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Reamer Speeds and Feeds, Sizes, Types, and Tips Guide
What is reaming?
Reaming is a cutting process that uses a special tool called a reamer to enlarge an existing hole to a precise diameter and at the same to to create a smooth finish on the walls of the hole. Reaming is typically done on a milling machine, a lathe, or a drill press. Reaming is therefore a finishing operating. Another process, such as drilling must rough out the hole before it can be reamed.
There are other means to create holes with precise diameters and high quality finish on the walls, but reaming is often the best choice for speed and low cost.
If you need to hold tolerances tighter than +/- 0.002 on hole diameter, a reamer is probably the way to go. For example, you could use our Press Fit Calculator to figure the required hole size and them use a reamer to achieve that size within tolerances.
The surface finish from reaming depends on the workpiece material. The range for cast iron is 50 to 80 rms and 30 to 60 rms for steels. A PCD reamer can impart a finish as fine as 8 rms in aluminum.
How to ream a hole?
Performing reaming correctly depends first and foremost on preparation of the hole. The reamer is only capable of removing a small amount of material from the hole, and it will tend to follow the hole. It can only slightly improve the straightness of a hole if it has front-cutting capability. A 1/4 reamer might improve the straightness of a hole by up to 0.005, but no more.
If you require more correction for straightness than that, boring may be a better approach.
Heres a quick video that shows how to ream a hole on a Bridgeport Mill:
More information on how to use a reamer:
Optimum Reamer Speed and Feeds
What are the best reamer speeds and feeds?
Saw this question come up on HMEM. A lot of machinists are taught a rule of thumb similar to this:
1/3 the SFM, 3x more feed than the same sized Twist Drill
(Click here to learn what is SFM and how to go from SFM to RPM)
Opinions vary on exactly what that rule of thumb ought to be for reamer speeds and feeds. Some say the ratio to a twist drill is 1/3, while others suggest it should be 1/2.
In looking over a number of different manufacturers recommendations, weve found 1/2 yields results reamer speeds and feeds that are much closer to their recommendations. Moreover, when we say, 2x more feed, we actually want 2x more chip load. 2x the feedrate would be 4x the chip load since weve already doubled the spindle rpm relative to a twist drill. This chip load is a synthetic number for G-Wizard, so dont try to do too much math on it!
Heres what G-Wizard would suggest for reamer speeds and feeds with a 3/16 HSS Reamer in 300 series stainless, which was the question in the post:
A 3/16 reamer going 1 deep in 304 stainless should run 458 rpm and 2.75 ipm feed. Chipload is 0.
For comparison, here is the same cut with a 3/16 HSS Twist Drill:
Twist drill is 703 rpm (a little less than 2x the reamer), and 1.863 ipm (reamer is feeding a little faster)
Okay, those numbers are neither 1/2 nor 1/3, though the reamer is spinning close to 1/2 the twist drill, and the reamer feed is faster. What gives?
Well, this is another reason to use a calculator instead of a rule of thumb. Theres more at work here than a rule of thumb can account for. For example, it gets harder for a twist drill to extract chips the deeper the hole. Reamers dont even try to extract chipsthey have straight flutes and dont produce many chips if a large enough pilot hole is provided. Hence, the twist drill needs to behave more and more differently than the rule of thumb the deeper the hole goes. In this case, were quite deep1 is 5.3 diameters deep. I made the hole deep just to make the point.
Reamer Hole Sizes
Reamers are a fast way to finish a hole and very convenient relative to other precision approaches like boring. Their purpose is not to change the location of the hole. In fact, they often have long shanks so that they will deflect slightly to ensure the go into the hole. Rather, theyre made to improve the surface finish, roundness, and hole size quickly and easily.
Reamers are certainly not the be all and end all of hole boring, but if youve never used one, give it a try. One thing to keep in mind when using reamers is hole size guidelines. If you make the hole too large (i.e. to close to the reamers finished bore size without going over), there isnt enough meat for the reamer to do its job. Too small and youre making the precision reamer work way too hard.
There was recently some back and forth on CNCZone about reamer hole sizes, and I felt like it would be a good time to throw out that G-Wizard tells you the recommended guidelines for how far undersized to make your holes before reaming:
G-Wizard says to make the hole 0.010 0.025 undersized for a 1/2 reamer, and it tells you the closest twist drill size in that range
Did you notice that down in the Tips area (right above the Tortoise and Hare), G-Wizard tells you the right twist drill size?
Give G-Wizard a try. Its gives you the starting hole size and good feeds and speeds for both HSS and carbide reamers. Best of all, its free during your 30 day trial.
Pre-ream Drill Size Chart
The hole that will be reamed must first be drilled to an undersized diameter. Typically, the rule of thumb is to keep 0.010 to 0.015 material after drilling for the reamer to remove. Very small diameters, say 1/32 or less, should have 0.003 to 0.006 of material to remove by reaming. Rather than using a fixed range, it is better to use a percentage. Make the hole 2-3% smaller than the reamers diameter. If conditions are good, you can have the hole be up to 5% smaller than the reamers diameter.
If the hole is poorly drilled, more material may need to be available to allow the reamer to clean up the hole sufficiently.
One of the most common mistakes using a reamer is to leave insufficient stock for the reamer to cut. If this happens, the reamer will rub instead of cutting which will result in excessive wear, poor tool life, and inability to hold diameter tolerances.
BTW, our G-Wizard Calculator will tell you the hole size as part of a Feeds and Speeds Calculation for Reamers. But, for those who want an old-fashioned chart, here you go:
Optimum Operating Conditions
Given a decent hole and the proper reamer selected, here are some of the remaining operating conditions that must be met for optimal performance:
- Make sure the workpiece is held tightly so it cant flex, shift, or vibrate/chatter.
- Use a good quality chuck to hold the reamer.
- Use recommended cutting fluids for the reamer.
- Do not allow the reamers flutes to become blocked with chips.
- Line up the reamers centerline as closely as possible on the holes centerline.
- Reaming an angled surface is not recommended if the angle is more than 5 degrees.
- Uses the shortest tool overhang (stickout) possible.
Reamer Holding
Reamers are typically held by precision collets or hydraulic chucks.
Other Reaming Tips
How to program a reamer in CNC
CNCers use a G85 canned cycle rather than a drilling cycle for reamers. The drilling cycles rapid out of the hole which can mar the surface finish.
Maximum Reaming Depth for HSS
HSS (High Speed Steel) is MUCH less rigid than Carbide. If the hole depth is greater than the limits below, you should be using a carbide reamer to ensure the reamer cant flex and the hole stays straight.
Hole Diameter Max Hole Depth with HSS Reamer 0. to 0. 0.500 0. to 0. 0.625 0. to 1. 0.750 1. to 1.
0.875
Workhardening materials like Titanium and Stainless Steel In materials that can workharden, such as Titanium, its desirable to keep a light DOC (Depth of Cut). The light DOC keeps chips thin so theyre easier to evacuate.
Reaming Twice If two much stock remains after drilling, it is possible to use 2 sizes of reamer to open up the hole.
Heat Treating Reamed Holes
Heat Treatment will often shrink a reamed hole so do some experiments to determine exactly how oversized the hole should be before any shrinkage will bring it right down to spec and tolerances.
Interrupted Reaming A spiral flute reamer
If there are hole interruptions, such as a keyway or cross hole, you should use a spiral-flute reamer rather than a straight flute. The spiral will help bridge the gap so the reamer is supported at all times. A straight flute reamer will bang like crazy as every tooth catches on the interrupted edge.
Reamer Types and Selection
Reamer Geometry and Flute Styles
Reamers typically have one of the following flute styles:
- Straight: Best suited to non-chip forming materials. The work best in thru holes as the lack of helix makes it hard for them to life chips out of a blind hole.
- Right Hand Spiral: May be used to pull chips out of a blind hole. Spirals are also better than straight flutes for making interrupted cuts. Due to aggressive geometry, they may cut slightly oversized.
- Left Hand Spiral: Preferred thru holes as the reverse spiral pushes chips down into the hole. Good for interrupted cuts and hard materials. Can potentially provide the very best size and finish.
- Expansion Reamers: Useful in in applications with abrasive materials that change the reamers size through wear very quickly. You can expand the diameter by turning a set screw.
In addition to flute style, reamer is geometry may be modified by these reamer types:
Types of reamers
Chucking reamer
The most common type of reamer, pictured at the very top of this article, is a Chucking Reamer.
Tapered reamer
A variety of uses required a tapered reamer than can finish a tapered hole:
- Taper Pin Reamers are designed to ream holes for standard taper pins. Cut the pilot hole a few thousands smaller than the small daimeter of the tapered hole.
- Car Reamers are made for Railroad Car work.
- Taper Pipe Reamers are used before tapping a tapered thread such as NPTF, Dryseal, or ANPT threads.
- Bridge Reamers are used in structural steel applications such as bridge building and ship construction.
You can find tapered reamers especially made for most standard tapered holes. For example, heres a 5 piece collection of Morse Taper reamers to fit 1 MT to 5 MT:
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Hand reamer
Hand Reamers are designed to be used by hand. Since the human hand is not capable of exerting as much force as a machine, Hand Reamers have special features to make reaming easier:
- tapered lead for easy entry
- Square on the end for use with a wrench
Even so, theyre not recommended for removing very much material.
Ring reamers / Cutting Rings
Cutting ring adjustable reamer
These reamers can use replaceable inserts and they are often expandable to adapt to tool wear.
Piloted Reamer
When alignment is critical the best tool may be a piloted reamer. The pilot is non-cutting and acts as a guide to ensure alignment of multi-diameter holes.
Drill Reaming
Drill Reamers combine a reamer and a drill into one tool. They only work for through holes, but they can save tool change time and really help lower costs.
Coolant Options
Good quality cutting fluid can enhance surface finish and prolong the reamers useful life. Through spindle coolant can be even more effective as it has a positive effect on chip control and chip breaking.
Center Feed coolant aids chip clearing. Use a Right Hand Spiral Reamer with Center Fed Coolant to maximize chip clearing, especially in highly ductile materials.
Cost Effective Reamer Selection: Carbide vs HSS and Cobalt
This is basically a function of the number of parts to be made and the hardness of the material being reamed. For most materials, its probably worth spending for carbide if you need to ream more than about 40 parts. Even 20 parts should go carbide if you are reaming all but the very softest kinds of materials.
Reamer Troubleshooting
Poor Finish
- Unequal chamfers: Reamer must be reground
- Incorrect Margins: Reamer must be reground
- Excessive Spindle Runout: Try a bushing 2 or 3 ten thousandths over reamer diameter.
- Chatter: Increase feed and reduce spindle rpms. Use power feed. Use spiral fluted reamer.
- Insufficient Cutting Action: Get a reamer with positive radial rake to reduce cutting pressure.
Oversized Holes, Tapered Holes, & Bell Mouth Holes
- Misalignment: Make sure your fixturing and setup allow the reamer to be right on center of the hole. Use a floating holder if necessary. Consider using precision bushings or piloted reamers.
- Incorrect Feed and/or Speed: use correct Feeds & Speeds.
Excessive Tool Wear
- Improper stock removal: Pre-ream hole should be 2-3% of reamer diameter
- Excessive Reaming Pressure: Reduce feed rate
- Misalignment: Make sure your fixturing and setup allow the reamer to be right on center of the hole. Use a floating holder if necessary. Consider using precision bushings or piloted reamers.
Crooked Holes
- Drill walking or incorrect sharpening: Make sure your pre-ream hole is good.
Tool Breakage
- Excessive reaming pressure: Reduce feed rate.
- Misalignment: Make sure your fixturing and setup allow the reamer to be right on center of the hole. Use a floating holder if necessary. Consider using precision bushings or piloted reamers.
Watch this video to learn how to use a reamer to properly and efficiently ream a hole! Tech Team Expert Kurt Repsher walks you through the do's and don't's of reaming a hole with a hand reamer from planning to execution. Subscribe to our YouTube Channel to see more how-to application videos like this one!
What is a reamer & what is reaming?
Reamers are multi-fluted cutting tools used to enlarge existing holes to a precise diameter. They are available in a variety of shank styles that can be mounted into hand tools, chucks, collets, or other tool holders, and are used in a variety of portable or stationary machines such as drill presses, lathes, screw machines, milling machines and more. The cutting end is ground with a 45° chamfer angle for easy entry into the hole. Straight fluted reamers are best for through holes, left-hand spiral flute models are better in blind hole applications. Available in a variety of materials, to suit the application and workpiece material, and some are available in almost any size imaginable. Light cutting oil or coolant is recommended for reaming operations.
HOW DOES A REAMER WORK?
A reamer is a cutting tool that is used to open the size of an existing hole by a small amount. A reamer will leave a smoother finish and a more precise size than a drill. Hand reaming, or reaming a hole without coolant or oil will result in an oversized hole and a rougher finish. Avoid reaming to the bottom of a blind hole.
What size drill should I use with a reamer?
- For reamers up to a 1/2": subtract 2% to 4% from the reamer diameter to determine the best drill size.
- For reamers 1/2" and larger: subtract 1/64 from the reamer diameter to determine the best drill size
how To use a reamer, step by step:
For the best reaming results, prepare your holes with just the right amount of stock for the reamer to remove. Too little, and the reamer will rub, leaving a smaller diameter than expected. Too much and the hole may be oversized and have a rough finish. Since reaming is about precision, use stub length tools where possible. The following is an example of how to ream a hole in metal. In this example, we are reaming a 5/16" (.") hole in soft, mild steel, step by step:
Step 1: Ensure that the workpiece is held securely and will not slide or rock.
Step 2: Locate & spot drill hole using a spot drill with a slightly greater taper than the drill being used. (For best results, avoid using a center drill (combination drill & countersink.)
Step 3:. Subtract 3% (since were working in mild steel) from the reamer diameter to determine the best drill size. (For example, . 3% = ."). A good rule of thumb to find the best drill size is to subtract 2% to 4% from the reamer size. 2% for harder metals, and 4% for softer materials.
Step 4: Use the appropriate drilling feed and speed for the tool, material and operation.
Step 5: Keep the drill and hole well lubricated with cutting oil or coolant.
Step 6: Drill the hole with a size N drill (0.302). Peck drill to prevent chips from jamming and scoring the walls of the hole.
Step 7: Reduce the feed and speed:
RPM: Use 1/2 to 2/3 the speed of the drill that was used.
FEED: Double the feed of the drill that was used.
Step 8: Chamfer top of hole (just to break the edge) with either a 90° or 82° countersink.
Step 9: Since reaming doesnt require heavy cutting fluids for optimal performance, use lighter oil or coolant. This will help to produce an accurate size hole and a smooth Finnish.
Step 10: Ream hole with a 5/16 reamer. Dont stop or peck with the reamer until it exits through the bottom of the hole. With the machine turned off and the spindle completely stopped, pull the reamer straight up, out of the hole.
REAMING RECOMMENDATIONS:
- Workpiece hardness and machinability must be considered when setting machine speed and feed rate. Both play an important part in the life expectancy of a tool and the hole size and finish you wish to attain.
- If chatter is a problem, slow the cutting speed and increase your feed rate. Stock removal on reaming operations should not exceed 2% to 4% of tool diameter in most cases.
- Cutting oil or coolant is recommended for most reaming operations. Lighter oil and coolant will help to produce an accurate size hole and a smooth Finnish. Heavier, darker cutting oils might produce a slightly smaller hole size.
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For the best reaming results, prepare your holes with just the right amount of stock left in them. Too little, and the reamer will rub, leaving you with more wear and less diameter than expected. Too much and you may have to repeat the process. A precise balance of stock in your holes will give your reamer the best surfaces for optimal performance.
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After selecting the optimal reamer option for your materials, ensure that your pre-drilled holes are the correct diameter. Now you can set the correct speeds and feed for your application.
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Keep your workpieces rigid, and ensure there is zero play in your spindle machine set-ups.
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Using higher quality chucks to hold your straight shank reamer can help prevent slippage. Slippage during automatic feeder operation can cause damage and breakage to your reamers.
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Reaming doesnt require heavy cutting fluids for optimal performance, so utilizing soluble oils with 40-to-1 dilution should suffice for most applications. If dry machining gray iron, air blasting can improve your surface preparation results.
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Check concentricity between your high-precision centers regularly, and regrind your bevel leads when necessary.
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Keeping your reamers sharp can maintain accuracy and hole quality while improving tool life.
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Make sure tool over hang from machine spindle is kept to absolute minimum.
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Use a soft faced hammer if utilizing morse taper shank reamers.
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Remember to check the flutes in your reamer for chip blockage throughout operation.
Popular types Of Reamers:
For a complete listing of all reamer types and styles, view or download our comprehensive Holemaking Guide, available via the link below.
Chucking Reamers, or Machine Chucking Straight Shank Reamers are used to enlarge existing holes to a very precise diameter. Chucking reamers have round, straight shanks which can be mounted in chucks, collets, or other tool holders, and are used in a variety of portable or stationary machines such as drill presses, lathes, screw machines, milling machines and more. Chucking Reamers are available in almost any size imaginable.
Taper Shank Chucking Reamers are like Machine Chucking Straight Shank Reamers, but these have a Morse Taper shank that will fit a same-size Morse Taper spindle, socket, or toolholder. Theyre multi-fluted cutting tools, used to enlarge existing holes to a precise diameter. The shanks on these reamers are used in a Morse Taper spindle, socket, or toolholder.
Shell Reamers are also like Machine Chucking Straight Shank Reamers and Taper Shank Chucking Reamers but without a shank. They are used with a shell reamer arbor, which fits the hole in the reamer. Shell reamers are used to produce larger holes of 3/4" diameter or greater. Shanks/arbors are sold separately and will fit a range of Shell Reamer sizes, which makes these reamers an economical choice for your large-hole reaming needs.
Adjustable Blade Reamers are versatile reamers due to their broad size ranges and are used by hand for resizing of hole diameters to a precise size. The replicable blades slide within tapered slots in the reamer body by loosening the nut at one end and tightening the nut at the other end, allowing the reamer to maintain a specific size. Adjustable Blade Reamers are recommended for through-hole operations.
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