Oscar E. Perrigo

Last updated

Charles Oscar Eugene Perrigo (c. 1848 - 1923) was an American mechanical engineer, inventor, and early technical and management author, known for his work on machine shop construction and management, [1] [2] and for his work on lathe design, construction and operation. [3]

Contents

Life and work

Perrigo was born in New York and received his education as mechanical engineer. After about three decennia working in industry as Consulting Mechanical Engineer, Perrigo started writing on technical and management subjects early 20th century. Perrigo was a member of the American Society of Mechanical Engineers, and in his works presented himself as an "Expert in machine Shop and Factory Organization, Modern Shop Methods, Time and Cost Systems, etc." [4]

Perigo wrote the successful Modern machine shop: construction, equipment and management in 1906 and Modern American Lathe Practice in 1907. These works were reprinted several times; the last edition of Machine shop work even was published in 1940, revised by the tool engineer Aldrick Bertrand. Perrigo continued writing articles for the Iron Trade Review and some other trade and technical papers, such as the American Machinist. Perigo got associated with the Modern Systems Correspondence School in Boston, Massachusetts.

Early 1910s he was also working as expert patent attorney in Boston, [5] and from 1917 to his death in 1923, he was working for the Pratt & Whitney company in Hartford. [6]

Work

Modern machine shop, 1906

Modern machine shop, 1906. Modern machine shop, 1906.jpg
Modern machine shop, 1906.

In the 1906 Modern machine shop: construction, equipment and management Perrigo aimed to "produce a work suitable for the practical and every-day use of the Architects who design, the Manufacturers who build, the Engineers who plan and equip, the Superintendents who organize and direct; and for the information of every Stockholder, Director, Officer, Accountant, Clerk, Superintendent, Foreman, and Workman of the Modem Machine Shop and Manufacturing Plant of Industrial America." [7] The many reprints confirm as Allen (2010) acknowledged, that this book was of sterling value; it was used for class instruction and as handbook for workman." [8]

This work was divided into three parts, as Perrigo explained:

The plan of the work is to divide its subject-matter into three parts or sections :
  • Part First being devoted to the Construction of the Modern Machine Shop or Manufacturing Plant, describing and illustrating buildings of approved form and arrangement:
  • Part Second to its Equipment with modem Tools, Machines, and Appliances, and the division of the plant into the proper departments for administrative and mechanical purposes; and
  • Part Third discussing the all-important question of Management^ showing the fallacy of some of the so-called systems of Management, Time and Cost Systems, and minutely describing and illustrating a plain, concise, accurate, and common-sense System of Management, and of Time and Cost Keeping, that may be easily and economically administered and yet give all the important information necessary for operating the business to financial success. [7]
The work is fully illustrated by over two hundred engravings made from designs and drawings prepared by the author especially for this purpose..."' [7]

One of those engravings was one of the first modern organizational charts (see image below), in which Perrigo pictured the new "System of Organization and Management of the Modern American Shop or Manufacturing Plant." [9] In his days this image was as "the shop tree." [10]

Machine shop construction

The first part of Modern machine shop, Perrigo (1906) focussed on the physical construction of the building, and presented a model machine shop. Of this idealized situation Perrigo gave descriptions on the front elevation of the factory building model (A), a plan of the works in the machine shop (B), the construction of the factory building (C), and the arrangement of tools and departments (D).

With this model machine shop Perrigo explored the way the space in factories could be organized. [11] This was not uncommon in his days. Many industrial engineers, like Alexander Hamilton Church, J. Slater Lewis, Hugo Diemer, F.A. Scheffer etc., published plans for some new industrial complex. Details could be quite specific, such as for example the location of the foreman's office. In this matter Perrigo in his 1905 article "Economical Arrangement of Machinery," only stipulated, that it should be prominently located. [11]

In line with this work, in 1911 Charles Day presented a new method, in which the routing diagram was proposed as basis for designing the laying out of industrial plants. This took machine shop construction to another level. [12]

Machine shop management

In the third part of Modern machine shop, Perrigo (1906) noted, that early 20th century the days of the "one-man management" had died, and instead had come the management by "a system of divided and property distributed responsibility." In this system "the real head of the establishment takes up only the consideration of the larger, broader, and more comprehensive questions of importance in management, leaving to his able assistants the questions of the next grade of importance, and in their special spheres, while they, in turn, divide the next grade of lesser responsibilities with their assistants, the foremen, and so on down through the several grades of less importance to the operatives or workmen." [10] And he continued:

Thus we have what has come to be known as "the shop tree," representing graphically this plan for the division of responsibility in the management of the entire plant. There are three grand factors that go to make up the sum of this problem of manufacturing which should not be lost sight of at the outset.
Graphic Chart, showing the System of Organization and Management of the Modern American Shop or Manufacturing Plant, 1906 Graphic Chart, showing the System of Organization and Management of the Modern American Shop or Manufacturing Plant, 1906.jpg
Graphic Chart, showing the System of Organization and Management of the Modern American Shop or Manufacturing Plant, 1906
  1. Capitalization of the scheme : The factor comprises the stockholders, represented by the Board of Directors, whose head is the president of the company, and whose executive officer is the general manager. This group includes the administrative and financial departments of the entire establishment.
  2. Manufacture of the product : The factor comprises the manufacturing plant, whose head is the works manager or superintendent, and includes the purchase of stock and supplies, the care of the grounds and buildings, and the entire process of manufacturing and shipping the product.
  3. Marketing or selling of the product : The factor includes the advertising or publicity department, and the sales department, each with its own manager, and frequently presided over by the vice-president.
While each of these departments are of prime importance in all respects, it is the second that particularly concerns us in this work. Nevertheless it may be interesting and instructive to present, see figure, a graphic diagram representing the division of duties and responsibilities as generally arranged for establishments such as we are considering, and as representing the management of our model manufacturing plant. [10]

Perrigo concludes that "this will show the regular channel for all official orders and communications, as well as, inversely, the channel through which all reports go through intermediate officers to their proper and ultimate destination. It also shows the proper relation of one department with another, of certain groups of departments with other groups, and in a general way the entire plan of organization and management. A careful study of these important relations is recommended to the earnest student of machine shop and factory organization, management, and economics." [10]

Modern American Lathe Practice, 1907

In the Modern American Lathe Practice, 1907 Perrigo aimed to present: [13]

Perrigo explained about the earliest form of a lathe proper, that it was, "a machine for shaping wood into forms having a curved, and generally a circular transverse section, by the action of a chisel or other cutting tool upon the piece, which is rotated for the purpose," as shown in the figure (A).

Before the Industrial Revolution the foot lathe has been use for many years for turning both wood and metals (see image B). Perrigo mentioned he built such a lathe himself, when he was between fifteen and sixteen years of age. [14] An 18th century new development for lathes was the idea of screw-cutting.

On 18th century innovation in lathe was the use of a "master screw" in the thread-cutting machine, which seems to have been of French origin. Perrigo explained that "in this lathe there was an arbor upon which threads of different pitches had been cut. These threads were on short sections of the arbor and by its use the different pitches required could be cut. While the exact manner of using this arbor was not described, its probable method of use will readily suggest itself to the mechanic, and was, no doubt, used at an earlier period, and in fact was what led up to the use of a lead screw or arbor with a multiplicity of different pitches. The principle is analogous to that used in the "Fox" brass finishing lathe so well known and extensively used, not only in finishing plain surfaces but in " chasing threads. This machine is shown" in the third image. [15]

Later in the book Perrigo focussed on contemporary problems of for example the introduction of high-speed steel. One of the many anecdotes mentioned, was about the problem of the fast-moving ribbon of metal, that with high-speed steel got thrown of the lathe. Perrigo recalled: "At a speed of, say, two hundred feet per minute, the chip comes writhing and twisting, almost red hot, in a continuous length, shooting here and there, everywhere but the chip box; and quick must be the workman that manages to keep well out of the way of it, for it 'sticketh like a brother' when once he gets tangled in it..." [16]

Publications

Articles and papers, a selection:

Patents

Related Research Articles

<span class="mw-page-title-main">Mass production</span> High volume production of standardized products

Mass production, also known as flow production, series production or continuous production, is the production of substantial amounts of standardized products in a constant flow, including and especially on assembly lines. Together with job production and batch production, it is one of the three main production methods.

<span class="mw-page-title-main">Joseph Whitworth</span> English engineer, entrepreneur, inventor and philanthropist

Sir Joseph Whitworth, 1st Baronet was an English engineer, entrepreneur, inventor and philanthropist. In 1841, he devised the British Standard Whitworth system, which created an accepted standard for screw threads. Whitworth also created the Whitworth rifle, often called the "sharpshooter" because of its accuracy, which is considered one of the earliest examples of a sniper rifle, used by some Confederate forces during the American Civil war.

<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">Henry Maudslay</span> English inventor and machine tool innovator (1771–1831)

Henry Maudslay was an English machine tool innovator, tool and die maker, and inventor. He is considered a founding father of machine tool technology. His inventions were an important foundation for the Industrial Revolution.

<span class="mw-page-title-main">Machine tool</span> Machine for handling or machining metal or other rigid materials

A machine tool is a machine for handling or machining metal or other rigid materials, usually by cutting, boring, grinding, shearing, or other forms of deformations. Machine tools employ some sort of tool that does the cutting or shaping. All machine tools have some means of constraining the workpiece and provide a guided movement of the parts of the machine. Thus, the relative movement between the workpiece and the cutting tool is controlled or constrained by the machine to at least some extent, rather than being entirely "offhand" or "freehand". It is a power-driven metal cutting machine which assists in managing the needed relative motion between cutting tool and the job that changes the size and shape of the job material.

<span class="mw-page-title-main">Machinist</span> Technician

A machinist is a tradesperson or trained professional who operates machine tools, and has the ability to set up tools such as milling machines, grinders, lathes, and drilling machines.

The American system of manufacturing was a set of manufacturing methods that evolved in the 19th century. The two notable features were the extensive use of interchangeable parts and mechanization for production, which resulted in more efficient use of labor compared to hand methods. The system was also known as armory practice because it was first fully developed in armories, namely, the United States Armories at Springfield in Massachusetts and Harpers Ferry in Virginia, inside contractors to supply the United States Armed Forces, and various private armories. The name "American system" came not from any aspect of the system that is unique to the American national character, but simply from the fact that for a time in the 19th century it was strongly associated with the American companies who first successfully implemented it, and how their methods contrasted with those of British and continental European companies. In the 1850s, the "American system" was contrasted to the British factory system which had evolved over the previous century. Within a few decades, manufacturing technology had evolved further, and the ideas behind the "American" system were in use worldwide. Therefore, in manufacturing today, which is global in the scope of its methods, there is no longer any such distinction.

<span class="mw-page-title-main">Chuck (engineering)</span> Clamp used to hold an object with radial symmetry, especially a cylinder

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.

<span class="mw-page-title-main">Machine shop</span> Room, building or company where machining is done

A machine shop or engineering workshop is a room, building, or company where machining, a form of subtractive manufacturing, is done. In a machine shop, machinists use machine tools and cutting tools to make parts, usually of metal or plastic. A machine shop can be a small business or a portion of a factory, whether a toolroom or a production area for manufacturing. The building construction and the layout of the place and equipment vary, and are specific to the shop; for instance, the flooring in one shop may be concrete, or even compacted dirt, and another shop may have asphalt floors. A shop may be air-conditioned or not; but in other shops it may be necessary to maintain a controlled climate. Each shop has its own tools and machinery which differ from other shops in quantity, capability and focus of expertise.

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

A 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 set-up tasks in between or to control the toolpath. The latter is due to the toolpath's being controlled by the machine, either in jig-like fashion, via the mechanical limits placed on it by the turret's slide and stops, or via digitally-directed servomechanisms for computer numerical control lathes.

<span class="mw-page-title-main">James Hartness</span> American engineer and Vermont politician (1861–1934)

James Hartness was an American business executive, inventor, mechanical engineer, entrepreneur, amateur astronomer, and politician who served as the 58th governor of Vermont from 1921 to 1923.

<span class="mw-page-title-main">Manufacturing engineering</span> Branch of engineering

Manufacturing engineering or production engineering is a branch of professional engineering that shares many common concepts and ideas with other fields of engineering such as mechanical, chemical, electrical, and industrial engineering. Manufacturing engineering requires the ability to plan the practices of manufacturing; to research and to develop tools, processes, machines, and equipment; and to integrate the facilities and systems for producing quality products with the optimum expenditure of capital.

<span class="mw-page-title-main">Screw-cutting lathe</span> Machine for accurately cutting screw threads

A screw-cutting lathe is a machine capable of cutting very accurate screw threads via single-point screw-cutting, which is the process of guiding the linear motion of the tool bit in a precisely known ratio to the rotating motion of the workpiece. This is accomplished by gearing the leadscrew to the spindle with a certain gear ratio for each thread pitch. Every degree of spindle rotation is matched by a certain distance of linear tool travel, depending on the desired thread pitch.

<span class="mw-page-title-main">Screw</span> Type of fastener characterized by a thread wrapped around a cylinder core

A screw is an externally helical threaded fastener capable of being tightened or released by a twisting force (torque) to the head. The most common uses of screws are to hold objects together and there are many forms for a variety of materials. Screws might be inserted into holes in assembled parts or a screw may form its own thread. The difference between a screw and a bolt is that the latter is designed to be tightened or released by torquing a nut.

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'.

<span class="mw-page-title-main">Hugo Diemer</span>

Hugo Diemer was an American engineer, management consultant, and professor at the Penn State University, who in 1910 published the first industrial engineering textbook: Factory Organization and Administration.

Horace Lucian Arnold was an American engineer, inventor, engineering journalist and early American writer on management, who wrote about shop management, cost accounting, and other specific management techniques. He also wrote under the names Hugh Dolnar, John Randol, and Henry Roland.

<span class="mw-page-title-main">J. Slater Lewis</span> British engineer, inventor, business manager and author

Joseph Slater Lewis MICE FRSE was a British engineer, inventor, business manager, and early author on management and accounting, known for his pioneering work on cost accounting.

<span class="mw-page-title-main">Charles Day (engineer)</span> American engineer (1879–1931)

Charles Day was an American electrical, construction and consulting engineer, and co-founder of Day & Zimmermann. He is known as a specialist in public utility management and operation, and for his seminal contributions to flow charts and the routing diagram.

References

  1. Raymond, Howard Monroe, ed. Cyclopedia of Modern Shop Practice. Vol. 1. American school of correspondence, 1909.
  2. Mallick, Randolph W., and Armand T. Gaudreau. Plant Layout. Wiley, 1951.
  3. McGeough, Joseph A. Advanced methods of machining. Springer, 1988.
  4. Perrigo (1906, title page)
  5. Popular Mechanics. March 1912, p. 184 (online)
  6. The Iron Trade Review, Vol 72. March 1, 1923. p. 676
  7. 1 2 3 Perrigo (1906, p. 5)
  8. Frederick J. Allen (2010). A Guide to the Study of Occupations. p. 179.
  9. Perrigo (1906, p. 237)
  10. 1 2 3 4 Perrigo (1906, p. 235)
  11. 1 2 Anna Vemer Andrzejewski (2008). Building Power: Architecture and Surveillance in Victorian America. p. 77
  12. Charles Day, "The Routing Diagram as a Basis for laying Out Industrial Plants." Engineering Magazine, September, 1910. p. 809-821; Republished in: Industrial Plants, 1911. Chapter VII.
  13. Perrigo (1907, p. 3)
  14. Perrigo (1907, p. 28)
  15. Perrigo (1907, p. 39)
  16. Perrigo (1907, p. 231); Partly cited in: Thomas J. Misa (1998). A Nation of Steel: The Making of Modern America, 1865-1925. p. 201
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.