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024 7 $a10.1109/IEEESTD.1955.7430213
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101 0 $aeng
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200 10$aIEEE Std No 54-1955 $eIEEE Standard, Test Code, and Recommended Practice for Induction and Dielectric Heating Equipment /$fInstitute of Electrical and Electronics Engineers
210  1$aPiscataway, NJ, USA :$cIEEE,$d1955.
215   $a1 online resource (24 pages)
330   $aHigh-frequency heating equipments divide into two main types: (1) those used for dielectric heating, and(2) those used for induction heating. The induction heating equipments again divide into seven types: (1) commercial power line; (2) rotary generator; (3) mercury-arc-converter; (4) gaseous-tube converter; (5) mercury-hydrogen-spark-gap converter; (6) quenched spark-gap converter; (7) vacuum-tube generator. Dielectric heating equipments in general use a vacuum-tube oscillator as a source of radio-frequency power ranging in frequency from 2 megacycles to hundreds of megacycles. At frequencies above about 200 megacycles,the power is generated by devices other than a conventional vacuum tube, such as a magnetron, Klystron or other microwave device. A dielectric heating generator is normally a high-voltage generator, and application requires high-voltage radio-frequency matching techniques. An induction heating generator is essentially a high-current device operating into very low impedance circuits and sometimes requires transformation in the load circuit to provide the desired heating effect.
517   $aIEEE Std No 54-1955
606   $aElectric heating
606   $aInduction heating
615  0$aElectric heating.
615  0$aInduction heating.
676   $a697.045
801  0$bNjHacI
801  1$bNjHacl
906   $aDOCUMENT
912   $a9910136395703321
996   $aIEEE Std No 54-1955$93646328
997   $aUNINA