|HHCC Accession No. 2006.157||HHCC Classification Code: 16.02-2A|
A mid 20th century, high tech, 25cycle capacitor-start motor, a new generation of high starting torque refrigeration motors made possible by the electrolytic, chemical capacitor, equipped with advanced, inherent, heat overload protection, with automatic reset and designed for ‘V’ belt drive applications, with light alloy end bells, vibration isolating, rubber, torsion motor mount on slotted base for belt tightening, Delco, Circa 1948. [see also 12.02-2B]
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16.02 Electric Motors - Single Phase Capacitor Start and Capacitor Run Motors
McKinnon Industries, St. Catherines, Ont.
12 x 8 x 10’h
Exhibit, education, and research quality, illustrating an early, 25 cycle capacitor start FHP induction motors, designed for electrolytic capacitor and engineered for refrigeration system operation, equipped with advanced, inherent automatic overload protection.
From York County (York Region) Ontario, once a rich agricultural hinterlands, attracting early settlement in the last years of the 18th century. Located on the north slopes of the Oak Ridges Moraine, within 20 miles of Toronto, the County would also attract early ex-urban development, to be come a wealthy market place for the emerging household and consumer technologies of the early and mid 20th century.
This artifact was discovered in the 1950’s in the used stock of T. H. Oliver, Refrigeration and Electric Sales and Service, Aurora, Ontario, an early worker in the field of agricultural, industrial and consumer technology.
With oringinal T.H. Oliver shop tag, in Howard Oliver’s writing
Type and Design:
Mid 20th century, high tech, FHP, capacitor-start motor design, 1/5th horsepower 25cycle, 110 volt, alternating current, Electrically reversible
heavy, steel laminated body, designed to reduce magnetic [hysteresis] losses and reduce heat to improve electrical efficiency High starting torque motor for reciprocating refrigeration compressor application, Internal, centrifugally operated switching for automatic control of starting winding Early design engineered for a new generation of capacitor start motors made possible by new, electrolytic, chemical capacitor technology, Equipped with inherent, overload protection with automatic reset, Light weight alloy end bells Bronze sleeve bearing with oil wicking Drive bearing extended, safety oiler Designed for ‘V’ belt drive applications, Ventilated, drip-proof housing, Slotted base to facilitate belt adjustment and tightening vibration isolating, rubber, torsion motor mounting slotted base for belt tightening,
Built for 25 cycle, 110 volt alternating current, representative of motor design used in Ontario prior to frequency standardization in the late 1940’s Oringinal T.H. Oliver shop tag, in Howard Oliver’s writing
Control and Regulation:
Targeted Market Segment:
Built for 25 cycle, 110 volt alternating current, this motor is a now rare example, representative of motor design used in Ontario prior to frequency standardization in the late 1940’s A truly advanced piece of FHP induction motor technology, built for the then rapidly expanding refrigeration equipment market, equipped with advanced engineering features new for the period, including: Vibration isolating, rubber, torsion motor mounts Drive bearing extended, safety oilier Electrolytic, chemical capacitor technology, high tech inherent, overload, thermal protection with automatic reset, light weight alloy end bells, taking advantage of new high tech metallurgy The motor exemplifies the latest in automatic over load protection, an on-going challenge through the early years in the development of unitary, fully automated refrigeration equipment, designed to operate safely, un-attended in the home. This generation of FHP capacitor-start motor technology in many ways would stand as a consummate achievement, a kind of icon of ‘the art form’, made economically possible by the high market demand for FHP motors in the Post W.W.II period. It was a market, too, that was augmented by the prospects of frequency standardization, and the massive undertaking of replacing all 25 cycle motors with 60 cycle equipment. The motor stands as a marker of the golden age in the post W.W.II expansion of the refrigeration industry in Canada, a period which saw the development of the commercial refrigeration market, based on open system refrigeration technology serving food stores, confectioneries, institutions and the like with fractional horsepower belt driven equipment, demonstrating remarkable versatility and inventiveness. It would be the last great period of expansion prior to the rush to re-equip the market with a new generation of hermetic [sealed] motor/compressors. Here the motor and compressor would both disappear from, sight both sealed in a single enclosure. The refrigeration motor, and the technology that made it possible, as it appears here, would disappear forever.
The development and commercial production of the capacitor-start single phase FHP motor, starting in the mid 1940’s was a seminal event in the history of the HVACR field. The capacitor-start motor would come to replace the more costly and complex repulsion induction motor, RI [See Group 16.01], with one with fewer moving mechanical parts, quieter, more reliable and maintainable, typically at lower cost. By allowing for electrical switching between starting and running windings, it would facilitate external relay control, rather than internal mechanical mechanisms, as with the RI motor. It would therefore be amenable for use in hermetically sealed refrigeration systems. Early experimentation, leading to the eventual commercial development of the FHP, capacitor start-motor, began with the work of Steinnmetz [American engineer and inventor 1865 ‘ 1923], 40 years before. But commercial production had to await the development of practical capacitors of sufficient capacity, the chemical, electrolytic capacitor. Early, paper capacitors, large enough to provide the required phase shift for motor starting, where larger than the motor itself, and were subject to short operating life span [see Reference 3] Conventional industrial practice for refrigeration systems, with compressors operating at conventional speeds, in the 1930’s through 60’s, saw these motors attached by ‘V’ belt drive to the refrigeration compressor with a compressor fly wheel about three times that of the diameter of the motor pulley. [see reference #4]. Maintaining belt alignment and tension was a constant challenge, due to close coupling of motor and compressor for space saving. The race to produce a quieter running, vibration free motor was on, a public expectation coming with the rapidly expanding post W.W.II market. Delco would be an acknowledged market leader in the development and production of the isolating torsion mount. Other mounting technologies were developed, but of less staying qualities, [See for example item 16.01-10 and 16.01-11]. The race was on, also, to produce an inherently safer motor, safe for the Canadian householder who was required to attend to routine maintenance tasks such as oiling. It was a period well in advance of sealed bearing technology with lifetime lubrication. Wick-oiled bronze bearings of the time required oiling quarterly. In belt driven refrigeration equipment this brought the householder in contact with a moving, compressor drive belt and whirring condenser fan blade. The design of the extended oilier tube would be a simple but significant safety feature, for householder and service man alike, allowing fingers to keep out of danger’s way.
Not-with-standing a major depression and two world wars the first half of the 20th century was a period of exceptional ferment in the development and popular dissemination of FHP electric motor technology. Associated with the development were a number of driving forces, mutually supporting and interacting: Scientifically, the theoretical ground work for development of an astonishing array of electrical and electro-magnet devices had been laid by the early years of the 20th century, through the efforts of Faraday and Steinnmetz, among many others, Technologically, the work of Thomas Edison, among others, laid the foundation stones on which urban and rural electrification would proceed, enabling an new era in human experience, favoured with consumer goods and services, previously unimagined,
Economically, a favourable climate for capital investment in manufacturing capacity, methods and materials emerged, part of North America’s second industrial revolution, Socially and culturally the consumer society was born, nurtured by a pent up demand for an easier, more comfortable, pleasurable lifestyle, and the sense that 20th century electrical and electro-motive technology might be able to help. The FHP electric motor, engineered for 110 volt, single phase house current, revolutionized life in the Canadian home. It enabled an astonishing list of appliances and labour saving devices. The revolution would take place in an astonishingly short period of time - for much of urban Canada much less than a decade. The electro-mechanical mechanization of the Canadian home was accomplished for much of urban Canada by the late 1930’s. But the early 20th century wonders of household mechanization would be dependent , in turn, on household ‘electrification’ Between them electrification and electro-mechanical mechanization changed everything. Almost over night it altered what Canadians do in the course of their day, how they live and their expectations of what their world had in store for them - in labour saving devices, devices of convenience, health and safety. The fractional horsepower electric motor [FHP] became an ubiquitous part of the Canadian household by the mid 1930’s. Cyril Veinott reported, December 1938:
‘Practically every electrified home today makes use of one or more fractional horsepower motors. This kind of motor may be used in a washing machine, refrigerator, vacuum cleaner, clock, oil burner, hair drier, room heater, sewing machine, razor, health machine, fan, air conditioner, stoker, ironed, floor waxer, or food mixer. In industrial use, the number of useful tasks performed by fractional horsepower motors is legion. In the United States alone, the value of fractional horsepower motors sold amounts to approximately $50,000,000 annually.’ See reference #1
Similarly, more than half a decade earlier Daniel Braymer had commented on the proliferation of this mind and life changing technology for home electro-mechanization. He observed that what had made it all possible was the invention of single phase alternating current motor, in a number of subtypes, small quiet, self starting, reliable and affordable motors for the home, motors which were compatible with the rapid standardization of single phase, alternating current, electrical distribution systems then spreading across north America. See reference #2 Among the types of single phase alternating current motors which quickly populated the Canadian home were: repulsion induction [see Group 16.01] for heavy duty, high starting torque applications such as refrigeration appliances; capacitor start [see Group 16.02] for advanced high torque applications, requiring quiet operation; split Phase [see Group 16.04] for light duty low starting torque applications; and shaded pole [see Group 16.04] designs for small devices such electric fans. The FHP single phase induction motor, often unobtrusive, out of sight in a dark corner, has, none-the-less, been a principle foundation stone on which Canadian, popular consumer and household technology has evolved, throughout the 20th century and into the 21st - a driving force of profound, typically un-recognized, social, cultural and economic change [See reference 6]. Electro-motive technology [the FHP motor], along with electric and electronic communications technology [the telephone and broadcast radio] would invade the Canadian home starting in the 1920’s. Throughout the balance of the 20th century these technologies would trigger a vast, new, popular consumer culture, a ‘popular technological revolution’. Yet, simply because technology has so shaped the Canadian reality, it has also shaped much profound Canadian though about the technological experience, its meaning and significance for humanity. Included among the works of Canadian writers with an international reputation are: Arthur Kroker, George Grant, Ursala Franklin, Heather Menzies, among many others [See references 7, 8, 9, and 10]. From the vantagepoint of the 21st century noted Canadian writer Jane Jacobs asks, ‘Now we stand at another monumental crossroad, as agrarianism gives way to a technology-based future. How do we make this shift without losing the culture we hold dear’ [See reference 11]
G. Leslie Oliver, The T. H. Oliver HVACR Collection
HHCC Storage Location:
‘Fractional Horsepower Electric Motors’, Cyril Veinott, McGraw Hill New York, 1948 ‘Rewinding Small Motors’, Daniel Braymer and C.C. Roe, McGraw Hill, 1932 ‘Theory and Application of Capacitor-Start Induction Motors’, G. L. Oliver, Bachelor Thesis ,University of Toronto, Session 1951-52 ‘Modern Refrigeration and Air Conditioning’, Electric Motors, Chapter 7, Andrew Althouse and Carl Turnquist, Goodheart-Wilcox, 1960 ‘A course in Electrical Engineering, Volume II, Alternating Current’, Chester Dawes, McGraw Hill, 1934, Starting single Phase Induction Motors, P. 362. ‘The Fractional Horsepower Motor and its Impact on Canadian Society and Culture’, G. Leslie Oliver, Material History Review, Vol. 43, Journal National Museum of Science and Technology, 1996. ‘Technology and the Canadian Mind, Innis/ McLuhan/Grant’, Arthur Kroker, New World Perspectives, 1984. ‘Technology and Empire’, George Grant, Anansi, 1969, ‘The Real World of Technology’, Ursula Franklin, Anansi, 1993. ‘Fast Forward and Out of Control’, Heather Menzies, Macmillan, 1989 ‘Dark Ages Ahead’, Jane Jacobs, Random House, 2004