Electric Meter: Difference between revisions
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=== Oliver B. Shallenberger Develops Westinghouse - Tesla Polyphase System Line Galvanometer Indicator with Philip Lange === | === Oliver B. Shallenberger Develops Westinghouse - Tesla Polyphase System Line Galvanometer Indicator with Philip Lange === | ||
[[Image:LANGE-SHALLENBERGER-TeslaPolyphaseSys1890METERrwLIPACKownerA.jpg|thumb|right|300px|'''Photo credit: Richard Warren Lipack / Wikimedia Commons.'''Tesla Polyphase System / Westinghouse "Three-Phase" A.C. Galvanometer Indicator by Lange & Shallenberger - 1890. Westinghouse line galvanometer / voltmeter, ser. #5453. Designed & manufactured under patents developed by Westinghouse Electric & Manufacturing Co. patentees Philip Lange & Oliver B. Shallenberger, or by Philip Lange singularly, awarded between 1887 & 1890 - and assigned to the Westinghouse Electric and Manufacturing Co. Over-all top frontal view.]] | [[Image:LANGE-SHALLENBERGER-TeslaPolyphaseSys1890METERrwLIPACKownerB.jpg|thumb|left|200px|'''Photo credit: Richard Warren Lipack / Wikimedia Commons.'''Tesla Polyphase System / Westinghouse "Three-Phase" A.C. Galvanometer Indicator by Lange & Shallenberger - 1890. Ser. #5453. Patented 1887-1890. Close-up top frontal view showing side by side 3-tiered flat coil configurations for integration into Tesla A.C. Polyphase System.]] What can be seen is a total of seven coils in this particular Tesla Polyphase System Galvanometer / Voltmeter; but six of the seven coils are unlike coils that are of the familiar round cylindrical form. [[Image:LANGE-SHALLENBERGER-TeslaPolyphaseSys1890METERrwLIPACKownerD.jpg|thumb|left|200px|'''Photo credit: Richard Warren Lipack / Wikimedia Commons.'''Tesla Polyphase System / Westinghouse "Three-Phase" A.C. Galvanometer Indicator by Lange & Shallenberger - 1890. Ser. #5453. Patented 1887-1890. Close-up rear view showing side by side 3-tiered flat coil configurations for integrated use in Tesla A.C. Polyphase System.]][[Image:LANGE-SHALLENBERGER-TeslaPolyphaseSys1890METERrwLIPACKownerA.jpg|thumb|right|300px|'''Photo credit: Richard Warren Lipack / Wikimedia Commons.'''Tesla Polyphase System / Westinghouse "Three-Phase" A.C. Galvanometer Indicator by Lange & Shallenberger - 1890. Westinghouse line galvanometer / voltmeter, ser. #5453. Designed & manufactured under patents developed by Westinghouse Electric & Manufacturing Co. patentees Philip Lange & Oliver B. Shallenberger, or by Philip Lange singularly, awarded between 1887 & 1890 - and assigned to the Westinghouse Electric and Manufacturing Co. Over-all top frontal view.]] The Westinghouse line galvanometer voltmeter shown here constructed under the combined Lange and Shallenberger patents of between 1887 and 1890, clearly show that the design is integral to handling electrical current developed and maintained under the Tesla Polyphase or "three-phase" system of electrical production and distribution. Looking close at the finely wound thin green wire coil system, one can immediately see the implementation of the "three-phase" concept. | ||
[[Category:Computing_and_electronics]] | [[Category:Computing_and_electronics]] |
Revision as of 19:32, 27 May 2015
Oliver B. Shallenberger Invents the A.C. Watt-Hour Meter
On 14 August 1888 in Pittsburgh, Pennsylvania, Oliver B. Shallenberger received a patent for the watt-hour meter, a device that measured the amount of A.C. current and made possible the business model of the electric utility.
Shallenberger was a former naval officer hired by the Westinghouse Electric & Manufacturing Co. By 1888, he rose to the power of its chief electrician. Westinghouse was fighting the “War of the Currents” in the 1880s against Thomas Edison. Westinghouse, which had purchased the rights to Nikola Tesla’s polyphase system, was trying to expand the reach of alternating current (A.C.) in American homes. Edison’s system of direct current (D.C.) was the American standard at the time, but it was less practical for residential use.
For example, Edison failed to develop a simple means of measuring how much power a consumer had used. Initially, he charged per lamp, but soon switched to a chemical method to measure amperes per hour. He installed an jar containing two zinc plates submerged in a zinc-sulfate electrolyte. As electricity flowed through the jar, it dissolved zinc off the positive plate and onto the negative one. Each month, workers checked to see how much zinc had moved. Edison actually preferred this messy and time-consuming process to a mechanical method, but its accuracy was questionable.
Working on applications for A.C. power, Shallenberger stumbled onto a solution for the problem of metering. As he was tinkering with a lamp in 1888, a spring fell out and fell on a ledge inside the lamp. He saw that the spring had rotated. Testing a hunch, he discovered that the lamp’s spinning electromagnetic fields had caused the spring to turn. Within a few weeks, Shallenberger designed a wheel that turned in relation to this rotational force, offering a means of measuring amperes per hour on an alternating current circuit.
Hundreds of thousands of these meters were built in the coming decades, allowing A.C. power to take off as an everyday consumer technology. Shallenberger’s basic design remains in use today. Because these meters operated on electrical current’s induced magnetic field, they consumed virtually no power. Consumers could feel more confident that they were only being charged for the power they used, and could more accurately monitor their consumption.
Oliver B. Shallenberger Develops Westinghouse - Tesla Polyphase System Line Galvanometer Indicator with Philip Lange
What can be seen is a total of seven coils in this particular Tesla Polyphase System Galvanometer / Voltmeter; but six of the seven coils are unlike coils that are of the familiar round cylindrical form.
The Westinghouse line galvanometer voltmeter shown here constructed under the combined Lange and Shallenberger patents of between 1887 and 1890, clearly show that the design is integral to handling electrical current developed and maintained under the Tesla Polyphase or "three-phase" system of electrical production and distribution. Looking close at the finely wound thin green wire coil system, one can immediately see the implementation of the "three-phase" concept.