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Honing
5:44 pm | November 22, 2011
Author: ManufacturingET.org | Category: Machining | Tags: , , | Comments: 1
ManufacturingET.org > 2011 > November

The surface of a honed workpiece.

Honing is an abrasive machining process that produces a precision surface on a metal workpiece by scrubbing an abrasive stone against it along a controlled path. Honing is primarily used to improve the geometric form of a surface, but may also improve the surface texture.

Typical applications are the finishing of cylinders for internal combustion engines, air bearing spindles and gears. Types of hone are many and various but all consist of one or more abrasive stones that are held under pressure against the surface they are working on.

In everyday use, a honing steel is used to hone knives, especially kitchen knives, and is a fine process, there contrasted with more abrasive sharpening.

Other similar processes are lapping and superfinishing.

Contents

Honing stones

Superabrasives and hone head for cylinders.

Honing tools

Honing uses a special tool, called a honing stone or a hone, to achieve a precision surface. The hone is a composed of abrasive grains that are bound together with an adhesive. Generally, honing grains are irregularly shaped and about 10 to 50 micrometers in diameter (300 to 1,500 mesh grit). Smaller grain sizes produce a smoother surface on the workpiece.

A honing stone is similar to a grinding wheel in many ways, but honing stones are usually more friable so that they conform to the shape of the workpiece as they wear in. To counteract their friability, honing stones may be treated with wax or sulfur to improve life; wax is usually preferred for environmental reasons.[1]

Any abrasive material may be used to create a honing stone, but the most commonly used are corundum, silicon carbide, cubic boron nitride, or diamond. The choice of abrasive material is usually driven by the characteristics of the workpiece material. In most cases, corundum or silicon carbide are acceptable, but extremely hard workpiece materials must be honed using superabrasives.[1]

The hone is usually turned in the bore while being moved in and out. Special cutting fluids are used to give a smooth cutting action and to remove the material that has been abraded. Machines can be portable, simple manual machines, or fully automatic with gauging depending on the application.

Modern advances in abrasives have made it possible to remove much larger amount of material than was previously possible. This has displaced grinding in many applications where “through machining” is possible. External hones perform the same function on shafts.

Process mechanics

Since honing stones look similar to grinding wheels, it is tempting to think of honing as a form of low-stock removal grinding. Instead, it is better to think of it as a self-truing grinding process.[2]

In grinding, the wheel follows a simple path. For example, in plunge grinding a shaft, the wheel moves in towards the axis of the part, grinds it, and then moves back out. Since each slice of the wheel repeatedly contacts the same slice of the workpiece, any inaccuracies in the geometric shape of the grinding wheel will be transferred onto the part. Therefore, the accuracy of the finished workpiece geometry is limited to the accuracy of the truing dresser. The accuracy becomes even worse as the grind wheel wears, so truing must occur periodically to reshape it.

The limitation on geometric accuracy is overcome in honing because the honing stone follows a complex path. In bore honing for example, the stone moves along two paths simultaneously. The stones are pressed radially outward to enlarge the hole while they simultaneously oscillate axially. Due to the oscillation, each slice of the honing stones touch a large area of the workpiece. Therefore, imperfections in the honing stone’s profile cannot transfer to the bore. Instead both the bore and the honing stones conform to the average shape of the honing stones’ motion, which in the case of bore honing is a cylinder. This averaging effect occurs in all honing processes; both the workpiece and stones erode until they conform to the average shape of the stones’ cutting surface. Since the honing stones tend to erode towards a desired geometric shape, there is no need to true them. As a result of the averaging effect, the accuracy of a honed component often exceeds the accuracy of the machine tool that created it.

The path of the stone is not the only difference between grinding and honing machines, they also differ in the stiffness of their construction. Honing machines are much more compliant than grinders. The purpose of grinding is to achieve a tight size tolerance. To do this, the grinding wheel must be moved to an exact position relative to the workpiece. Therefore a grinding machine must be very stiff and its axes must move with very high precision.

A honing machine, ironically, is relatively inaccurate and compliant. Instead of relying on the accuracy of the machine tool, it relies on the averaging effect between the stone and the workpiece. In fact, compliance is a requirement of a honing machine that is necessary for the averaging effect to occur. This leads to an obvious difference between the two machines: in a grinder the stone is rigidly attached to a slide, while in honing the stone is actuated with pneumatic or hydraulic pressure.

High-precision workpieces are usually ground and then honed. Grinding determines the size, and honing improves the shape.

The difference between honing and grinding is not always distinct. Some grinders have complex movements and are self-truing, and some honing machines are equipped with in-process gaging for size control. Many through-feed grinding operations rely on the same averaging effect as honing.

Honing configurations

A flat honing machine.

  • Track/Raceway honing
  • Spherical honing
  • OD through-feed honing (taper and straight)
  • Flat honing
  • Bore honing

Economics

Since honing is a high precision process, it is also relatively expensive. Therefore it is only used in components that demand the highest level of precision. It is typically the last manufacturing operation before the part is shipped to a customer. The dimensional size of the object is established by preceding operations, the last of which is usually grinding. Then the part is honed to improve a form characteristic such as roundness, flatness, cylindricity, or sphericity.[3]

Performance advantages of honed surfaces

Since honing is a relatively expensive manufacturing process, it can only be economically justified for applications that require very good form accuracy. The improved shape after honing may result in a quieter running or higher precision component.[3]

Cross-hatch finish

A “cross-hatch” pattern is used to retain oil or grease to ensure proper lubrication and ring seal of pistons in cylinders. A smooth glazed cylinder wall can cause piston ring and cylinder scuffing. The “cross-hatch” pattern is used on brake rotors, and flywheels.

Plateau finish

A tool with the brand name Flex-Hone made by Brush Research Manufacturing Co., Inc. was introduced as a hone with many of the benefits of honing without the need for labor intensive set up or training. The tool is often referred to as a “ball-hone” for its many abrasive globules mounted to the ends of flexible nylon filament. The result of using this tool is that it provides a cross hatched finish while achieving a plateau finish at the same time.

The Plateau Finish is one characterized by the removal of “peaks” in the metal while leaving the cross hatch intact for oil retention. The plateaued finish increases the bearing area of the finish, and does not require the piston or ring to “break in” the cylinder walls.

See also

Notes

Look up honing (metalworking) in Wiktionary, the free dictionary.
  1. ^ a b Schibisch, Dirk M.; Friedrich, Uwe (2002). Superfinishing Technology. Germany: verlag moderne industrie. pp. 53–58. 
  2. ^ King, Robert C.; Hahn, Robert (1986). Handbook of modern grinding technology. New York: Chapman and Hall. pp. 301–336. ISBN 0-412-01081-X. 
  3. ^ a b Swigert Jr., Arthur M. (1940). The story of superfinish. Ann Arbor, MI: The Ann Arbor Press. pp. 575–594. OCLC 568009. 

This information originally retrieved from http://en.wikipedia.org/wiki/Honing_(metalworking)
on Tuesday 22nd November 2011 12:38 pm EST
Now edited and maintained by ManufacturingET.org

 Additional Resources

Meara, T. “New Honing Options for Hypereutectic Aluminum Cylinder Bores” 18 Sept. 2008. <http://www.mmsonline.com/articles/new-honing-options-for-hypereutectic-aluminum-cylinder-bores>

Gun Drilling
4:51 pm | November 17, 2011
Author: ManufacturingET.org | Category: Machining Manufacturing | Tags: , , | Comments: None
ManufacturingET.org > 2011 > November

 

A 12×640 mm gun drill and carbide tip of 25 mm drill.

Coolant holes in tip and base of gun drill.

Gun drills are straight fluted drills which allow cutting fluid (either compressed air or a suitable liquid) to be injected through the drill’s hollow body to the cutting face. They are used for deep drilling—a depth-to-diameter ratio of 300:1 or more is possible. Gun barrels are the obvious example; hence the name. Other uses include moldmaking, diemaking, and the manufacture of woodwind musical instruments, such as uilleann pipes, as gun drills can drill long straight holes in metal, wood, and some plastics. The coolant provides lubrication and cooling to the cutting edges and removes the swarf or chips from the hole. Modern gun drills use carbide tips to prolong life and reduce total cost when compared with metal tips. Speed of drilling depends on the material being drilled, rotational speed, and the drill diameter; a high speed drill can cut a hole in P20 steel at 30 inches per minute.

Contents

Requirement

With a standard twist drill, it is difficult to drill a straight and accurately sized hole of a depth more than about 5 times the diameter. This is a problem in many manufacturing processes, especially the firearms industry: the barrel of a gun must be very straight and accurately sized. Gun barrels are far longer than their inside diameter; as an example, the .223 inch (5.56 mm) caliber barrel of the M-16 rifle is 20 inches (508 mm) long, nearly 90 times the diameter of the bore. The gun drill was developed to drill such long, straight holes.

Gun drilling is possible over a range of depths and diameters. For diameters between 1-3mm, gun drilling can be performed successfully with special equipment. It is a common process between 3-50mm in diameter. It is also possible for the 50-75mm range, however less efficient than BTA deep hole drilling.[1]

Types

A gun drilling machine drilling holes in steel.

There are two basic types of gun drill: the internal chip removal type and the external chip removal type.

The internal type is basically a tube with a cutting bit on the front. Coolant is forced around the outside of the tube, and pours around the front of the drill, forcing the chips through the hole in the tip, up through the shaft, and out. This type is more common to BTA deep hole drilling.

The external chip removal bit has a notch cut in the outside of the drill tip. Coolant is forced down through the hollow shaft, and forces chips to exit along the notch. This type is more common in most gun drilling applications. These types of bits may also vary in the coolant hole. For maximum coolant flow, the drill will have a larger, kidney-shaped hole, or two round holes. Standard flow drills will simply have one round hole.

Related Videos

Eldorados Youtube Channel (several gun drilling videos)

References

  1. ^ What Is Gun Drilling?

Further reading

External links

v · d · eMetalworking
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Computer-aided engineering
Drilling and threading
Grinding and lapping
Machining and milling
Machine tooling
Terminology
Casting · Fabrication · Forming · Jewellery · Machining · Metallurgy · Smithing · Tools and terminology · Welding

This information originally retrieved from http://en.wikipedia.org/wiki/Gun_drill
on Thursday 17th November 2011 11:45 am EST
Now edited and maintained by ManufacturingET.org

 

 

Broaching
6:32 pm | November 10, 2011
Author: ManufacturingET.org | Category: Manufacturing | Tags: , | Comments: None
ManufacturingET.org > 2011 > November

 

A push style 516 inches (8 mm) keyway broach; note how the teeth are larger on the left end.

A broached keyway in the end of an adjustable wrench.

Broaching is a machining process that uses a toothed tool, called a broach, to remove material. There are two main types of broaching: linear and rotary. In linear broaching, which is the more common process, the broach is run linearly against a surface of the workpiece to effect the cut. Linear broaches are used in a broaching machine, which is also sometimes shortened to broach. In rotary broaching, the broach is rotated and pressed into the workpiece to cut an axis symmetric shape. A rotary broach is used in a lathe or screw machine. In both processes the cut is performed in one pass of the broach, which makes it very efficient.

Broaching is used when precision machining is required, especially for odd shapes. Commonly machined surfaces include circular and non-circular holes, splines, keyways, and flat surfaces. Typical workpieces include small to medium sized castings, forgings, screw machine parts, and stampings. Even though broaches can be expensive, broaching is usually favored over other processes when used for high-quantity production runs.[1]

Broaches are shaped similar to a saw, except the teeth height increases over the length of the tool. Moreover, the broach contains three distinct sections: one for roughing, another for semi-finishing, and the final one for finishing. Broaching is an unusual machining process because it has the feed built into the tool. The profile of the machined surface is always the inverse of the profile of the broach. The rise per tooth (RPT), also known as the step or feed per tooth, determines the amount of material removed and the size of the chip. The broach can be moved relative to the workpiece or vice-versa. Because all of the features are built into the broach no complex motion or skilled labor is required to use it.[2] A broach is effectively a collection of single-point cutting tools arrayed in sequence, cutting one after the other; its cut is analogous to multiple passes of a shaper.

Contents

Process

The process depends on the type of broaching being performed. Surface broaching is very simple as either the workpiece is moved against a stationary surface broach, or the workpiece is held stationary while the broach is moved against it. Internal broaching is more involved. The process begins by clamping the workpiece into a special holding fixture, called a workholder, which mounts in the broaching machine. The broaching machine elevator, which is the part of the machine that moves the broach above the workholder, then lowers the broach through the workpiece. Once through, the broaching machine’s puller, essentially a hook, grabs the pilot of the broach. The elevator then releases the top of the pilot and the puller pulls the broach through the workpiece completely. The workpiece is then removed from the machine and the broach is raised back up to reengage with the elevator.[3] The broach usually only moves linearly, but sometimes it is also rotated to create a spiral spline or gun-barrel rifling.[4]

Cutting fluids are used for three reasons. First, to cool the workpiece and broach. Second, to lubricate cutting surfaces. Third, to flush the chips from the teeth. Fortified petroleum cutting fluids are the most common, however heavy duty water soluble cutting fluids are being used because of their superior cooling, cleanliness, and non-flammability.[5]

Usage

An example of a broached workpiece. Here the broaching profile is a spline.

Broaching was originally developed for machining internal keyways. However, it was soon discovered that broaching is very useful for machining other surfaces and shapes for high volume workpieces. Because each broach is specialized to cut just one shape either the broach must be specially designed for the geometry of the workpiece or the workpiece must be designed around a standard broach geometry. A customized broach is usually only viable with high volume workpieces, because the broach can cost $15,000 USD to $30,000 USD to produce.[6]

Broaching speeds vary from 20 to 120 surface feet per minute (SFPM). This results in a complete cycle time of 5 to 30 seconds. Most of the time is consumed by the return stroke, broach handling, and workpiece loading and unloading.[7]

The only limitations on broaching are that there are no obstructions over the length of the surface to be machined, the geometry to be cut does not have curves in multiple planes,[8] and that the workpiece is strong enough to withstand the forces involved. Specifically for internal broaching a hole must first exist in the workpiece so the broach can enter.[9] Also, there are limits on the size of internal cuts. Common internal holes can range from 0.125 to 6 in (3.2 to 150 mm) in diameter but it is possible to achieve a range of 0.05 to 13 in (1.3 to 330 mm). Surface broaches’ range is usually 0.075 to 10 in (1.9 to 250 mm), although the feasible range is 0.02 to 20 in (0.51 to 510 mm).[10]

Tolerances are usually ±0.002 in (±0.05 mm), but in precise applications a tolerance of ±0.0005 in (±0.01 mm) can be held. Surface finishes are usually between 16 and 63 microinches (μin), but can range from 8 to 125 μin.[10] There may be minimal burrs on the exit side of the cut.[7]

Broaching works best on softer materials, such as brass, bronze, copper alloys, aluminium, graphite, hard rubbers, wood, composites, and plastic. However, it still has a good machinability rating on mild steels and free machining steels. When broaching, the machinability rating is closely related to the hardness of the material. For steels the ideal hardness range is between 16 and 24 Rockwell C (HRC); a hardness greater than HRC 35 will dull the broach quickly. Broaching is more difficult on harder materials, stainless steel and titanium,[11] but is still possible.[8][12]

Types

Broach types and examples.jpg

Broaches can be categorized by many means:[4]

  • Use:[8] internal, or surface
  • Purpose: single, or combination
  • Motion: push, pull, or stationary
  • Construction: solid, built-up, hollow or shell
  • Function: roughing, sizing, or burnishing

If the broach is large enough the costs can be reduced by using a built-up or modular construction. This involves producing the broach in pieces and assembling it. If any portion wears out only that section has to be replaced, instead of the entire broach.[13]

Most broaches are made from high speed steel (HSS) or an alloy steel; TiN coatings are common on HSS to prolong life. Except when broaching cast iron, tungsten carbide is rarely used as a tooth material because the cutting edge will crack on the first pass.[13]

Surface broaches

The slab broach is the simplest surface broach. It is a general purpose tool for cutting flat surfaces.[8]

Slot broaches (G & H) are for cutting slots of various dimensions at high production rates. Slot broaching is much quicker than milling when more than one slot needs to be machined, because multiple broaches can be run through the part at the same time on the same broaching machine.[8]

Contour broaches are designed to cut concave, convex, cam-, contoured, and irregular shaped surfaces.[8]

Pot broaches are cut the inverse of an internal broach; they cut the outside diameter of a cylindrical workpiece. They are named after the pot looking fixture in which the broaches are mounted; the fixture is often referred to as a “pot”. The pot is designed to hold multiple broaching tools concentrically over its entire length. The broach is held stationary while the workpiece is pushed or pulled through it.[14] This has replaced hobbing for some involute gears and cutting external splines and slots.[8]

Straddle broaches use two slab broaches to cut parallel surfaces on opposite sides of a workpiece in one pass. This type of broaching holds closer tolerances than if the two cuts were done independently.[8] It is named after the fact that the broaches “straddle” the workpiece on multiple sides.[14]

Internal broaches

A modular broach

Solid broaches are the most common type; they are made from one solid piece of material. For broaches that wear out quickly shell broaches are used; these broaches are similar to a solid broach, except there is a hole through the center where it mounts on an arbor. Shell broaches cost more initially, but save cost overall if the broach must be replaced often because the pilots are on the mandrel and do not have to be reproduced with each replacement.[13]

Modular broaches are commonly used for large internal broaching applications. They are similar to shell broaches in that they are a multi-piece construction. This design is used because it is cheaper to build and resharpen and is more flexible than a solid design.[13]

A common type of internal broach is the keyway broach (C & D). It uses a special fixture called a horn to support the broach and properly locate the part with relations to the broach.[8]

A concentricity broach is a special type of spline cutting broach which cuts both the minor diameter and the spline form to ensure precise concentricity.[8]

The cut-and-recut broach is used to cut thin-walled workpieces. Thin-walled workpieces have a tendency to expand during cutting and then shrink afterward. This broach overcomes that problem by first broaching with the standard roughing teeth, followed by a “breathing” section, which serves as a pilot as the workpiece shrinks. The teeth after the “breathing” section then include roughing, semi-finishing, and finishing teeth.[15]

  • An internal broach for cutting splines

  • The finishing teeth

  • The semi-finishing teeth

  • The roughing teeth

  • The front pilot

  • The slot in the tip of the broach where the broaching machine latches on to the broach to pull it through the workpiece

Design

For defining the geometry of a broach an internal type is shown below. Note that the geometry of other broaches are similar.

Broach geometry.png Broach tooth geometry.svg

where:

  • P = pitch
  • RPT = rise per tooth
  • nr = number of roughing teeth
  • ns = number of semi-finishing teeth
  • nf = number of finishing teeth
  • tr = RPT for the roughing teeth
  • ts = RPT for the semi-finishing teeth
  • tf = RPT for the finishing teeth
  • Ls = Shank length
  • LRP = Rear pilot length
  • D1 = Diameter of the tooth tip
  • D2 = Diameter of the tooth root
  • D = Depth of a tooth (0.4P)
  • L = Land (behind the cutting edge) (0.25P)
  • R = Radius of the gullet (0.25P)
  • α = Hook angle or rake angle
  • γ = Back-off angle or clearance angle
  • Lw = Length of the workpiece (not shown)

A progressive surface broach

The most important characteristic of a broach is the rise per tooth (RPT), which is how much material is removed by each tooth. The RPT varies for each section of the broach, which are the roughing section (tr), semi-finishing section (ts), and finishing section (tf). The roughing teeth remove most of the material so the number of roughing teeth required dictates how long the broach is.[16] The semi-finishing teeth provide surface finish and the finishing teeth provide the final finishing. The finishing section’s RPT (tf) is usually zero so that as the first finishing teeth wear the later ones continue the sizing function. For free-machining steels the RPT ranges from 0.006 to 0.001 in (0.15 to 0.025 mm). For surface broaching the RPT is usually between 0.003 to 0.006 in (0.076 to 0.15 mm) and for diameter broaching is usually between 0.0012 to 0.0025 in (0.030 to 0.064 mm). The exact value depends on many factors. If the cut is too big it will impart too much stress into the teeth and the workpiece; if the cut is too small the teeth rub instead of cutting. One way to increase the RPT while keeping the stresses down is with chip breakers. They are notches in the teeth designed to break the chip and decrease the overall amount of material being removed by any given tooth (see the drawing above).[4] For broaching to be effective, the workpiece should have 0.020 to 0.025 in (0.51 to 0.64 mm) more material than the final dimension of the cut.[7]

The hook (α) angle is a parameter of the material being cut. For steel, it is between 15 and 20° and for cast iron it is between 6 and 8°. The back-off (γ) provides clearance for the teeth so that they don’t rub on the workpiece; it is usually between 1 and 3°.[4]

When radially broaching a workpieces that require a deep cut per tooth, such as forgings or castings, a rotor-cut or jump-cut design can be used; these broaches are also known as free egress or nibbling broaches.[8] In this design the RPT is designated to two or three rows of teeth. For the broach to work the first tooth of that cluster has a wide notch, or undercut, and then the next tooth has a smaller notch (in a three tooth design) and the final tooth has no notch. This allows for a deep cut while keeping stresses, forces, and power requirements low.[4]

There are two different options for achieving the same goal when broaching a flat surface. The first is similar to the rotor-cut design, which is known as a double-cut design. Here four teeth in a row have the same RPT, but each progressive tooth takes only a portion of the cut due to notches in the teeth (see the image gallery below). The other option is known as a progressive broach, which completely machines the center of the workpiece and then the rest of the broach machines outward from there. All of these designs require a broach that is longer than if a standard design were used.[4]

For some circular broaches, burnishing teeth are provided instead of finishing teeth. They are not really teeth as they are just rounded discs that are 0.001 to 0.003 in (0.025 to 0.076 mm) over-sized. This results in burnishing the hole to the proper size. This is primarily used on non-ferrous and cast iron workpieces.[7]

The pitch defines the tooth construction, strength, and number of teeth in contact with the workpiece. The pitch is usually calculated from workpiece length, so that the broach can be designed to have at least two teeth in contact with the workpiece at any time; the pitch remains constant for all teeth of the broach. One way to calculate the pitch is:[16]

P \cong 0.35 \sqrt{L_\mathrm w}

  • Example of a double-cut surface broach

  • Top view of a double-cut surface broach

  • Side view of a double-cut surface broach

Broaching machines

The hydraulic cylinder of a horizontal broaching machine.

Broaching machines are relatively simple as they only have to move the broach in a linear motion at a predetermined speed and provide a means for handling the broach automatically. Most machines are hydraulic, but a few specialty machines are mechanically driven. The machines are distinguished by whether their motion is horizontal or vertical. The choice of machine is primarily dictated by the stroke required. Vertical broaching machines rarely have a stroke longer than 60 in (1.5 m).[17]

Vertical broaching machines can be designed for push broaching, pull-down broaching, pull-up broaching, or surface broaching. Push broaching machines are similar to an arbor press with a guided ram; typical capacities are 5 to 50 tons. The two ram pull-down machine is the most common type of broaching machine. This style machine has the rams under the table. Pull-up machines have the ram above the table; they usually have more than one ram.[18] Most surface broaching is done on a vertical machine.[8]

Horizontal broaching machines are designed for pull broaching, surface broaching, continuous broaching, and rotary broaching. Pull style machines are basically vertical machines laid on the side with a longer stroke. Surface style machines hold the broach stationary while the workpieces are clamped into fixtures that are mounted on a conveyor system. Continuous style machines are similar to the surface style machines except adapted for internal broaching.[18]

Horizontal machines used to be much more common than vertical machines, however today they represent just 10% of all broaching machines purchased. Vertical machines are more popular because they take up less space.[8]

Rotary broaching

Schematic of a rotary broach starting a cut.

θ Off-axis (wobble) angle
θr Rake
θf Front relief
dp Pilot diameter
w Width across corners (AC)

A somewhat different design of cutting tool that can achieve the irregular hole or outer profile of a broach is called a rotary broach or wobble broach. One of the biggest advantages to this type of broaching is that it does not require a broaching machine, but instead is used on lathes, milling machines[19], screw machines or Swiss lathes.[20]

Rotary broaching requires two tooling components: a tool holder and a broach. The leading (cutting) edge of the broach has a contour matching the desired final shape. The broach is mounted in a special tool holder that that allows it to freely rotate. The tool holder is special because it holds the tool so that its axis of rotation is inclined slightly to the axis of rotation of the work. A typical value for this misalignment is 1 degree. This angle is what produces a rotating edge for the broach to cut the workpiece. Either the workpiece or the tool holder is rotated. If the tool holder is rotated, the misalignment causes the broach to appear as though it is “wobbling”, which is the origin of the term “wobble broach”.[20]

For internal broaching the sides of the broach are drafted inward so it becomes thinner; for external broaching the sides are drafted outward, to make the pocket bigger. This draft keeps the broach from jamming; the draft must be larger than the angle of misalignment. If the work piece rotates, the broach is pressed against it, is driven by it, and rotates synchronously with it. If the tool holder rotates, the broach is pressed against the workpiece, but is driven by the tool holder.[20]

Ideally the tool advances at the same rate that it cuts. The ideal rate of cut is defined as:[21]

Rate of cut [inches per rotation (IPR)] = (diameter of tool [inches]) × sin(Angle of misalignment [degrees])

If it advances much faster, then the tool becomes choked; conversely, if it advances much slower, then an interrupted or zig-zag cut occurs. In practice the rate of cut is slightly less than the ideal rate so that the load is released on the non-cutting edge of the tool.

There is some spiraling of the tool as it cuts, so the form at the bottom of the workpiece may be rotated with respect to the form at the top of the hole or profile. Spiraling may be undesirable because it binds the body of the tool and prevents it from cutting sharply. One solution to this is to reverse the rotation in mid cut, causing the tool to spiral in the opposite direction. If reversing the machine is not practical, then interrupting the cut is another possible solution.

In general, a rotary broach will not cut as accurately as a push or pull broach. However, the ability to use this type of cutting tool on common machine tools is highly advantageous.

History

The concept of broaching can be traced back to the early 1850s, with the first applications used for cutting keyways in pulleys and gears. After World War I, broaching was used to rifle gun barrels. In the 1920s and 30s the tolerances were tightened and the cost reduced thanks to advances in form grinding and broaching machines.[22]

References

  1. ^ Degarmo, Black & Kohser 2003, pp. 637–638.
  2. ^ Degarmo, Black & Kohser 2003, p. 638.
  3. ^ Degarmo, Black & Kohser 2003, pp. 644–645.
  4. ^ a b c d e f Degarmo, Black & Kohser 2003, p. 641.
  5. ^ AstroBroach Machines: Principles of Operation, Anderson Tool & Engineering Co., Inc., http://www.ateinc.com/astroBroach/PrinciplesOfOperation.html, retrieved 2009-04-12 .
  6. ^ Degarmo, Black & Kohser 2003, p. 640.
  7. ^ a b c d Degarmo, Black & Kohser 2003, p. 642.
  8. ^ a b c d e f g h i j k l m Van De Motter, Chris (February 2006),
    “The Basics of Broaching”
    , Gear Product News (1206): 27–30,
    http://www.gearproductnews.com/issues/0206/broaching_basics.pdf
     .
  9. ^ Degarmo, Black & Kohser 2003, pp. 640–641.
  10. ^ a b Todd, Allen & Alting 1994, p. 17.
  11. ^ Slater Tools: What materials can I broach?, Slater tools, archived from the original on 2010-06-08, http://www.webcitation.org/5qL3GIDl0, retrieved 2010-06-08. 
  12. ^ Todd, Allen & Alting 1994, p. 18.
  13. ^ a b c d Degarmo, Black & Kohser 2003, p. 643.
  14. ^ a b VW Broaching Services: Straddle & Pot Broaching, VW Broaching Services, Inc., archived from the original on 2010-06-08, http://www.webcitation.org/5qL3KIoML, retrieved 2009-04-12 .
  15. ^ Drozda 1983, pp. 7‐32.
  16. ^ a b Degarmo, Black & Kohser 2003, pp. 638–639.
  17. ^ Degarmo, Black & Kohser 2003, pp. 643–644.
  18. ^ a b Degarmo, Black & Kohser 2003, p. 644.
  19. ^ “Rotary Broaching on a Bridgeport” (in English) (Video). Polygon Solutions Inc. 15 December 2010. http://www.youtube.com/watch?v=uTsPXFy7Xx0. Retrieved 24 May 2011. 
  20. ^ a b c Bagwell, Peter; Tryles, Jeff (March 2006),
    “One-Pass Polygons”
    , Cutting Tool Engineering 58 (3),
    http://www.ctemag.com/pdf/2006/0603-Broaching.pdf
     .
  21. ^ Somma: Offset Rotating Broach, Somma Tool Company, Inc., http://www.sommatool.com/manuscripts/broaching.asp, retrieved 2010-06-08. 
  22. ^ Milling Operations – Broaching, http://its.foxvalleytech.com/MachShop3/broach/BroachingIS.htm, retrieved 2009-04-12 .

Bibliography

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This information originally retrieved from http://en.wikipedia.org/wiki/Broaching_(metalworking)
on Thursday 10th November 2011 1:31 pm EST
Now edited and maintained by ManufacturingET.org