{"id":5150,"date":"2024-09-20T17:00:00","date_gmt":"2024-09-20T09:00:00","guid":{"rendered":"https:\/\/globalquartztube.com\/?p=5150"},"modified":"2024-09-25T17:22:32","modified_gmt":"2024-09-25T09:22:32","slug":"carbon-fiber-infrared-heating-principles-applications","status":"publish","type":"post","link":"https:\/\/globalquartztube.com\/lv\/carbon-fiber-infrared-heating-principles-applications\/","title":{"rendered":"Oglek\u013ca \u0161\u0137iedras infrasarkan\u0101 apkure: Frekven\u010du \u0161\u0137iedras: principi un pielietojumi"},"content":{"rendered":"

Vakar p\u0113cpusdien\u0101 m\u0113s nos\u016bt\u012bj\u0101m 15 oglek\u013ca \u0161\u0137iedras sild\u012b\u0161anas caurules<\/a>katrs 1,8 m gar\u0161, ar 380 V un 2000 W specifik\u0101ciju. \u0160is garums ir sal\u012bdzino\u0161i liels. \u0160odien es turpin\u0101\u0161u iepaz\u012bstin\u0101t ar oglek\u013ca \u0161\u0137iedras sild\u012b\u0161anas cauru\u013cu sild\u012b\u0161anas principu un apspried\u012b\u0161u nozares, kur\u0101s t\u0101s galvenok\u0101rt izmanto. Dal\u012b\u0161os ar da\u017eiem konkr\u0113tu gad\u012bjumu p\u0113t\u012bjumiem no da\u017e\u0101d\u0101m nozar\u0113m, lai ikviens var\u0113tu no tiem m\u0101c\u012bties.<\/p>\n\n\n\n

Pamatzin\u0101\u0161anas par infrasarkano starojumu<\/h4>\n\n\n\n

Vispirms s\u0101ksim ar da\u017e\u0101m pamatzin\u0101\u0161an\u0101m par infrasarkano starojumu. \u0160is ir \u012bss p\u0101rskats; detaliz\u0113ts skaidrojums viegli aizpild\u012btu veselu fizikas lekciju, t\u0101p\u0113c str\u0101d\u0101sim kop\u0101, lai uzzin\u0101tu vair\u0101k.<\/p>\n\n\n\n

Oglek\u013ca \u0161\u0137iedras sild\u012b\u0161anas cauru\u013cu sild\u012b\u0161anas process<\/h4>\n\n\n\n

Kad oglek\u013ca \u0161\u0137iedras sild\u012b\u0161anas caurule<\/a> ir zem sprieguma, tas izstaro oran\u017ei sarkanu gaismu un vienlaikus rada infrasarkano starojumu, kas sasilda apk\u0101rt\u0113jos objektus. Kars\u0113\u0161anas caurules virsmas temperat\u016bra var p\u0101rsniegt 500 \u00b0C. Sild\u012b\u0161anas proces\u0101 tiek integr\u0113ti tr\u012bs izplat\u012bt\u0101kie siltuma p\u0101rneses veidi: siltuma vad\u012btsp\u0113ja, siltuma konvekcija un siltuma starojums, no kuriem galvenais ir siltuma starojums. T\u0101l\u0101k es iepaz\u012bstin\u0101\u0161u ar \u0161iem trim siltuma p\u0101rneses veidiem.<\/p>\n\n\n\n

Siltuma vad\u012btsp\u0113ja<\/h4>\n\n\n\n

Siltumvad\u012btsp\u0113ja<\/strong> attiecas uz procesu, kur\u0101 siltums tiek nodots no objekta da\u013cas ar augst\u0101ku temperat\u016bru uz objekta da\u013cu ar zem\u0101ku temperat\u016bru. Siltumvad\u012btsp\u0113ja notiek ciet\u0101s viel\u0101s, \u0161\u0137idrumos un g\u0101z\u0113s, bet, stingri \u0146emot, tikai ciet\u0101s viel\u0101s t\u0101 ir t\u012bra siltumvad\u012btsp\u0113ja. Pat stacion\u0101ros \u0161\u0137idrumos notiek dabisk\u0101 konvekcija, ko izraisa bl\u012bvuma starp\u012bba, ko rada temperat\u016bras gradients, t. i., \u0161\u0137idrumos vienlaikus notiek siltuma konvekcija un siltuma vad\u012btsp\u0113ja. Ikdien\u0101 bie\u017ei sastopams piem\u0113rs ir dzelzs stie\u0146a viena gala kars\u0113\u0161ana virs uguns un saj\u016bta, ka otrais gals k\u013c\u016bst karsts - t\u0101 ir siltuma vad\u012btsp\u0113ja. Cits piem\u0113rs ir l\u0101psti\u0146as rokturis, kas \u0113diena gatavo\u0161anas laik\u0101 k\u013c\u016bst karsts, un ar\u012b tas ir siltuma vad\u012btsp\u0113jas veids.<\/p>\n\n\n\n

Termisk\u0101 konvekcija<\/h4>\n\n\n\n

Termisk\u0101 konvekcija<\/strong>, ko d\u0113v\u0113 ar\u012b par konvekcijas siltuma p\u0101rnesi, ir siltuma p\u0101rneses process, ko izraisa da\u013ci\u0146u relat\u012bv\u0101 kust\u012bba \u0161\u0137idrum\u0101. \u0160is siltuma p\u0101rneses veids var notikt tikai \u0161\u0137idrumos (g\u0101z\u0113s un \u0161\u0137idrumos), un to vienm\u0113r pavada vad\u012btsp\u0113jai, ko izraisa \u0161\u0137idruma molekulu kust\u012bba.<\/p>\n\n\n\n

Termisko konvekciju var iedal\u012bt divos veidos:<\/p>\n\n\n\n