turning tool with a carbide insert can machine threads with a lathe. Before starting the cutting process, calculations for pitch, lead, depth, and major and minor diameters are essential. The tap handle method is commonly employed for tapping with a lathe machine, but it requires the workpiece to be securely clamped into the chuck.

Here&#;s a step-by-step guide for thread machining with a lathe:

1. Set the thread bit and adjust its height to align with the center point of the lathe. Ensure the tool bit is at the correct angle relative to the workpiece.


2. Gradually bring the threading tool closer to the workpiece.


3. Rotate the handle to generate threads. For instance, if aiming for threads with a pitch of 1 mm, the threading tool should move 1 mm as the workpiece completes one revolution.

Die-Cutting of Threads:

Die-cutting is a simple and cost-effective method suitable for mass production without requiring high precision. It involves using threading dies to create external threads compatible with internal thread counterparts.

Here&#;s an overview of the die-cutting process:

1. Chamfer the first end side of the workpiece at a 45-degree angle.


2. Choose an appropriate diameter for the die and secure it in a die-stock.


3. Position the dies on the end side of the workpiece and rotate the die-stock along its length to create threads.

Threading dies are commonly employed in metalworking and manufacturing to repair threads in worn-out holes or bolts. Threads produced with dies enhance strength and durability while reducing material costs due to minimal wastage.

Key Thread Design Tips: :

Design Tips for Designing Machined Threads

Uniform Surface Preparation:

• A uniform surface preparation is essential for ensuring the quality and functionality of machined threads.
• Before threading, it&#;s crucial to ensure that the surface of the workpiece is clean, free from debris, and properly deburred to prevent interference during threading.
• Any irregularities or imperfections on the surface can impact thread quality and lead to issues such as irritating or stripping.

Chamfering:

• A uniform surface preparation is essential for ensuring the quality and functionality of machined threads.
• Before threading, it&#;s crucial to ensure that the surface of the workpiece is clean, free from debris, and properly deburred to prevent interference during threading.
• Any irregularities or imperfections on the surface can impact thread quality and lead to issues such as irritating or stripping.

Thread Height and Thickness:

• The appropriate thread height and thickness are crucial for achieving the desired thread profile and functionality.
• The thread height refers to the length between the crest and the root of the thread, while the thread thickness is the width of the thread measured across the crest.
• These dimensions should be carefully calculated based on the thread pitch, diameter, and intended application to ensure optimal thread engagement, strength, and load-bearing capacity.

Surface Finishing for Threads:  

• Surface finishing is the final step in thread machining, enhancing both the threads&#; aesthetics and functionality.
• Black-oxide finishes and painting are two effective methods for surface treatment, offering corrosion resistance and aesthetic appeal.
• Black-oxide finishes provide additional protection against corrosion, making them particularly suitable for threaded components exposed to harsh environments or outdoor applications.
• Painting can further enhance the appearance of machined threads and provide additional protection against corrosion, abrasion, and wear.

Conclusion:

Mastering thread machining is essential for producing high-quality products in the manufacturing industry. By understanding the types of threads, key terminology, machining methods, design tips, and surface finishing techniques, manufacturers can ensure the reliability and durability of their products. For expert assistance in thread machining services, consult our experienced team of engineers specializing in all thread manufacturing aspects.

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