Turret latheFrom Wikipedia, the free encyclopedia

Hartness 3x36 flat turret lathe with cross-sliding head, equipped forbar work, 1910.[1]

The turret lathe is a form of metalworking lathe that is used for repetitive production of duplicate parts,

which by the nature of their cutting process are usually interchangeable. It evolved from earlier lathes

with the addition of the turret, which is an indexable toolholder that allows multiple cutting operations to

be performed, each with a different cutting tool, in easy, rapid succession, with no need for the

operator to perform setup tasks in between, such as installing or uninstalling tools, nor to control the

toolpath. The latter is due to the toolpath's being controlled by the machine, either injig-like fashion, via

the mechanical limits placed on it by the turret's slide and stops, or via electronically-directed

servomechanisms for computer numerical control (CNC) lathes.

Contents

 [hide]

1   Types of turret lathes, and their nomenclature

o 1.1   Overview

o 1.2   The archetypical turret lathe: horizontal, manual

o 1.3   Semi-automatic turret lathes

o 1.4   Automatic turret lathes

o 1.5   Computer numerical control and second-operation lathes

o 1.6   Vertical turret lathes

o 1.7   Other variations of design and nomenclature

1.7.1   Capstan versus turret

1.7.2   Flat-turret lathe

1.7.3   Hollow-hexagon turret lathe

1.7.4   Monitor lathe

1.7.5   Toolpost turrets and tailstock turrets

2   Significance of turret lathes to the history of technology

o 2.1   Mid-19th century: do not treat duplicate parts like one-off parts

o 2.2   Late-19th through mid-20th centuries: key to mass production

o 2.3   Mid-20th century to present: transition to small runs and second operations

3   Description of an example part-cutting cycle on a manual turret lathe

4   Reference citations

5   Bibliography

6   External links

[edit]Types of turret lathes, and their nomenclature

[edit]Overview

There are many variants of the turret lathe. They can be most generally classified by size (small,

medium, or large); method of control (manual, automated mechanically, or automated via computer

(numerical control (NC) or computer numerical control (CNC)); and bed orientation (horizontal or

vertical).

[edit]The archetypical turret lathe: horizontal, manual

The archetypical turret lathe, and the first in order of historical appearance, is the horizontal-bed,

manual turret lathe. In machine shop jargon, the term "turret lathe", without further qualification, is still

usually understood in context to refer to this type. The formative decades for this class of machine

were the 1840s through 1860s, when the basic idea of mounting an indexable turret on a bench lathe

or engine lathe was elaborated upon, developed, and disseminated into factories. Some important

tool-builders in this development were Stephen Fitch; Gay, Silver & Co.; Elisha K. Root of Colt; J.D.

Alvord of the Sharps Armory; Frederick W. Howe, Richard S. Lawrence, and Henry D. Stone of

Robbins & Lawrence; J.R. Brown of Brown & Sharpe; Pratt & Whitney; and later various designers at

these and other firms.[2]

[edit]Semi-automatic turret lathes

Sometimes machines similar to those above, but with power feeds and automatic turret-indexing at the

end of the return stroke, are called "semi-automatic turret lathes". This nomenclature distinction is

blurry and not consistently observed. The term "turret lathe" encompasses them all. During the 1860s,

when semi-automatic turret lathes were developed, they were sometimes called "automatic". What we

today would call "automatics", that is, fully automatic machines, had not been developed yet. During

that era both manual and semi-automatic turret lathes were sometimes called "screw machines",

although we today reserve that term for fully automatic machines.

[edit]Automatic turret lathes

Main article: Screw machine

During the 1870s through 1890s, the mechanically automated "automatic" turret lathe was developed

and disseminated. These machines can execute many part-cutting cycles without human intervention.

Thus the duties of the operator, which were already greatly reduced by the manual turret lathe, were

even further reduced, and productivity increased. These machines use cams to automate the sliding

and indexing of the turret and the opening and closing of the chuck. Thus, they execute the part-

cutting cycle somewhat analogously to the way in which an elaborate cuckoo clock performs an

automated theater show. Small- to medium-sized automatic turret lathes are usually called "screw

machines" or "automatic screw machines", while larger ones are usually called "automatic chucking

lathes", "automatic chuckers", or "chuckers".

Machine tools of the "automatic" variety, which in the pre-computer era meant mechanically

automated, had already reached a highly advanced state by World War I.

[edit]Computer numerical control and second-operation lathes

When World War II ended, the digital computer was poised to develop from a colossal laboratory

curiosity into a practical technology that could begin to disseminate into business and industry. The

advent of electronics-based automation in machine tools via numerical control (NC) and then computer

numerical control (CNC) displaced to a large extent, but not at all completely, the previously existing

manual and mechanically automated machines. Today, most CNC lathes have turrets, and so could

logically be called "turret lathes", but the terminology is usually not used that way. Horizontal CNC

lathes, with or without turrets, are generally called "CNC lathes" or "CNC turning centers" or "turning

centers", and the term "turret lathe" by itself is still usually understood in context to refer to horizontal,

manual turret lathes. The changed role in the production process that such machines now play is

reflected in another name for them, second-operation lathe, as explained later.

[edit]Vertical turret lathes

The term "vertical turret lathe" (VTL) is applied to machines wherein the same essential design of the

horizontal version is upended, which allows the headstock to sit on the floor and thefaceplate to

become a horizontal rotating table, analogous to a huge potter's wheel. This is useful for the

handling of very large, heavy, short workpieces. Vertical lathes in general are also called

"vertical boring mills" or often simply "boring mills"; therefore a vertical turret lathe is a

vertical boring mill equipped with a turret. A CNC version is called a "CNC VTL".

CNC VTL, 46” Bullard High Column Dynatrol, built mid-

1960s.

CNC VTL, 88” Niles Vertical Turret Lathe, built mid-

1950s.

CNC VTL, King Vertical Turret Lathe Model 100, built 1955.

CNC VTL, 16' Rockford Open Side, built 1980.

[edit]Other variations of design and nomenclature

[edit]Capstan versus turret

The term "capstan lathe" overlaps in sense with the term "turret lathe" to a large extent. In many times

and places, it has been understood to be synonymous with "turret lathe". In other times and places it

has been held in technical contradistinction to "turret lathe", with the difference being in whether the

turret's slide is fixed to the bed (ram-type turret) or slides on the bed's ways (saddle-type turret).[3]

[4] The difference in terminology is mostly a matter of United Kingdom and Commonwealth usage

versus United States usage.[2] American usage tends to call them all "turret lathes".

The word "capstan" could logically seem to refer to the turret itself, and to have been inspired by the

nautical capstan. A lathe turret with tools mounted in it can very much resemble a nautical capstan full

of handspikes. This interpretation would lead Americans to treat "capstan" as a synonym of "turret"

and "capstan lathe" as a synonym of "turret lathe". However, the multi-spoked handles that the

operator uses to advance the slide are also called capstans, and they themselves also resemble the

nautical capstan.

No distinction between "turret lathe" and "capstan lathe" persists upon translation from English into

other languages. Most translations involve the term "revolver", and serve to translate either of the

English terms.

The words "turret" and "tower", the former being a diminutive of the latter, come ultimately from the

Latin "turris", which means "tower", and the use of "turret" both to refer to lathe turrets and to refer

to gun turrets seems certainly to have been inspired by its earlier connection to

the turrets of fortified buildings and to siege towers. The history of the rook in chess is connected to

the same history, with the French word for rook, tour, meaning "tower".

It is an interesting coincidence that the word "tour" in French can mean both "lathe" and "tower", with

the first sense coming ultimately from Latin "tornus", "lathe", and the second sense coming ultimately

from Latin "turris", "tower". "Tour revolver", "tour tourelle", and "tour tourelle revolver" are various ways

to say "turret lathe" in French.

[edit]Flat-turret lathe

A subtype of horizontal turret lathe is the flat-turret lathe. Its turret is flat (and analogous to a rotary

table), allowing the turret to pass beneath the part. Patented by James Hartness of Jones & Lamson,

and first disseminated in the 1890s, it was developed to provide more rigidity via requiring less

overhang in the tool setup, especially when the part is relatively long.[5]

[edit]Hollow-hexagon turret lathe

Hollow-hexagon turret lathes competed with flat-turret lathes by taking the conventional hexagon turret

and making it hollow, allowing the part to pass into it during the cut, analogously to how the part would

pass over the flat turret. In both cases, the main idea is to increase rigidity by allowing a relatively long

part to be turned without the tool overhang that would be needed with a conventional turret, which is

not flat or hollow.

[edit]Monitor lathe

The term "monitor lathe" formerly (1860s-1940s) referred to the class of small- to medium-sized

manual turret lathes used on relatively small work. The name was inspired by the monitor-class

warships, which the monitor lathe's turret resembled. Today, lathes of such appearance, such as the

Hardinge DSM-59 and its many clones, are still common, but the name "monitor lathe" is no longer

current in the industry.

[edit]Toolpost turrets and tailstock turrets

Turrets can be added to non-turret lathes (bench lathes, engine lathes, toolroom lathes, etc.) by

mounting them on the toolpost, tailstock, or both. Often these turrets are not as large as a turret

lathe's, and they usually do not offer the sliding and stopping that a turret lathe's turret does; but they

do offer the ability to index through successive tool settings.

[edit]Significance of turret lathes to the history of technology

[edit]Mid-19th century: do not treat duplicate parts like one-off parts

The development of the turret lathe around the middle of the 19th century was a key aspect of the

advancement of manufacturing technology. Unlike bench lathes, engine lathes, and toolroom lathes,

on which each tool change involved some amount of setup, and toolpath had to be carefully controlled

by the operator, turret lathes allowed the multiple tool changes and toolpaths of one part-cutting cycle

to be repeated with little time or effort. By taking the tool-changing and the toolpath control out of the

hands of the operator and building it into the machine tool, it accomplished several feats: it made

interchangeable parts easier, faster, and thus cheaper to produce; and it made their production

possible by workers with little skill. As long as a few skilled engineers, toolmakers, and setup

technicians made and equipped the machine correctly, just about any operator could be hired

(inexpensively) to run it.

Another way to look at this change is that humans gradually figured out that they should not treat

duplicate parts like one-off parts. You do not need a master craftsman to cut each duplicate part as if it

were unique; if you can set up a repeatable sequence of restricted movements, you can simply repeat

the same sequence with each part. And if you can preserve the setting of each tool, so that a tool

change does not destroy the setting, but rather lets it be indexed back into position whenever needed,

then you have saved vast amounts of time and effort.

The ideas above developed gradually, first in the armory practice of the mid and late 19th century

(otherwise known as the American system), and then in true mass production during the 20th century.

Those two phenomena have not always been differentiated from each other, but the difference is in

the degree to which toolpath control had replaced skilled fitting, or, as it is more often expressed, the

degree to which "the skill had been built into the machine tool". The replacement did not happen

overnight, but rather was a gradual tapering off of reliance upon fitting, the progress varying by plant

and by decade, until it had been completely eliminated from the assembly process, creating true mass

production.[6]

Turret lathe operator, USA, 1942.

[edit]Late-19th through mid-20th centuries: key to mass production

From the late-19th through mid-20th centuries, turret lathes, both manual and automatic (i.e., screw

machines and chuckers), were one of the most important classes of machine tools for mass

production.

[edit]Mid-20th century to present: transition to small runs and second operations

With the development and dissemination of CNC lathes, which themselves often have automated

turrets, manual turret lathes began to lose their position as the key to mass production of turned parts.

However, they did not become obsolete; the focus of their use simply shifted from the main turning

operations of mass production, which are now usually done by CNCs, to small runs, for which they can

still compete in unit cost with CNC use, and second operations, such as re-chucking a part turned out

by a CNC in order to make a few simple cuts on the back. This transition in primary job description is

reflected in the name "second-operation lathe", which is often synonymous with "manual turret lathe".

Similarly, cam-operated screw machines and chuckers did not disappear; they simply shifted to a

different niche. They still often compete with CNC machines in terms of unit cost per part produced,

depending on the difference in overhead. A CNC lathe with hefty payments may translate to higher

overall costs than a screw machine or chucker that is long since paid for.

[edit]Description of an example part-cutting cycle on a manual turret lathe

By pushing the handlever of a manual turret forward, the tool is moved via the turret's slide toward the

workpiece being held by the chuck, soon making contact and cutting or forming the part. On the return

stroke, the tool is retracted and then indexed to the next tool held in the turret. In this way, a sequence

of operations can be performed on a part without switching tools with each operation. That is, different

tools can be shifted into position without the need to unscrew one and screw in another. Each tool can

be set for a different length of travel by a stop screw located at the far right of the turret.

As an example, if one wanted to make a batch of special knurled-head screws, the turret could be set

up with tools and used in this sequence:

1. Stop to set length of bar stock to be machined;

2. Box tool  to turn diameter of stock down to threading size;

3. Geometric die head to cut external threads on turned-down part,

4. Knurling tool to knurl the screw's head.

After this, a front tool on the cross slide could cut a groove in the knurled area, providing a chamfer,

and then a rear tool would be brought forward to cut the finished screw from the bar, called "parting it

off".