Energy & Power

The Museum's collections on energy and power illuminate the role of fire, steam, wind, water, electricity, and the atom in the nation's history. The artifacts include wood-burning stoves, water turbines, and windmills, as well as steam, gas, and diesel engines. Oil-exploration and coal-mining equipment form part of these collections, along with a computer that controlled a power plant and even bubble chambers—a tool of physicists to study protons, electrons, and other charged particles.

A special strength of the collections lies in objects related to the history of electrical power, including generators, batteries, cables, transformers, and early photovoltaic cells. A group of Thomas Edison's earliest light bulbs are a precious treasure. Hundreds of other objects represent the innumerable uses of electricity, from streetlights and railway signals to microwave ovens and satellite equipment.

One method that companies have long used to minimize production costs is to design products that use many of the same parts.
Description
One method that companies have long used to minimize production costs is to design products that use many of the same parts. In the early 1990s Duro-Test Lighting used this approach in a series of modular compact fluorescent lamps (CFLs).
Modular CFLs are designed so that specific parts can be replaced if they fail. This allows the reuse of expensive parts that still work. In this particular lamp, the fluorescent tube and the reflector enclosing it are made as one piece; the base-unit that houses the ballast and starter are another. In addition to allowing one to replace the tube assembly if it failed, one could swap different assemblies. The reflector lamp could be changed to a decorative lamp for example, without having to remove the base-unit.
Since the price of electronic components has dropped since this lamp was made, the economic reasoning behind this feature is less persuasive.
Lamp characteristics: Two-piece, modular compact fluorescent lamp including a base-unit and a tube assembly. The base-unit has a medium-screw base-shell with plastic insulator, and a plastic skirt that houses a ballast and a starter. A socket on top accepts a plug-in base. Tube assembly includes plastic plug-in base, a fluorescent tube with two electrodes, mercury, and a phosphor coating. A glass R-shaped envelope with silvered coating serves as a reflector and is glued to the tube assembly's base.
Date made
January 1991
1991-01
manufacturer
DURO-TEST Corporation
ID Number
1997.0062.09
catalog number
1997.0062.09
accession number
1997.0062
The energy crises of the 1970s inspired inventors to try novel ideas for new light bulbs. One of the more unusual designs emerged from the drawing board of Manhattan Project veteran Leo Gross.
Description
The energy crises of the 1970s inspired inventors to try novel ideas for new light bulbs. One of the more unusual designs emerged from the drawing board of Manhattan Project veteran Leo Gross. Supported by Merrill Skeist at Spellman High Voltage Electronics Corporation, Gross designed a compact fluorescent lamp that he called a "magnetic arc spreader" (MAS).
The design took advantage of a fundamental aspect of electro-magnetism known since the early 1800s. When a current flows through a coil of wire, it produces a magnetic field. The arc discharge that travels between the electrodes of a fluorescent lamp can be affected by the presence of such a field. In the center of the MAS lamp seen here there is a copper coil. Current moving through the coil creates a magnetic field that spreads out the electrical arc within the lamp. The expanded arc energizes phosphor throughout the lamp's entire length.
The concept was tested at Lawrence Berkeley Laboratory, and General Electric became interested. In 1978 GE purchased a one-year license from Spellman in order to conduct further tests but determined that the necessary glasswork would make the lamp too expensive for commercial production. GE donated one of their test lamps to the Smithsonian in 1998—the only known surviving example of this experimental design.
Lamp characteristics: No base. Two stranded lead-wires extend about 2" from either end, and each end has one lead wire encased in a glass insulating tube. Two coiled tungsten electrodes are mounted in a hollow cylindrical envelope. The exhaust tip is near one set of leads, and the envelope has an internal phosphor coating. A coil of bare copper wire held together with black string is inserted into the center of the envelope. A current passing thru this coil spreads the arc between electrodes so that more of the phosphor is activated.
Date made
ca 1978
date made
ca. 1978
maker
General Electric Corporate Research & Development Laboratory
inventor
Spellman High Voltage Electronics Corp.
ID Number
1998.0050.15
accession number
1998.0050
catalog number
1998.0050.15
As energy prices soared in the 1970s, lamp makers focused research efforts on raising the energy efficiency of electric lamps. A great deal of effort by many researchers went into designing small fluorescent lamps that might replace a regular incandescent lamp.
Description
As energy prices soared in the 1970s, lamp makers focused research efforts on raising the energy efficiency of electric lamps. A great deal of effort by many researchers went into designing small fluorescent lamps that might replace a regular incandescent lamp. These efforts led to modern compact fluorescent lamps that use bent or connected tubes, but many other designs were tried. This experimental "partition lamp" from 1978 shows one such design.
Soon after the 1939 introduction of linear fluorescent lamps, inventors began receiving patents for smaller lamps. But they found that the small designs suffered from low energy efficiency and a short life-span. Further research revealed that energy efficiency in fluorescent lamps depends in part on the distance the electric current travels between the two electrodes, called the arc path. A long arc path is more efficient than a short arc path. That's why fluorescent tubes in stores and factories are usually 8 feet (almost 3 meters) long.
Inventors in the 1970s tried many ways of putting a long arc path into a small lamp. In this case there are thin glass walls inside the lamp, dividing it into four chambers. Each chamber is connected in such a way that the electric current travels the length of the lamp four times when moving from one electrode to the other. So the arc path is actually four times longer than the lamp itself, raising the energy efficiency of the lamp. This unit was made by General Electric for experiments on the concept, though other makers were also working on partition lamps.
While the partition design works, it proved to be expensive to manufacture and most lamp makers decided to use thin tubes that could be easily bent and folded while being made.
Lamp characteristics: No base. Two stem assemblies each have tungsten electrodes in a CCC-6 configuration with emitter. Welded connectors, 3-piece leads with lower leads made of stranded wire. Bottom-tipped, T-shaped envelope with internal glass partition that separates the internal space into four connected chambers. Partition is made of two pieces of interlocked glass and is not sealed into the envelope. All glass is clear. No phosphors were used since the experimenter wanted to study the arc path.
Date made
ca 1978
date made
ca. 1978
maker
General Electric Corporate Research & Development Laboratory
ID Number
1998.0050.16
accession number
1998.0050
catalog number
1998.0050.16
A major hurdle that makers of compact fluorescent lamps (CFLs) have faced stems from the unusual shapes of the lamps, as compared to traditional incandescent lamps. Consumers have grown used to what light bulbs "are supposed" to look like.
Description
A major hurdle that makers of compact fluorescent lamps (CFLs) have faced stems from the unusual shapes of the lamps, as compared to traditional incandescent lamps. Consumers have grown used to what light bulbs "are supposed" to look like. Many have rejected CFLs for that reason despite the potential cost savings.
As lamp makers refined their understanding of the new product, designs were introduced to meet consumers' preferences for less-intrusive styles. Duro-Test developed a series of five modular CFLs around 1996, including this "Duro-Brite" unit that has a removable glass globe covering the twin-tube lamp. Another unit in the collection sports a removable glass reflector. The base-units contain the lamp's ballast and starter, and the tube assemblies themselves are interchangeable.
This unit is a modular CFL with three components: a tube assembly, an adapter, and a glass cover.
Lamp characteristics: Tube assembly is a twin-tube unit mounted on a plastic base. The adapter has a medium-screw base-shell with an insulator that is part of the plastic skirt housing the ballast. A G23 socket is on top for the tube assembly, and key-slots are molded around the edge to attach the cover. Cover is a G-shaped, clear-glass envelope with aluminum collar at bottom. There are stamped protrusions on the inside of the collar to mount the cover onto the adapter. Electrical rating is 13 watts.
date made
ca. 1996
Date made
ca 1996
manufacturer
DURO-TEST Corporation
ID Number
1997.0062.11
catalog number
1997.0062.11
accession number
1997.0062
Original switch key put in on introduction of the second dynamo, November, 1881. A wooden knife switch mounted on a wooden base. Four binding posts. Used in the Hinds-Ketchum printing plant as part of the first commercial installation of the Edison lighting system.
Description (Brief)
Original switch key put in on introduction of the second dynamo, November, 1881. A wooden knife switch mounted on a wooden base. Four binding posts. Used in the Hinds-Ketchum printing plant as part of the first commercial installation of the Edison lighting system.
Date made
1881
maker
Edison Electric Co.
ID Number
EM.180944
catalog number
180944
accession number
24315
Original safety plugs put in on system in December, 1881. Prior to this a small section of lead wire had been soldered into the trunk line and there were no safety plugs [fuses] on any of the main lines to the lamps.
Description (Brief)
Original safety plugs put in on system in December, 1881. Prior to this a small section of lead wire had been soldered into the trunk line and there were no safety plugs [fuses] on any of the main lines to the lamps. Used in the Hinds-Ketchum printing plant as part of the first commercial installation of the Edison lighting system
Date made
1881
maker
Edison Electric Co.
ID Number
EM.180943
catalog number
180943
accession number
24315
Original switch key by which current was turned on lamps in the building. #499 and 451 Water Street, New York City, on the evening of January 15, 1881. A wooden pivot switch mounted on a wooden base. Four binding posts.
Description (Brief)
Original switch key by which current was turned on lamps in the building. #499 and 451 Water Street, New York City, on the evening of January 15, 1881. A wooden pivot switch mounted on a wooden base. Four binding posts. Used in the Hinds-Ketchum printing plant as part of the first commercial installation of the Edison lighting system.
Date made
1881
ID Number
EM.180942
catalog number
180942
accession number
24315
Donor reported: "Fixture and lamp socket, with covered tin shade, used by engravers to concentrate the light on a small space.
Description (Brief)
Donor reported: "Fixture and lamp socket, with covered tin shade, used by engravers to concentrate the light on a small space. This fixture and shade excited great interest at the time as it was apparently the first shade that any one had ever seen which covered the top of the lamp or light without ventilation. Double swing gas pipe brackets with rough tin shades - one extra shade." A converted gas fixture with a keyless Edison socket for a Johnson bevel-ring incandescent lamp. Used in the Hinds-Ketchum printing plant as part of the first commercial installation of the Edison lighting system.
Date made
1881
ID Number
EM.180939
catalog number
180939
accession number
24315
Date made
1831
maker
Henry, Joseph
ID Number
EM.181343
catalog number
181343
accession number
26705
Experimental LEAP (Linear Exhaust And Processing) tungsten halogen lamp for a production method that used a laser.Currently not on view
Description (Brief)
Experimental LEAP (Linear Exhaust And Processing) tungsten halogen lamp for a production method that used a laser.
Location
Currently not on view
date made
1972
maker
General Electric Lighting Company
ID Number
1996.0082.02
catalog number
1996.0082.02
accession number
1996.0082
A lamp with Baltimore Gas & Electric anniversary wrapper. Mailed to customers as part of a load-building program.Currently not on view
Description (Brief)
A lamp with Baltimore Gas & Electric anniversary wrapper. Mailed to customers as part of a load-building program.
Location
Currently not on view
date made
ca 1966
1966
maker
Westinghouse Electric Corp.
ID Number
1997.0387.19
accession number
1997.0387
catalog number
1997.0387.19
Date made
1885
ID Number
EM.314917
catalog number
314917
accession number
212336
Experimental LEAP (Linear Exhaust And Processing) tungsten halogen lamp for a production method that used a laser.Currently not on view
Description (Brief)
Experimental LEAP (Linear Exhaust And Processing) tungsten halogen lamp for a production method that used a laser.
Location
Currently not on view
date made
1972
maker
General Electric Lighting Company
ID Number
1996.0082.03
catalog number
1996.0082.03
accession number
1996.0082
New lighting inventions occasionally appear from unexpected directions. The development of this microwave-powered lamp provides a case in point.
Description
New lighting inventions occasionally appear from unexpected directions. The development of this microwave-powered lamp provides a case in point. In 1990 Fusion Systems was a small company with a successful, highly specialized product, an innovative ultraviolet (UV) industrial lighting system powered by microwaves.
Discharge lamps typically use electrodes to support an electric arc. Tungsten electrodes are most common, so materials that might erode tungsten can't be used in the lamp and care must be taken to not melt the electrodes. Fusion's lamp side-stepped this problem by eliminating electrodes entirely. Microwave energy from an external source energized the lamp. This opened the way for experiments with non-traditional materials, including sulfur.
During the 1980s engineer Michael Ury, physicist Charles Wood, and their colleagues experimented several times with adapting their UV system to produce visible light without success. In 1990, they tried placing sulfur in a spherical bulb instead of a linear tube. Sulfur could give a good quality light, but did not work well in the linear tube. Other elements only gave marginal results in the spherical bulb. But when they tested sulfur in the spherical lamp they found what they hoped for: lots of good visible light with little invisible UV or infrared rays.
They began setting up "crude" lamps like this one (one of the first ten according to Ury) in order to learn more about the new light source. In the mid-1990s Fusion began trying to sell their sulfur bulbs with limited success. The lamp rotated at 20,000 rpm so that the temperature stayed even over the surface, and a fan was needed for cooling. The fan and spin motor made noise and reduced energy efficiency of the total system. Then they found that the bulbs lasted longer than the magnetrons used to generate the microwaves that powered them. Finding inexpensive magnetrons proved too difficult, and the company stopped selling the product in 2002.
Lamp characteristics: A quartz stem with notch near the bottom serves as the base. The notch locks the lamp into its fixture. The sphere has an argon gas filling, and the yellow material is sulfur condensed on the inner lamp wall. The pattern of condensation indicates lamp was burned base-down. Tipless, G-shaped quartz envelope.
Date made
ca 1990
date made
ca. 1990
maker
Ury, Michael G.
ID Number
1992.0467.01
catalog number
1992.0467.01
accession number
1992.0467
An experimental 10,000 watt stage and studio lamp with a hydrogen-bromine fill gas.Currently not on view
Description (Brief)
An experimental 10,000 watt stage and studio lamp with a hydrogen-bromine fill gas.
Location
Currently not on view
date made
ca 1970
maker
General Electric Lighting Company
ID Number
1996.0082.06
catalog number
1996.0082.06
accession number
1996.0082
Linear incandescent lamp with a carbon filament. Made by the Johns-Manville Company.Currently not on view
Description (Brief)
Linear incandescent lamp with a carbon filament. Made by the Johns-Manville Company.
Location
Currently not on view
date made
ca 1908
maker
H. W. Johns-Manville Co.
ID Number
1997.0388.68
catalog number
1997.0388.68
accession number
1997.0388
Pre-production GE metal halide lamp for indoor use.
Description (Brief)
Pre-production GE metal halide lamp for indoor use.
date made
ca 1980
maker
General Electric Co.
ID Number
1996.0080.01
accession number
1996.0080
catalog number
1996.0080.01
The discovery of nuclear fission in uranium, announced in 1939, allowed physicists to advance with confidence in the project of creating "trans-uranic" elements - artificial ones that would lie in the periodic table beyond uranium, the last and heaviest nucleus known in nature.
Description
The discovery of nuclear fission in uranium, announced in 1939, allowed physicists to advance with confidence in the project of creating "trans-uranic" elements - artificial ones that would lie in the periodic table beyond uranium, the last and heaviest nucleus known in nature. The technique was simply to bombard uranium with neutrons. Some of the uranium nuclei would undergo fission, newly understood phenomenon, and split violently into two pieces. In other cases, however, a uranium-238 nucleus (atomic number 92) would quietly absorb a neutron, becoming a nucleus of uranium-239, which in turn would soon give off a beta-particle and become what is now called neptunium-239 (atomic number 93). After another beta decay it would become Element 94 (now plutonium-239)
By the end of 1940, theoretical physicists had predicted that this last substance, like uranium, would undergo fission, and therefore might be used to make a nuclear reactor or bomb. Enrico Fermi asked Emilio Segre to use the powerful new 60-inch cyclotron at the University of California at Berkeley to bombard uranium with slow neutrons and create enough plutonium-239 to test it for fission. Segre teamed up with Glenn T. Seaborg, Joseph W. Kennedy, and Arthur C. Wahl in January 1941 and set to work.
They carried out the initial bombardment on March 3-6, then, using careful chemical techniques, isolated the tiny amount (half a microgram) of plutonium generated. They put it on a platinum disc, called "Sample A," and on March 28 bombarded it with slow neutrons to test for fission. As expected, it proved to be fissionable - even more than U-235. To allow for more accurate measurements, they purified Sample A and deposited it on another platinum disc, forming the "Sample B" here preserved. Measurements taken with it were reported in a paper submitted to the Physical Review on May 29, 1941, but kept secret until 1946. (The card in the lid of the box bears notes from a couple of months later.)
After the summer of 1941, this particular sample was put away and almost forgotten, but the research that began with it took off in a big way. Crash programs for the production and purification of plutonium began at Berkeley and Chicago, reactors to make plutonium were built at Hanford, Washington, and by 1945 the Manhattan Project had designed and built a plutonium atomic bomb. The first one was tested on July 16, 1945 in the world's first nuclear explosion, and the next was used in earnest over Nagasaki. (The Hiroshima bomb used U-235.)
Why is our plutonium sample in a cigar box? G.N. Lewis, a Berkeley chemist, was a great cigar smoker, and Seaborg, his assistant, made it a habit to grab his boxes as they became empty, to use for storing things. In this case, it was no doubt important to keep the plutonium undisturbed and uncontaminated, on the one hand, but also, on the other hand, to make it possible for its weak radiations to pass directly into instruments - not through the wall of some closed container. Such considerations, combined probably with an awareness of the historic importance of the sample, brought about the storage arrangement we see.
Location
Currently not on view
Date made
1941-05-21
Associated Date
1941-05-29
referenced
Segre, Emilio
Seaborg, Glenn T.
Kennedy, Joseph W.
Wahl, Arthur C.
Lewis, G. N.
University of California, Berkeley
maker
Segre, Emilio
Seaborg, Glenn
ID Number
EM.N-09384
catalog number
N-09384
accession number
272669
Production model PLG41E2 compact fluorescent lamp to replace a 60 watt incandescent lamp.Currently not on view
Description (Brief)
Production model PLG41E2 compact fluorescent lamp to replace a 60 watt incandescent lamp.
Location
Currently not on view
date made
ca 1992
maker
General Electric Lighting Company
ID Number
1996.0357.04
accession number
1996.0357
catalog number
1996.0357.04
This stationary walking-beam steam engine generated forty horsepower to operate woodworking machines at the Southern Railway's shops in Charleston, South Carolina.
Description
This stationary walking-beam steam engine generated forty horsepower to operate woodworking machines at the Southern Railway's shops in Charleston, South Carolina. The engine ran for 75 years, from 1852 to 1927.
The engine's vertical cylinder and graceful walking beam recall the pioneering steam engines of British engineer Thomas Newcomen, who found commercial application for the expansive powers of steam, not to power other machines but to pump water out of mines.
Date made
1851
maker
Harlan & Hollingsworth Company
ID Number
MC.314791
catalog number
314791
accession number
209703
When most people think of electric lighting, they think of ordinary lamps used for lighting rooms or shops. But many types of lamps are made for use in highly specialized applications. One example is a successful product made by Fusion Systems.
Description
When most people think of electric lighting, they think of ordinary lamps used for lighting rooms or shops. But many types of lamps are made for use in highly specialized applications. One example is a successful product made by Fusion Systems. Founded by four scientists and an engineer, the company markets an ultraviolet (UV) lighting system powered by microwaves. Introduced in 1976, the system found a market in industrial processing as a fast, efficient way to cure inks. A major brewery, for example, purchased the system for applying labels to beer cans and quickly curing their inks while the bottles went down the production line. U.S. patents issued for this lighting system include 3872349, 4042850 and 4208587.
The lamp seen here, referred to as a "TEM lamp" is a typical production unit. As in a fluorescent lamp, this lamp makes ultraviolet light by energizing mercury vapor. Fluorescents and other conventional lamps pass an electric current between two electrodes to energize the mercury. But Fusion's lamp has no electrodes. Instead the lamp is placed in a specially made fixture similar in principle to a household microwave oven. The microwaves energize the mercury vapor directly. A small dose of metal halides is also energized in the lamp. The choice of metal halides allows specific wavelengths of light to be produced to meet different needs.
Profits made from the production of this industrial lamp were used by the company to support research and development of a microwave-powered lamp that made visible light. Instead of mercury that lamp used sulfur. However this sulfur lamp did not sell well when introduced in the mid-1990s.
Lamp characteristics: Clear quartz tube containing a metal-halide pellet and a drop of mercury. No electrodes. The air-cooled tube is radiated by microwaves and produces ultraviolet light.
date made
ca. 1996
Date made
ca 1996
maker
Fusion Lighting, Inc.
ID Number
1996.0359.03
catalog number
1996.0359.03
accession number
1996.0359
Experimental LEAP (Linear Exhaust And Processing) tungsten halogen lamp for a production method that used a laser.Currently not on view
Description (Brief)
Experimental LEAP (Linear Exhaust And Processing) tungsten halogen lamp for a production method that used a laser.
Location
Currently not on view
date made
1972
maker
General Electric Lighting Company
ID Number
1996.0082.04
catalog number
1996.0082.04
accession number
1996.0082
associated institution
Faesch & Piccard
ID Number
EM.315850
catalog number
315850
accession number
221414
Made in Fort Wayne Indiana, this gasoline pump sold "Red Crown" gasoline, a brand produced by Standard Oil of Indiana.
Description
Made in Fort Wayne Indiana, this gasoline pump sold "Red Crown" gasoline, a brand produced by Standard Oil of Indiana. Consumers could see how much gas was pumped as the arrow moved around the face dial.
As Americans began to drive gasoline-fueled cars in large numbers, oil companies and gasoline stations created technologies and systems to fulfill the demands of consumers. By the 1930s, pumps were the recognizable ancestors of the ones we use today.
Date made
1930
date made
1932
distributor
Amoco
maker
Wayne Oil Tank & Pump Company
ID Number
TR.326809
accession number
265699
catalog number
326809

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