Chuck (engineering)

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A chuck on a power drill, showing the teeth that engage with the key Chuck (PSF).jpg
A chuck on a power drill, showing the teeth that engage with the key

A chuck is a specialized type of clamp used to hold an object with radial symmetry, especially a cylinder. In a drill, a mill and a transmission, a chuck holds the rotating tool; in a lathe, it holds the rotating workpiece. [1]

Contents

Chucks commonly use jaws to hold the tool or workpiece. The jaws) are typically arranged in a radially symmetrical pattern like the points of a star. Jawed chucks may require a wrench-like device called a chuck key to be tightened or loosened, but other jawed chucks may be tightened or loosened by hand force alone, offering convenience at the expense of gripping force. Chucks on some lathes have jaws that move independently, allowing them to hold irregularly shaped objects. More complex designs might include specially shaped jaws, greater numbers of jaws, or quick-release mechanisms.

Instead of jaws, a chuck may use magnetism, vacuum, or collets, which are flexible collars or sleeves that fit closely around the tool or workpiece and grip it when squeezed.[ citation needed ]

Types

Self-centering three-jaw chuck and key with one jaw removed and inverted showing the teeth that engage in the scroll plate. The scroll plate is rotated within the chuck body by the key, the scroll engages the teeth on the underside of the jaws which moves the three jaws in unison, to tighten or release the workpiece. ThreeJawChuckKey.jpg
Self-centering three-jaw chuck and key with one jaw removed and inverted showing the teeth that engage in the scroll plate. The scroll plate is rotated within the chuck body by the key, the scroll engages the teeth on the underside of the jaws which moves the three jaws in unison, to tighten or release the workpiece.

Jawed chucks

Self-centering

A self-centering chuck, also known as a scroll chuck, [2] uses jaws, interconnected via a scroll gear (scroll plate), to hold onto a tool or workpiece. Because they most often have three jaws, the term three-jaw chuck without other qualification is understood by machinists to mean a self-centering three-jaw chuck. The term universal chuck also refers to this type. These chucks are best suited to grip circular or hexagonal cross-sections when very fast, reasonably accurate (±0.005 inch [0.125 mm] TIR) centering is desired.[ citation needed ]

Sometimes this type of chuck has four or six jaws instead of three. Four-jawed chucks are primarily useful for gripping square or octagon material, while six-jawed chucks hold thin-walled tubing and plastic materials with minimum distortion.[ citation needed ]

There are also independent-jaw (non-self-centering) chucks with three jaws, but they offer few advantages and are very rare.[ citation needed ]

There are hybrid self-centering chucks that have adjustment screws that can be used to further improve the concentricity after the workpiece has been gripped by the scroll jaws. This feature is meant to combine the speed and ease of the scroll plate's self-centering with the run-out eliminating controllability of an independent-jaw chuck. The most commonly used name for this type is a brand name, GripTru. To avoid undue genericization of that brand name, suggestions for a generic name have included "exact-adjust".[ citation needed ]

Three-jaw chucks are often used on lathes and indexing heads.

Drill chuck
Top: an assembled keyless chuck. This type of chuck is tightened by twisting the body using firm hand pressure only. While convenient, this feature can cause the chuck to tighten too much when high torque is applied. Bottom: the widely used keyed type of drill chuck with its key. The arbor is shown separately to the right. These chucks require a toothed key to provide the necessary torque to tighten and loosen the jaws. When the key is turned its teeth mate with teeth on the chuck, turning an internal screw which in turn moves the threaded jaws in or out along a tapered surface. The taper allows the jaws to clamp drill shanks of a range of diameters. The end view shows the three small jaws that slide within the body. ChuckDrillKeyedKeylessArbor.jpg
Top: an assembled keyless chuck. This type of chuck is tightened by twisting the body using firm hand pressure only. While convenient, this feature can cause the chuck to tighten too much when high torque is applied. Bottom: the widely used keyed type of drill chuck with its key. The arbor is shown separately to the right. These chucks require a toothed key to provide the necessary torque to tighten and loosen the jaws. When the key is turned its teeth mate with teeth on the chuck, turning an internal screw which in turn moves the threaded jaws in or out along a tapered surface. The taper allows the jaws to clamp drill shanks of a range of diameters. The end view shows the three small jaws that slide within the body.
Two pin chucks. The top one is assembled, the lower one shows the body and nose cap assembled with the collet piece below it. PinChucks.jpg
Two pin chucks. The top one is assembled, the lower one shows the body and nose cap assembled with the collet piece below it.

A drill chuck is a specialised self-centering, three-jaw chuck, usually with capacity of 0.5 in (13 mm) or less, and rarely greater than 1 in (25 mm), used to hold drill bits or other rotary tools. This type of chuck is used on tools ranging from professional equipment to inexpensive hand and power drills for domestic use.

Some high-precision chucks use ball thrust bearings to reduce friction in the closing mechanism and maximize drilling torque. One brand name for this type of chuck, which is often genericized in colloquial use although not in catalogs, is Super Chuck.[ citation needed ]

A pin chuck is a specialized chuck designed to hold small drills (less than 1 mm (0.039 in) in diameter) that could not be held securely in a normal drill chuck. The drill is inserted into the pin chuck and tightened; the pin chuck has a shaft which is then inserted into the larger drill chuck to hold the drill securely. Pin chucks are also used with high-speed rotary tools other than drills, such as die grinders and jig grinders.

Independent-jaw

Independent four-jaw chuck, with the jaws independently set. The key is used to adjust each jaw separately. FourJawChuckIndependent.jpg
Independent four-jaw chuck, with the jaws independently set. The key is used to adjust each jaw separately.
An older and larger 4 jaw chuck. Note how it is able to grip an irregularly cut piece of used metal. Though not found on small chucks it is common for larger chucks (the one in the second photo was made around 1900 and is 24" in diameter) to have many of the features of a faceplate. The jaws are stepped on one side and full height for gripping on the other and are reversible. Generally the jaws are usable for holding either outside as shown here, or inside as in gripping the inside of a pipe. Old4jaw.jpg
An older and larger 4 jaw chuck. Note how it is able to grip an irregularly cut piece of used metal. Though not found on small chucks it is common for larger chucks (the one in the second photo was made around 1900 and is 24" in diameter) to have many of the features of a faceplate. The jaws are stepped on one side and full height for gripping on the other and are reversible. Generally the jaws are usable for holding either outside as shown here, or inside as in gripping the inside of a pipe.

On an independent-jaw chuck, each jaw can be moved independently. Because they most often have four jaws, the term four-jaw chuck without other qualification is understood by machinists to mean a chuck with four independent jaws. The independence of the jaws makes these chucks ideal for (a) gripping non-circular cross sections and (b) gripping circular cross sections with extreme precision (when the last few hundredths of a millimeter [or thousandths of an inch] of runout must be manually eliminated). The non-self-centering action of the independent jaws makes centering highly controllable (for an experienced user), but at the expense of speed and ease. Four-jaw chucks are almost never used for tool holding. Four-jaw chucks can be found on lathes and indexing heads.

Self-centering chucks with four jaws also can be obtained. Although these are often said to suffer from two disadvantages: inability to hold hex stock, and poor gripping on stock which is oval, only the latter is true. Even with three jaw self centering chucks, work which is not of uniform section along the work (and which is not free of spiral or 'wind') should not be gripped, as the jaws can be strained and the accuracy permanently impaired.

Four-jaw chucks can easily hold a workpiece eccentrically if eccentric features need to be machined.

Cat's Paw

A "cat's paw" is a simple, relatively inexpensive, limited-capability version of an independent-jaw chuck. It typically consists of a ring of metal with screw threads tapped radially into it, in which screws (hex cap, socket hex cap, or set screws) serve as independent jaws. Cat's paws can serve various purposes:

  • As auxiliary features that complement the main lathe chuck:
    • To hold the bar or workpiece at the back end of the spindle bore and support it concentrically, so that it resists wobbling or whipping while the spindle is turning. Gun barrels and oil pipes are examples of workpieces that benefit.
    • To hold the bar or workpiece at the tailstock end (thus serving as a steady rest) or following the tool (thus serving as a follower rest).
  • In place of the main lathe chuck (for particular workpieces that can benefit—for example, in some gunsmithing work)

Specialty jawed types (two-, six-, eight-jaw; other)

Chuck with six jaws Lathe Chuck.jpg
Chuck with six jaws

For special purposes, chucks are available with six or eight jaws. These are usually of the self-centering design, and may be built to very high standards of accuracy. However, it is a misconception that such chucks necessarily offer more precision in holding solid workpieces than conventional three-jawed self-centering chucks. Indeed, hot-rolled or other imperfectly round workpieces may "teeter" insecurely between opposing jaws of scroll chucks having even numbers of jaws, in the same manner that a four-legged stool teeters on a rough floor while a three-legged stool never does. The primary purpose of six- and eight-jawed chucks is to hold thin-walled tubing with minimum deformation. By having twice as many clamping points, a six-jaw chuck induces less than half as much clamping distortion in a thin-walled workpiece, compared to a three-jawed chuck.

Two-jaw chucks are available and can be used with soft jaws (typically an aluminium alloy) that can be machined to conform to a particular workpiece. It is a short conceptual leap from these to faceplates holding custom fixtures, wherein the part is located against fixed stops and held there with toggle clamps or toe clamps.

Jaw construction

Many chucks have removable jaws (often the top part is removable leaving the base or 'master jaw' assembled with the scroll), which allows the user to replace them with new jaws, specialised jaws, or soft jaws. Soft jaws are made of soft materials such as soft (unhardened) metal, plastic, or wood. They can be machined as needed for particular setups. The typical interface between the master jaw and the removable jaw is a matching pair of serrated surfaces, which, once clamped by the mounting screws, cannot allow relative slipping between the two parts.

Collet

A collet, one type of chuck, is a sleeve with a (normally) cylindrical inner surface and a conical outer surface. The collet can be squeezed against a matching taper such that its inner surface contracts to a slightly smaller diameter, squeezing the tool or workpiece whose secure holding is desired. Most often this is achieved with a spring collet, made of spring steel, with one or more kerf cuts along its length to allow it to expand and contract. An alternative collet design is one that has several tapered steel blocks (essentially tapered gauge blocks) held in circular position (like the points of a star, or indeed the jaws of a jawed chuck) by a flexible binding medium (typically synthetic or natural rubber). The Jacobs Rubber-Flex brand is a name that most machinists would recognize for this type of collet chuck system.

Regardless of the collet design, the operating principle is the same: squeeze the collet radially against the tool or workpiece to be held, resulting in high static friction. Under correct conditions, it holds quite securely. Almost all collet chucks achieve the radial squeezing motion via moving one or more male-female pairs of tapered (conical) surfaces axially, which produces the radial squeezing in a highly concentric manner. Depending on the collet design, it can be either pulled (via a threaded section at the rear of the collet) or pushed (via a threaded cap with a second taper) into a matching conical socket to achieve the clamping action. As the collet is forced into the tapered socket, the collet will contract, gripping the contents of the inner cylinder. (The axial movement of cones is not mandatory, however; a split bushing squeezed radially with a linear force—e.g., set screw, solenoid, spring clamp, pneumatic or hydraulic cylinder—achieves the same principle without the cones; but concentricity can only be had to the extent that the bushing's diameters are perfect for the particular object being held. Thus only in toolroom contexts, such as machine tool tooling creation and setup, is this common.)

One of the corollaries of the conical action is that collets may draw the work axially a slight amount as they close. Collet chuck systems that make no provision to prevent this draw-in are often called draw-in collet chucks, in contrast to systems which circumvent this movement, usually by pushing the tapered closing ring toward the collet rather than pulling the collet into the ring. Such non-draw-in types are often called "dead-length" or "non-draw-in" collet chucks. Draw-in is not always a problem, but avoiding it can be helpful on some work where failing to account for it might result in inaccuracy on part overall length, shoulder lengths, etc.

Collets are most commonly found on milling machines, lathes, wood routers, precision grinders, and certain handheld power tools such as die grinders and rotary tools. There are many different systems, common examples being the ER, 5C, and R8 systems. Collets can also be obtained to fit Morse or Brown and Sharpe taper sockets.

Typically collets offer higher levels of precision and accuracy than self-centering chucks, and have a shorter setting up time than independent-jaw chucks. The penalty is that most collets can only accommodate a single size of workpiece. An exception is the ER collet which typically has a working range of 1 mm (about 0.04 in).

Collets usually are made to hold cylindrical work, but are available to hold square, hexagonal or octagonal workpieces. While most collets are hardened, "emergency" collets are available that can be machined to special sizes or shapes by the user. These collets can be obtained in steel, brass, or nylon. Step collets are available that are machinable to allow holding of short workpieces that are larger than the capacity of normal collets.

Special Direct System (SDS)

Diagram of an SDS chuck Special-Direct-System-chuck.png
Diagram of an SDS chuck

Developed by Bosch in 1975 for hammer drills, the SDS System uses an SDS Shank which is a cylindrical shank with indentations to be held by the chuck. [3] A tool is inserted into the chuck, and is locked in place until the lock is released. The rotary force is transmitted through wedges that fit into two or three open grooves. The bit is free to move a short distance and the hammer action moves the bit up and down within the chuck. Two sprung balls fit into closed grooves, allowing movement whilst retaining the bit. There are four standard sizes with varying shank diameters:

SDS Quick
A 6 mm shank with two open grooves interacting with the driving wedges and two closed grooves held by locking balls. This is the newest size introduced in 2011 for the Bosch Uneo series and takes concrete drills up to 10 mm diameter. [4]

SDS-Plus

A 10 mm shank with two open grooves interacting with the driving wedges and two closed grooves held by locking balls. This is the most common size and takes a hammer up to 4 kg. The wedges grip an area of 75 mm2 (0.116 sq in) and the shank is inserted 40 mm into the chuck.
SDS-top
A 14 mm shank similar to SDS-plus, designed for hammers from 2 to 5 kg. The grip area is increased to 212 mm2 (0.329 sq in) and the shank is inserted 70 mm. This size remained uncommon and was discontinued in 2009. [5]
SDS-max
An 18 mm shank with three open grooves and locking segments rather than balls. It is designed for hammers over 5 kg. The wedges grip an area of 389 mm2 (0.603 sq in) and the shank is inserted 90 mm. [6]

Many SDS drills have a "rotation off" setting, which allows the drill to be used for chiselling. The name SDS comes from the German Steck-Dreh-Sitz (insert-drill-attachment). In German-speaking countries the acronym Spannen durch System (Clamping System) was also used, though Bosch now uses Special Direct System internationally. [7]

Chucks with both indexable positioning and indexable clamping

Commercial production machining now makes use of increasingly advanced chucks which have not only indexable positioning but also indexable clamping. [8] Both functions are typically hydraulically controlled. The clamping is often done with each pair of jaws consisting of one fixed jaw and one movable jaw (hydraulically actuated), thematically similar to advanced milling vises. This method of clamping brings the high precision and repeatability of such vises to a chucking application. Such chucks offer the centering precision of traditional independent-jaw chucks with the chucking speed and ease of traditional three-jaw self-centering scroll chucks. They have expensive initial cost (compared with traditional chucks), but such initial cost pays for itself and then lowers ongoing marginal costs in commercial production-run environments.

It is also possible nowadays to build CNC chucks in which the position and clamping pressure of each jaw can be precisely controlled with CNC, via closed-loop positioning and load monitoring. In essence, each jaw is one independent CNC axis, a machine slide with a leadscrew, and all four or six of them can act in concert with each other. Although this idea is conceptually interesting, the simpler chucking systems mentioned in the previous paragraph are probably a marketplace winner over this alternative for most applications, because they supply the same capabilities via a simpler, less expensive solution.

Magnetic

Used for holding ferromagnetic workpieces, a magnetic chuck consists of an accurately centred permanent magnet face. Electromagnets or permanent magnets are brought into contact with fixed ferrous plates, or pole pieces, contained within a housing. These pole pieces are usually flush with the housing surface. The part (workpiece) to be held forms the closing of the magnetic loop or path, onto those fixed plates, providing a secure anchor for the workpiece.

Electrostatic

Commonly used for holding silicon wafers during lithography processes, an electrostatic chuck comprises a metal base-plate and a thin dielectric layer; the metal base-plate is maintained at a high-voltage relative to the wafer, and so an electrostatic force clamps the wafer to it. Electrostatic chucks may have pins, or mesas, the height of which is included in the reported dielectric thickness; a design by Sandia National Laboratory uses a patterned silicon-dioxide dielectric to form the pins. [9]

Vacuum

A vacuum chuck is primarily used on non-ferrous materials, such as copper, bronze, aluminium, titanium, plastics, and stone. In a vacuum chuck, air is pumped from a cavity behind the workpiece, and atmospheric pressure provides the holding force. Vacuum produces a hold down pressure of 14.7 psi (101 kPa) at sea level, decreasing at higher elevations where the atmospheric pressure is lower. The decrease in holding pressure is roughly 0.5 psi per 1000' above sea level.[ citation needed ]

Mounting methods

Connecting chucks to the spindles or tables of machine tools or power tools has been accomplished in many ways over the years.

Mounting of drill chucks

Mounting of large jawed chucks

Taper spindle nose with threaded retention. The retainer ring is wrenched with a spanner wrench. Taper spindle nose with threaded retention.jpg
Taper spindle nose with threaded retention. The retainer ring is wrenched with a spanner wrench.

Mounting of collet chucks

History

The Jacobs type chuck, with three converging splines or jaws, is perhaps the most usual design. This one is tightened with a key, but some types may be sufficiently tightened by hand Jacobs Chuck.png
The Jacobs type chuck, with three converging splines or jaws, is perhaps the most usual design. This one is tightened with a key, but some types may be sufficiently tightened by hand

The original forms of workholding on lathes were between-centers holding and ad hoc fastenings to the headstock spindle.[ clarification needed ] The spike-style centers still used on wood lathes represent an ancient method. Ad hoc fastening methods in centuries past included anything from pinning with clenching or wedging; nailing; lashing with cords of leather or fiber; dogging down (again involving pinning/wedging/clenching); or other types. Faceplates have probably been around at least since the era of medieval clock-makers.

Tooling similar to today's chucks seems likely to have evolved from faceplate work, as workers using faceplates for repetitive work began to envision types of clamps or dogs for the faceplate that could be opened and closed in more convenient ways than repeated total disassembly and reassembly. A chock was originally just a lump of wood. However, by 1703 it could be "... Chocks, belonging to the Screw-Mandrel". [10] By 1807 the word had changed to the more familiar 'chuck: "On the end of the spindle ... is screwed ... a universal Chuck for holding any kind of work". [11]

In late 1818 or early 1819 the Society for the Encouragement of Arts, Manufactures and Commerce awarded its silver medal and 10 guineas (£10.50 – equivalent to £1,006in 2023 [12] ) to Mr. Alexander Bell for a three jaw lathe chuck:

The instrument can be screwed into ... the mandrel of a lathe, and has three studs projecting from its flat surface, forming an equi-lateral triangle, and are capable of being moved equably to, or from, its centre.

It is not clear how they were moved "equably" whether by a scroll or some other means. [13] Later in 1819 the same body awarded a further silver medal to Mr. T. Hack for a four jaw chuck. [14] In the United States Simon Fairman (1792–1857) developed a recognisable modern scroll chuck as used on lathes. [15] The patent refers to the technicalities of assembly, he does not claim invention of the scroll ("convolute grooves"). [16] His son-in-law Austin F. Cushman (1830–1914) developed the ideas and sold chucks through his business, Cushman Industries. [17]

Jacobs Chuck

Arthur Irving Jacobs (1858-1918) Arthur Irving Jacobs.png
Arthur Irving Jacobs (1858–1918)

At the start of the 20th century, Arthur Irving Jacobs developed the modern drill chuck. After bruising his knuckles on one of the old-fashioned spanner adjusted drill chucks, he developed a chuck in which the jaws moved axially in inclined slots. His patent of 1902 details the mechanism. [18] The term drill chuck clearly did not originate with him, but his new type of drill chuck long ago displaced any earlier types that lacked the angled jaw movement and outer sleeve now found on all common drill chucks.

Performance evaluation

National and international standards are used to standardize the definitions, requirements, and test methods used for the performance evaluation of chucks. Selection of the standard to be used is an agreement between the supplier and the user and has some significance in the design of the chuck. In the United States, ASME has developed the B5.60 Standard entitled Workholding Chucks: Jaw-Type Chucks, which establishes requirements and methods for specifying and testing the performance of workholding chucks used primarily in turning operations. [19]

See also

Related Research Articles

<span class="mw-page-title-main">Lathe</span> Machine tool which rotates the work piece on its axis

A lathe is a machine tool that rotates a workpiece about an axis of rotation to perform various operations such as cutting, sanding, knurling, drilling, deformation, facing, threading and turning, with tools that are applied to the workpiece to create an object with symmetry about that axis.

<span class="mw-page-title-main">Drill</span> Tool used to create holes

A drill is a tool used for making round holes or driving fasteners. It is fitted with a bit, either a drill or driver chuck. Hand-operated types are dramatically decreasing in popularity and cordless battery-powered ones proliferating due to increased efficiency and ease of use.

<span class="mw-page-title-main">Drill bit</span> Type of cutting tool

A drill bit is a cutting tool used in a drill to remove material to create holes, almost always of circular cross-section. Drill bits come in many sizes and shapes and can create different kinds of holes in many different materials. In order to create holes drill bits are usually attached to a drill, which powers them to cut through the workpiece, typically by rotation. The drill will grasp the upper end of a bit called the shank in the chuck.

A reamer is a type of rotary cutting tool used in metalworking. Precision reamers are designed to enlarge the size of a previously formed hole by a small amount but with a high degree of accuracy to leave smooth sides. There are also non-precision reamers which are used for more basic enlargement of holes or for removing burrs. The process of enlarging the hole is called reaming. There are many different types of reamer and they may be designed for use as a hand tool or in a machine tool, such as a milling machine or drill press.

<span class="mw-page-title-main">Mandrel</span> Gently tapered cylinder against which material can be forged or shaped

A mandrel, mandril, or arbor is a tapered tool against which material can be forged, pressed, stretched or shaped, or a flanged or tapered or threaded bar that grips a workpiece to be machined in a lathe. A flanged mandrel is a parallel bar of a specific diameter with an integral flange towards one end, and threaded at the opposite end. Work is gripped between the flange and a nut on the thread. A tapered mandrel has a taper of approximately 0.005 inches per foot and is designed to hold work by being driven into an accurate hole on the work, gripping the work by friction. A threaded mandrel may have a male or female thread, and work which has an opposing thread is screwed onto the mandrel.

<span class="mw-page-title-main">Collet</span> Type of chuck

A collet is a segmented sleeve, band or collar. One of the two radial surfaces of a collet is usually tapered and the other is cylindrical. The term collet commonly refers to a type of chuck that uses collets to hold either a workpiece or a tool, but collets have other mechanical applications.

<span class="mw-page-title-main">Machine taper</span> System for securing cutting tools or toolholders in a spindle

A machine taper is a system for securing cutting tools or toolholders in the spindle of a machine tool or power tool. A male member of conical form fits into the female socket, which has a matching taper of equal angle.

<span class="mw-page-title-main">Turning</span> Machining process

Turning is a machining process in which a cutting tool, typically a non-rotary tool bit, describes a helix toolpath by moving more or less linearly while the workpiece rotates.

The shank is the end of a drill bit grasped by the chuck of a drill. The cutting edges of the drill bit contact the workpiece, and are connected via the shaft with the shank, which fits into the chuck. In many cases a general-purpose arrangement is used, such as a bit with cylindrical shaft and shank in a three-jaw chuck which grips a cylindrical shank tightly. Different shank and chuck combination can deliver improved performance, such as allowing higher torque, greater centering accuracy, or moving the bit independently of the chuck, with a hammer action.

Milling cutters are cutting tools typically used in milling machines or machining centres to perform milling operations. They remove material by their movement within the machine or directly from the cutter's shape.

<span class="mw-page-title-main">Vise</span> Apparatus for securing a workpiece

A vise or vice is a mechanical apparatus used to secure an object to allow work to be performed on it. Vises have two parallel jaws, one fixed and the other movable, threaded in and out by a screw and lever. The jaws are often flat but may have grooves, adapt to the shape of the workpiece or be custom made.

<span class="mw-page-title-main">Lathe center</span>

A lathe center, often shortened to center, is a tool that has been ground to a point to accurately position a workpiece on an axis. They usually have an included angle of 60°, but in heavy machining situations an angle of 75° is used.

<span class="mw-page-title-main">Lathe dog</span> Mechanical component of a lathe

A lathe dog is a mechanical device typically made of cast iron, steel or aluminum that transmits rotary motion from a faceplate to a workpiece mounted between centers in a lathe. The tail of the dog is rotated by a slot in a driving faceplate, a stud mounted on a faceplate, or sometimes a side of a chuck jaw. The workpiece passes through an aperture in the dog into which the work is secured by one or more setscrews or a clamp arrangement. The maximum cross sectional dimension of the workpiece is limited by the dimensions of the dog aperture. Lathe dogs are provided in straight tail or bent tail form, and may be single tail or double tail. A lathe dog designed to hold square, rectangular or odd-shaped work and having a moveable portion secured typically by two cap screws is called a clamp dog. Bent tail dogs are able to engage directly with a driving faceplate slot or a chuck jaw but can crowd work off centre if clearance is not present between the dog tail and a closed end of the faceplate slot. Straight tail dogs do not present the issue of crowding work off centre but require at least one driving stud to be mounted on the faceplate. If the rotating mass of the dog setup is not balanced, eccentric motion of the work may occur. Counterbalancing or reduced spindle speed may be required. Care must be taken by the operator when using lathe dogs, as it is easy to get snagged on one. Use of headless setscrews, preferably of multiple-spline drive design, that do not protrude above the outer surface of the dog is recommended. A lathe dog may also be used with some indexing heads and other tools with similar faceplates that turn about a center.

<span class="mw-page-title-main">Metal lathe</span> Machine tool used to remove material from a rotating workpiece

In machining, a metal lathe or metalworking lathe is a large class of lathes designed for precisely machining relatively hard materials. They were originally designed to machine metals; however, with the advent of plastics and other materials, and with their inherent versatility, they are used in a wide range of applications, and a broad range of materials. In machining jargon, where the larger context is already understood, they are usually simply called lathes, or else referred to by more-specific subtype names. These rigid machine tools remove material from a rotating workpiece via the movements of various cutting tools, such as tool bits and drill bits.

<span class="mw-page-title-main">Lathe faceplate</span> Workholding accessory

A lathe faceplate is a basic workholding accessory for a wood or metal turning lathe. It is a circular metal plate which fixes to the end of the lathe spindle. The workpiece is then clamped to the faceplate, typically using t-slot nuts in slots in the faceplate, or less commonly threaded holes in the faceplate itself.

<span class="mw-page-title-main">Boring (manufacturing)</span> Process of enlarging an already-drilled hole with a single-point cutting tool

In machining, boring is the process of enlarging a hole that has already been drilled by means of a single-point cutting tool, such as in boring a gun barrel or an engine cylinder. Boring is used to achieve greater accuracy of the diameter of a hole, and can be used to cut a tapered hole. Boring can be viewed as the internal-diameter counterpart to turning, which cuts external diameters.

<span class="mw-page-title-main">Grinding (abrasive cutting)</span> Machining process using a grinding wheel

Grinding is a type of abrasive machining process which uses a grinding wheel as cutting tool.

In manufacturing, threading is the process of creating a screw thread. More screw threads are produced each year than any other machine element. There are many methods of generating threads, including subtractive methods ; deformative or transformative methods ; additive methods ; or combinations thereof.

<span class="mw-page-title-main">Automatic lathe</span>

In metalworking and woodworking, an automatic lathe is a lathe with an automatically controlled cutting process. Automatic lathes were first developed in the 1870s and were mechanically controlled. From the advent of NC and CNC in the 1950s, the term automatic lathe has generally been used for only mechanically controlled lathes, although some manufacturers market Swiss-type CNC lathes as 'automatic'.

ASME B5 refers to a technical committee of the American Society of Mechanical Engineers and the standard they maintain which deals with machine tools.

References

  1. "Development of a Specialized Lathe Chuck for Turning Operations of Cast Iron Rope Wheels".
  2. Cubberly, W. (1989). Tool and Manufacturing Engineers Handbook. Society of Manufacturing Engineers. p. 23-16. ISBN   978-0-87263-351-3.
  3. US 4123074,Wanner, Karl,"Tool shank and chuck combination for a hammer drill",published 1978-10-31, assigned to Robert Bosch GmbH
  4. "Uneo Maxx Batteridrevet borhammer | Bosch DIY". Verktøy for Hjem og Hage (in Norwegian). Retrieved February 21, 2021.
  5. "SDS-top". Encyclopedia of technical terms (A-Z). Archived from the original on January 16, 2005. Retrieved April 12, 2006.
  6. "SDS-max". Encyclopedia of technical terms (A-Z). Archived from the original on January 16, 2005. Retrieved April 12, 2006.
  7. "SDS". Lexikon der Elektrowerkzeuge. Archived from the original on June 26, 2006. Retrieved April 12, 2006. (German language)
  8. Brown 2011.
  9. Lab News. "Electrostatic chuck". Sandia.gov. Retrieved January 13, 2010.
  10. "chock". Oxford English Dictionary (2nd ed.). Oxford University Press. 1989.
  11. "chuck". Oxford English Dictionary (2nd ed.). Oxford University Press. 1989.
  12. UK Retail Price Index inflation figures are based on data from Clark, Gregory (2017). "The Annual RPI and Average Earnings for Britain, 1209 to Present (New Series)". MeasuringWorth . Retrieved May 7, 2024.
  13. Thomson, Thomas, ed. (February 1819), "Proceedings of the Society for the Encouragement of Arts, Manufactures and Commerce", Annals of Philosophy, XIII (74), London: Baldwin, Cradock, and Joy: 143, retrieved July 31, 2015
  14. Thomson, Thomas, ed. (July 1819), "Proceedings of the Society for the Encouragement of Arts, Manufactures and Commerce", Annals of Philosophy , XIV (79), London: Baldwin, Cradock, and Joy: 53, retrieved July 31, 2015
  15. US 1692,Fairman, Simon,"Expanding and contracting or universal chuck for lathes",published 1840-07-18
  16. Fairman (1840) lines 77 ff.
  17. "Cushman - Home". Cushman - Home.
  18. "Archived copy". Archived from the original on January 20, 2018. Retrieved January 19, 2018.{{cite web}}: CS1 maint: archived copy as title (link)
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Bibliography