Many manufacturing processes rely heavily on a service called precision threading. This process is highly effective at producing screw threads which are needed for a wide array of industrial applications. At JBC Machine, we are your source for precision threading services that produce exceptional quality threaded parts.
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Purpose of Precision Threading
Threading is used mainly to produce screwed connections on parts that are used in structures and machines. This service helps ensure exceptional parts application and the simplification of structural configurations.
Threading via Mill, Lathe, or Die-Cutting
Precision threading can be performed on a milling machine. In this case, a CNC machining center with helical interpolation is required, which ensures the efficiency of thread milling operations and dependable results. With threading on a lathe, the production of external and internal threads is made possible. The precision threading technique chosen will be based on the application of the parts involved.
When it comes to cutting external threads, the die-cutting method is highly popular. With die-cutting, parts are produced relatively rapidly. This method produces quality and accuracy to a moderate degree and its results are acceptable for most parts which are mass-produced.
Benefits of Precision Threading Operations
Thread cutting produces screwed connections for parts. Connections that have complete screws require internal threads and sometimes complementary external threads. For single piece manufacturing and repair operations, the ability to cut threads in this manner is a vital technique.
Our Precision Threading Operations
At JBC Machine, we utilize the latest technology, including everything from our software systems to our equipment to help ensure accuracy and quality results during each operational stage. Our trained and experienced personnel provide our precision threading services and the machines they operate make possible faster production and lower costs.
Regardless of the type of threading you need, we provide precision threading operations via lathe machines that can provide fast and accurate results and also carry out a large number of operations to top-of-the-line industry standards.
To learn more about the precision threading services we offer to meet the needs of your applications, give us a call today at 920.779., reach us through our contact form, or request a free quote.
THREADING ON THE LATHE
Introduction
This document presents some of the more common techniques for threading on the manual engine lathe.
Tap Handle
Using a tap handle is the most common method of tapping on the lathe. The workpiece is clamped in the lathe chuck, a spring loaded center (for smaller taps) or a dead center (for larger taps) is clamped in the tailstock, and the tap is held and rotated using a tap handle, as we do with the assigned parts in lab.
Figure 1a: Examples of using standard tap wrenches and spring loaded tap guide (left) or dead center (right) to tap holes on the lathe.
Figure 1b: Example of using an adjustable wrench and a live center to tap holes on the lathe.
Figure 1c: Examples of various tap handles.
Die Handle
Using a die handle is a common method of external thread cutting on the lathe. The workpiece is clamped in the lathe chuck, and the threading die is held and rotated using a die handle.
In general, round-shaped dies are for cutting threads onto a workpiece and hex-shaped dies are for chasing (cleaning up / repairing) existing threads.
Before using a threading die it&#;s important to make sure the major diameter of the shaft to be threaded matches the range listed in the Machinery Handbook. For example, a ½-20 UNF 2A thread must have a major diameter between 0. and 0.&#;. The smaller the major diameter, the easier the die will cut. In general, undersize the shaft diameter by 2% of the major thread diameter.
When using a threading die on the lathe it&#;s important to start the thread die collinear to the axis of the part, so use the body of the drill chuck for alignment and guidance. It&#;s also important to cut a generous chamfer on the end of the part to help the threading die start cutting.
Figure 2a: Examples of various threading die handles.
Figure 2b: Using the drill chuck body to align the threading die axis with the workpiece axis when starting the thread.
Rigid Tapping
Rigid tapping is the second most common method of thread cutting on the lathe. With this technique the tap or die is clamped in the tailstock using a variety of methods and threaded into or onto the workpiece under spindle power. Smaller taps up to 3/8&#; can be clamped in a keyed Jacob&#;s style chuck (NEVER a keyless chuck!). Larger taps should be clamped using a split sleeve or heavy duty tap driver, as shown in figure 3b.
Figure 3a: Rigid tapping on manual lathe. Click the image on the right for a video showing the process.
Figure 3b: Example of split sleeve tap driver for lathe tailstock (left) and heavy duty tap driver for lathe tailstock (right).
Figure 3c: Rigid die cutting on manual lathe.
Die cutting video
Single Point Threading
Single point threading involves mounting a threading tool with the proper thread profile to the toolpost and cutting the thread using multiple synchronized passes.
In general there are two types of cutting tool geometries which can be used: partial and full form profiles. Partial profile cutting geometries only cut the minor (or root) diameter of the thread, whereas full profile cutting geometries cut both the minor and major diameters of the thread profile to size. The advantage of partial profile cutting geometries is that one tool can cut a variety of thread pitches, whereas a full profile cutting geometry is only good for one particular thread pitch. The advantage of full profile cutting geometries is that the entire thread is finished in one operation, saving significant thread finishing and deburring time.
Figure 4a: Partial vs full form profile threading geometries.
The following videos explain the process in good detail. Fast forward through the parts which are not interesting to you J.
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Figure 4b: Good single point threading video (left; threading starts at 18:08 time stamp) and shorter clip of thread cutting (right).
Figure 4c: Examples of properly designed thread reliefs.
The process for single point turning threads in the design lab is as follows:
1. Clamp the part in the lathe using a live center if necessary.
2. Turn the OD to the target major diameter and include a chamfer on the end at least 0.020&#; smaller than the minor diameter of the thread profile to be cut.
3. If permissible, cut a thread relief using a grooving tool (as shown in Figure 10 and the two video thumbnail images above). The thread relief should be slightly less than the minor thread diameter.
4. Adjust the gearbox levers on the front of the headstock to cut the proper thread pitch.
5. Adjust the threading tool so it is aligned parallel to the X-axis.
6. Touch off on the part and zero the X-axis.
7. Cut a light (0.001 - 0.002&#;) scratch pass across the surface of the part to be checked with a thread gage for accuracy.
8. If the pitch of the scratch pass measures correctly, begin cutting the thread to depth; start with deeper depths of cut (.010&#; in aluminum, 0.005&#; in steel) and make progressively shallower cuts as the thread gets deeper and the threading tool begins to leave a worse finish)
9. As you approach final thread size, use a fine file to carefully debur the rough edges of the major diameter (unless using a full profile insert, which deburrs the major diameters automatically, as discussed above). The major diameter should end up a few thousandths of an inch under the nominal size, according to the tolerances listed in the Machinery Handbook (e.g. 0.-0.&#; for a ½-20 UNF 2A thread). You will know when you are close to the final size by keeping track of your X-infeed value, which will end up smaller than the equivalent internal thread&#;s minimum minor diameter by the noted allowance (e.g. 0.446&#; &#; 0.&#; = 0.&#; for the same ½-20 UNF 2A thread).
10. The procedure for making an actual cut is:
a. Check the direction of the threading direction by engaging the half-nut with the tool a safe distance from the part; for this example, we will thread toward the chuck
b. Adjust the spindle speed to a low setting (100-300 rpm) depending on how brave you are J
c. Position the tool in a safe starting location to begin cutting the thread
d. Advance the tool toward the part the distance (depth of cut) you wish to cut
e. Engage the half-nut for threading (it&#;s safest to leave this engaged for the duration of the threading session)
f. Turn the spindle ON in the FWD direction and allow the tool to make a cut
g. Turn the spindle OFF before the tool reaches a shoulder (if not exists); you can use the foot brake to stop it quickly if needed; if you stop too early, simply bump the power switch to continue the cut or rotate the chuck by hand
h. Retract the tool a safe distance from the part in the X-direction
i. Turn the spindle ON in the REV direction to allow the tool to return to a safe starting location
j. Repeat steps d. thru i. until the desired minor or pitch diameter is reached.
Figure 4d: Insert comprehensive single point threading video here?
Thread Measurement
Threads can be measured at least three different ways: by checking with a mating nut or thread gage, by using a dedicated thread micrometer, or by using the three wire method.
Mating Nut or Thread Gage
Checking with a mating quality nut or thread gage is the easiest method to determine when the thread is cut deep enough. Nuts are much cheaper than calibrated thread gages, but work fine for most prototyping applications.
Figure 5a: Checking thread size using an existing, quality nut. It&#;s convenient to keep a complete set of quality nuts on rings for thread measurement (right).
Figure 5b: Checking thread size using a thread gage. Click the thumbnail for the video.
Thread Micrometer
Using a thread micrometer is the easiest way to accurately measure thread pitch diameter for comparison to the thread data listed in the Machinery Handbook or this link. However, thread mics are fairly expensive.
Figure 6a: Example of a thread micrometer (notice the v-shaped anvils) and its use measuring thread pitch diameter.
Figure 6b: (Poorly made) video on how to use a thread micrometer. Click thumbnail for video.
3 Wire Method
The three wire method uses basic geometry and three identically sized wire rods to allow the pitch diameter to be calculated using any standard micrometer measurement. The three wire method is very accurate and the cheapest method of measuring a variety of thread pitch diameters. The downside to this method is that it requires a lot of dexterity to make an accurate measurement without dropping the precision thread wires.
Figure 7a: Checking thread size using 3 wire method. Click the thumbnails for the videos.
Figure 7b: Thread wire formulas for converting between actual measurement and pitch diameter.
Figure 7c: Three wire measurement method explained. Click image for .pdf file.
Miscellaneous Points
Always use cutting oil when threading on the lathe. WD40 works well for aluminum. Oatey dark threading oil works well for steel. Chlorinated Moly-D works best for materials which are tougher to machine, like stainless and alloy steels.
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