{"id":1768,"date":"2025-08-06T03:52:49","date_gmt":"2025-08-06T03:52:49","guid":{"rendered":"https:\/\/nbaem.com\/?p=1768"},"modified":"2025-08-06T07:39:55","modified_gmt":"2025-08-06T07:39:55","slug":"maximum-operating-temperature-vs-curie-temperature","status":"publish","type":"post","link":"https:\/\/nbaem.com\/cs\/maximum-operating-temperature-vs-curie-temperature\/","title":{"rendered":"Vysv\u011btleno maxim\u00e1ln\u00ed provozn\u00ed teploty versus Curieova teplota u magnet\u016f"},"content":{"rendered":"<div class=\"post-single\">\n<div class=\"post-content\">\n<p>Sna\u017e\u00edte se pochopit rozd\u00edl mezi\u00a0<strong>Maxim\u00e1ln\u00ed provozn\u00ed teplota<\/strong>\u00a0a\u00a0<strong>Teplota Curie<\/strong>\u00a0kdy\u017e p\u0159ijde na magnetick\u00e9 materi\u00e1ly? Nejste sami. A\u0165 u\u017e jste in\u017een\u00fdr, kupuj\u00edc\u00ed nebo n\u00e1vrh\u00e1\u0159 pracuj\u00edc\u00ed s magnety v odv\u011btv\u00edch jako motory, senzory nebo elektronika, znalost t\u011bchto teplotn\u00edch limit\u016f je kl\u00ed\u010dov\u00e1 pro chytr\u00e9 rozhodov\u00e1n\u00ed.<\/p>\n<p>Pro\u010d? Proto\u017ee tyto teploty p\u0159\u00edmo ovliv\u0148uj\u00ed magnetick\u00fd v\u00fdkon, spolehlivost a \u017eivotnost va\u0161ich komponent\u016f. P\u0159es\u00e1hnete-li magnet nad\u00a0<strong>maxim\u00e1ln\u00ed provozn\u00ed teplotu<\/strong>, riskujete trval\u00e9 po\u0161kozen\u00ed nebo sn\u00ed\u017eenou \u00fa\u010dinnost. P\u0159ekro\u010d\u00edte-li\u00a0<strong>teplotu Curie<\/strong>, magnet ztr\u00e1c\u00ed sv\u00e9 magnetick\u00e9 vlastnosti \u00fapln\u011b \u2013 \u010dasto nevratn\u011b.<\/p>\n<p>V tomto \u010dl\u00e1nku zjist\u00edte, co odli\u0161uje tyto dva kl\u00ed\u010dov\u00e9 teplotn\u00ed body, jak ovliv\u0148uj\u00ed v\u00fdb\u011br va\u0161eho magnetick\u00e9ho materi\u00e1lu a jak jsou magnety NBAEM navr\u017eeny tak, aby splnily va\u0161e nejn\u00e1ro\u010dn\u011bj\u0161\u00ed tepeln\u00e9 po\u017eadavky. P\u0159ipraveni se pono\u0159it?<\/p>\n<h2>Co je Maxim\u00e1ln\u00ed provozn\u00ed teplota<\/h2>\n<p>Maxim\u00e1ln\u00ed provozn\u00ed teplota (MOT) je nejvy\u0161\u0161\u00ed teplota, p\u0159i kter\u00e9 m\u016f\u017ee magnetick\u00fd materi\u00e1l spolehliv\u011b fungovat bez v\u00fdznamn\u00e9 ztr\u00e1ty sv\u00fdch magnetick\u00fdch vlastnost\u00ed. Jednodu\u0161e \u0159e\u010deno, je to teplotn\u00ed limit, kter\u00fd byste nem\u011bli p\u0159ekro\u010dit, aby magnet dlouhodob\u011b fungoval spr\u00e1vn\u011b.<\/p>\n<p>Tato teplota je velmi d\u016fle\u017eit\u00e1 pro \u017eivotnost a spolehlivost produktu. Kdy\u017e magnet pracuje p\u0159i nebo pod sv\u00fdm MOT, zachov\u00e1v\u00e1 si s\u00edlu, stabilitu a v\u00fdkon. Ale pokud teplota p\u0159ekro\u010d\u00ed tento limit, magnet m\u016f\u017ee za\u010d\u00edt ztr\u00e1cet magnetizaci, co\u017e vede k probl\u00e9m\u016fm s v\u00fdkonem a dokonce k trval\u00e9mu po\u0161kozen\u00ed.<\/p>\n<p>Typick\u00e9 hodnoty MOT z\u00e1vis\u00ed na druhu magnetick\u00e9ho materi\u00e1lu:<\/p>\n<ul>\n<li><strong>Neodymov\u00e9 magnety:<\/strong>\u00a0Obvykle maj\u00ed MOT mezi 80\u00b0C a 150\u00b0C, v z\u00e1vislosti na t\u0159\u00edd\u011b a slo\u017een\u00ed.<\/li>\n<li><strong>Ferritov\u00e9 magnety:<\/strong>\u00a0Odoln\u011bj\u0161\u00ed v\u016f\u010di teplu, \u010dasto s MOT a\u017e 250\u00b0C a\u017e 300\u00b0C.<\/li>\n<li><strong>Samarium-kobaltov\u00e9 magnety:<\/strong>\u00a0Zn\u00e1m\u00e9 pro vy\u0161\u0161\u00ed MOT, n\u011bkdy a\u017e do 350\u00b0C.<\/li>\n<\/ul>\n<p>N\u011bkolik faktor\u016f ovliv\u0148uje MOT:<\/p>\n<ul>\n<li>Slo\u017een\u00ed materi\u00e1lu a t\u0159\u00edda<\/li>\n<li>Kvalita v\u00fdroby a povlaky<\/li>\n<li>S\u00edla magnetick\u00e9ho pole a zat\u011b\u017eovac\u00ed podm\u00ednky<\/li>\n<li>Environment\u00e1ln\u00ed faktory jako vlhkost a mechanick\u00fd stres<\/li>\n<\/ul>\n<p>P\u0159ekro\u010den\u00ed maxim\u00e1ln\u00ed provozn\u00ed teploty vede k postupn\u00e9mu sni\u017eov\u00e1n\u00ed v\u00fdkonu. To znamen\u00e1\u00a0<strong>kles\u00e1 magnetick\u00e1 s\u00edla<\/strong>, magnet se st\u00e1v\u00e1 nestabiln\u00edm a jeho celkov\u00e1 \u017eivotnost se zkracuje. Po\u0161kozen\u00ed m\u016f\u017ee b\u00fdt nevratn\u00e9, pokud teplota z\u016fst\u00e1v\u00e1 dlouhodob\u011b vysok\u00e1, co\u017e sni\u017euje spolehlivost a zp\u016fsobuje n\u00e1kladn\u00e9 poruchy v aplikac\u00edch jako jsou motory, senzory nebo elektronika.<\/p>\n<p>Porozum\u011bn\u00ed MOT pom\u00e1h\u00e1 in\u017een\u00fdr\u016fm a u\u017eivatel\u016fm vybrat spr\u00e1vn\u00fd typ magnetu a navrhnout vhodn\u00e9 tepeln\u00e9 \u0159\u00edzen\u00ed, aby se p\u0159ede\u0161lo selh\u00e1n\u00ed za re\u00e1ln\u00fdch provozn\u00edch podm\u00ednek.<\/p>\n<h2>Co je Curieova teplota<\/h2>\n<p><img decoding=\"async\" src=\"https:\/\/artseo.cn\/apis\/uploads\/20250806\/Curie_Temperature_and_Ferromagnetic_Phase_Transition_wWb.webp\" alt=\"Teplota Curie a p\u0159echod feromagnetick\u00e9 f\u00e1ze\" \/><\/p>\n<p>Curieova teplota je bod, ve kter\u00e9m magnetick\u00fd materi\u00e1l ztr\u00e1c\u00ed sv\u00e9 trval\u00e9 magnetick\u00e9 vlastnosti. Je to z\u00e1kladn\u00ed vlastnost spojen\u00e1 s fyzikou magnetismu. Pod touto teplotou jsou materi\u00e1ly jako neodym nebo ferrit feromagnetick\u00e9, co\u017e znamen\u00e1, \u017ee jejich atomov\u00e9 magnetick\u00e9 momenty se se\u0159ad\u00ed a vytv\u00e1\u0159ej\u00ed siln\u00e1 magnetick\u00e1 pole. Jakmile materi\u00e1l dos\u00e1hne Curieovy teploty, projde f\u00e1zovou p\u0159em\u011bnou a st\u00e1v\u00e1 se paramagnetick\u00fdm. V tomto stavu jsou magnetick\u00e9 momenty atom\u016f n\u00e1hodn\u011b orientovan\u00e9, co\u017e zp\u016fsobuje ztr\u00e1tu magnetick\u00e9 s\u00edly materi\u00e1lu.<\/p>\n<p>Typick\u00e9 Curieovy teploty se li\u0161\u00ed podle materi\u00e1lu. Nap\u0159\u00edklad magnety z neodymu maj\u00ed Curieovu teplotu kolem 310 a\u017e 400\u00b0C, v z\u00e1vislosti na jejich p\u0159esn\u00e9m slo\u017een\u00ed, zat\u00edmco ferritov\u00e9 magnety obvykle dosahuj\u00ed kolem 450\u00b0C a\u017e 460\u00b0C. Jakmile magnet p\u0159ekro\u010d\u00ed tuto teplotu, jeho magnetick\u00e9 vlastnosti se ji\u017e neobnov\u00ed. Tato ztr\u00e1ta je trval\u00e1 \u2013 p\u0159ekro\u010den\u00ed Curieovy teploty v podstat\u011b znemo\u017e\u0148uje magnetu fungovat jako magnet.<\/p>\n<p>Porozum\u011bn\u00ed Curieov\u011b teplot\u011b je kl\u00ed\u010dov\u00e9 pro pr\u016fmysly vyu\u017e\u00edvaj\u00edc\u00ed magnetick\u00e9 materi\u00e1ly, proto\u017ee stanovuje absolutn\u00ed teplotn\u00ed limit, za kter\u00fdm nelze magnetick\u00fd v\u00fdkon obnovit.<\/p>\n<h2>Porovn\u00e1n\u00ed maxim\u00e1ln\u00ed provozn\u00ed teploty a Curieovy teploty<\/h2>\n<p>S\u00edla\u00a0<strong>Maxim\u00e1ln\u00ed provozn\u00ed teplota<\/strong>\u00a0a\u00a0<strong>Teplota Curie<\/strong>\u00a0oba jsou d\u016fle\u017eit\u00e9 p\u0159i pr\u00e1ci s magnetick\u00fdmi materi\u00e1ly, ale znamenaj\u00ed velmi odli\u0161n\u00e9 v\u011bci.<\/p>\n<ul>\n<li><strong>Maxim\u00e1ln\u00ed provozn\u00ed teplota<\/strong>\u00a0je nejvy\u0161\u0161\u00ed teplota, kterou m\u016f\u017ee magnet bezpe\u010dn\u011b zvl\u00e1dnout, ani\u017e by ztratil v\u00fdkon nebo utrp\u011bl po\u0161kozen\u00ed v pr\u016fb\u011bhu \u010dasu.<\/li>\n<li><strong>Teplota Curie<\/strong>\u00a0je bod, ve kter\u00e9m materi\u00e1l magnetu zcela ztr\u00e1c\u00ed sv\u00e9 feromagnetick\u00e9 vlastnosti \u2013 p\u0159est\u00e1v\u00e1 b\u00fdt magnetick\u00fd.<\/li>\n<\/ul>\n<h3>Pro\u010d je maxim\u00e1ln\u00ed provozn\u00ed teplota ni\u017e\u0161\u00ed ne\u017e Curieova teplota<\/h3>\n<p>V\u00fdrobci stanovuj\u00ed maxim\u00e1ln\u00ed provozn\u00ed teplotu v\u00fdrazn\u011b pod Curieovou teplotou. To je proto, \u017ee pod Curieov\u00fdm bodem magnety st\u00e1le funguj\u00ed, ale mohou za\u010d\u00edt ztr\u00e1cet s\u00edlu, pokud jsou p\u0159eh\u0159\u00e1ty nebo jsou vystaveny vysok\u00fdm teplot\u00e1m po del\u0161\u00ed dobu. Udr\u017eov\u00e1n\u00ed pod maxim\u00e1ln\u00ed provozn\u00ed teplotou zaji\u0161\u0165uje del\u0161\u00ed \u017eivotnost magnetu bez ztr\u00e1ty v\u00fdkonu nebo nevratn\u00e9ho po\u0161kozen\u00ed.<\/p>\n<p>Nap\u0159\u00edklad magnet z neodymu m\u016f\u017ee m\u00edt Curieovu teplotu kolem 310\u2013320\u00b0C, ale maxim\u00e1ln\u00ed provozn\u00ed teplotu bl\u00ed\u017ee 80\u2013150\u00b0C, v z\u00e1vislosti na t\u0159\u00edd\u011b. P\u0159i provozu bl\u00edzko nebo nad Curieovou teplotou doch\u00e1z\u00ed k trval\u00e9 ztr\u00e1t\u011b magnetismu, zat\u00edmco p\u0159ekro\u010den\u00ed maxim\u00e1ln\u00ed provozn\u00ed teploty postupn\u011b oslabuje magnet.<\/p>\n<h3>Rizika p\u0159ekro\u010den\u00ed t\u011bchto teplot<\/h3>\n<ul>\n<li>\n<h3>Nad maxim\u00e1ln\u00ed provozn\u00ed teplotu:<\/h3>\n<p>Hroz\u00ed v\u00e1m urychlen\u00e1 ztr\u00e1ta magnetick\u00e9 s\u00edly, mechanick\u00e9 selh\u00e1n\u00ed nebo zkr\u00e1cen\u00ed \u017eivotnosti produktu. Jedn\u00e1 se o pomal\u00fd \u00fabytek v\u00fdkonu.<\/li>\n<li>\n<h3>Nad teplotu Curie:<\/h3>\n<p>Magnetick\u00fd materi\u00e1l proch\u00e1z\u00ed f\u00e1zovou zm\u011bnou z feromagnetick\u00e9ho na paramagnetick\u00fd. Tato zm\u011bna je za norm\u00e1ln\u00edch podm\u00ednek nevratn\u00e1, co\u017e m\u00e1 za n\u00e1sledek trvalou ztr\u00e1tu magnetismu.<\/li>\n<\/ul>\n<h3>B\u011b\u017en\u00e9 myln\u00e9 p\u0159edstavy<\/h3>\n<ul>\n<li>N\u011bkte\u0159\u00ed si mysl\u00ed, \u017ee magnety p\u0159estanou fungovat okam\u017eit\u011b po dosa\u017een\u00ed maxim\u00e1ln\u00ed provozn\u00ed teploty. Ve skute\u010dnosti je to sp\u00ed\u0161e varovn\u00fd limit \u2014 ne okam\u017eit\u00fd bod selh\u00e1n\u00ed.<\/li>\n<li>Jin\u00ed zam\u011b\u0148uj\u00ed maxim\u00e1ln\u00ed provozn\u00ed teplotu s teplotou Curie, p\u0159edpokl\u00e1daj\u00edce, \u017ee jsou t\u00e9m\u011b\u0159 stejn\u00e9. Nen\u00ed to tak. Maxim\u00e1ln\u00ed provozn\u00ed teplota je bezpe\u010dn\u00fd provozn\u00ed limit; teplota Curie je fyzik\u00e1ln\u00ed pr\u00e1h, kde magnetismus miz\u00ed.<\/li>\n<\/ul>\n<p>Pozn\u00e1n\u00ed rozd\u00edlu pom\u00e1h\u00e1 vyhnout se n\u00e1kladn\u00fdm chyb\u00e1m a zaji\u0161\u0165uje spolehliv\u00fd v\u00fdkon magnet\u016f v re\u00e1ln\u00fdch aplikac\u00edch.<\/p>\n<h2>Praktick\u00e9 d\u016fsledky pro in\u017een\u00fdry a kupuj\u00edc\u00ed<\/h2>\n<p><img decoding=\"async\" src=\"https:\/\/artseo.cn\/apis\/uploads\/20250806\/Magnet_Temperature_Selection_Guide_Jyd.webp\" alt=\"Pr\u016fvodce v\u00fdb\u011brem teploty magnetu\" \/><\/p>\n<p>Znalost rozd\u00edlu mezi maxim\u00e1ln\u00ed provozn\u00ed teplotou a teplotou Curie je kl\u00ed\u010dov\u00e1 p\u0159i v\u00fdb\u011bru magnet\u016f pro motory, senzory, elektroniku a dal\u0161\u00ed aplikace. Tady je d\u016fvod, pro\u010d je to d\u016fle\u017eit\u00e9:<\/p>\n<ul>\n<li>\n<h3>V\u00fdb\u011br spr\u00e1vn\u00e9ho magnetu<\/h3>\n<p>Porozum\u011bn\u00ed t\u011bmto teplotn\u00edm limit\u016fm v\u00e1m pom\u016f\u017ee vybrat magnety, kter\u00e9 neztrat\u00ed s\u00edlu nebo se nerozpadnou v provozn\u00edm prost\u0159ed\u00ed va\u0161eho za\u0159\u00edzen\u00ed. Nap\u0159\u00edklad neodymov\u00e9 magnety nab\u00edzej\u00ed velkou s\u00edlu, ale maj\u00ed ni\u017e\u0161\u00ed maxim\u00e1ln\u00ed provozn\u00ed teploty ve srovn\u00e1n\u00ed s ferritov\u00fdmi magnety, kter\u00e9 zvl\u00e1dnou vy\u0161\u0161\u00ed teploty, ale s men\u0161\u00ed magnetickou silou.<\/li>\n<li>\n<h3>Tepeln\u00e1 spr\u00e1va a n\u00e1vrh<\/h3>\n<p>Nejde jen o v\u00fdb\u011br magnetu. Dobr\u00e1 tepeln\u00e1 spr\u00e1va \u2014 nap\u0159\u00edklad chladi\u010de, chladic\u00ed syst\u00e9my nebo spr\u00e1vn\u00fd proud vzduchu \u2014 udr\u017euje magnety v jejich bezpe\u010dn\u00e9m provozn\u00edm rozsahu, \u010d\u00edm\u017e se p\u0159edch\u00e1z\u00ed n\u00e1kladn\u00fdm selh\u00e1n\u00edm nebo sn\u00ed\u017een\u00e9mu v\u00fdkonu v pr\u016fb\u011bhu \u010dasu.<\/li>\n<li>\n<h3>Z\u00e1ruka a bezpe\u010dnostn\u00ed aspekty<\/h3>\n<p>Provoz magnet\u016f nad jejich maxim\u00e1ln\u00ed provozn\u00ed teplotou m\u016f\u017ee zru\u0161it z\u00e1ruky a p\u0159edstavovat bezpe\u010dnostn\u00ed rizika. P\u0159ebyte\u010dn\u00e9 teplo nezp\u016fsobuje jen sn\u00ed\u017een\u00ed magnetick\u00e9 s\u00edly \u2014 m\u016f\u017ee tak\u00e9 zp\u016fsobit nevratn\u00e9 po\u0161kozen\u00ed, zvl\u00e1\u0161t\u011b kdy\u017e teploty bl\u00ed\u017e\u00ed teplot\u011b Curie.<\/li>\n<li>\n<h3>Dlouhodob\u00fd v\u00fdkon<\/h3>\n<p>Dodr\u017eov\u00e1n\u00ed t\u011bchto teplotn\u00edch mez\u00ed znamen\u00e1 spolehliv\u011bj\u0161\u00ed a konzistentn\u011bj\u0161\u00ed v\u00fdkon magnet\u016f po celou dobu \u017eivotnosti va\u0161eho produktu. To se prom\u00edt\u00e1 do m\u00e9n\u011b v\u00fdm\u011bn a probl\u00e9m\u016f s \u00fadr\u017ebou v budoucnu.<\/li>\n<\/ul>\n<p>Pro v\u00edce informac\u00ed o v\u00fdb\u011bru magnet\u016f odoln\u00fdch vysok\u00fdm teplot\u00e1m si prohl\u00e9dn\u011bte nab\u00eddku NBAEM.\u00a0<a href=\"https:\/\/nbaem.com\/cs\/high-temperature-magnets\/\" target=\"_blank\" rel=\"noopener\">magnety s vysokou teplotou<\/a>. Nab\u00edzej\u00ed spolehliv\u00e1 \u0159e\u0161en\u00ed p\u0159izp\u016fsoben\u00e1 n\u00e1ro\u010dn\u00fdm tepeln\u00fdm prost\u0159ed\u00edm, co\u017e zaji\u0161\u0165uje nejlep\u0161\u00ed v\u00fdkon a odolnost pro va\u0161e projekty.<\/p>\n<h2>P\u0159\u00edstup NBAEM k teplotn\u011b odoln\u00fdm magnetick\u00fdm materi\u00e1l\u016fm<\/h2>\n<p>Ve spole\u010dnosti NBAEM ch\u00e1peme v\u00fdzvy spojen\u00e9 s prac\u00ed s magnety v prost\u0159ed\u00edch s vysokou teplotou. Proto se na\u0161e produktov\u00e1 \u0159ada zam\u011b\u0159uje na magnetick\u00e9 materi\u00e1ly navr\u017een\u00e9 tak, aby spolehliv\u011b fungovaly i bl\u00edzko sv\u00fdch maxim\u00e1ln\u00edch provozn\u00edch teplotn\u00edch limit\u016f. A\u0165 u\u017e pot\u0159ebujete neodymov\u00e9 magnety s vylep\u0161enou tepelnou odolnost\u00ed nebo ferritov\u00e9 magnety, kter\u00e9 odol\u00e1vaj\u00ed teplu, nab\u00edz\u00edme mo\u017enosti ur\u010den\u00e9 pro n\u00e1ro\u010dn\u00e9 pr\u016fmyslov\u00e9 aplikace.<\/p>\n<p>N\u00e1\u0161 v\u00fdrobn\u00ed proces je p\u0159izp\u016fsoben\u00fd pro tepelnou stabilitu. Pou\u017e\u00edv\u00e1me p\u0159esn\u00e9 techniky sintrov\u00e1n\u00ed a povrchov\u00fdch \u00faprav, kter\u00e9 minimalizuj\u00ed magnetickou degradaci a udr\u017euj\u00ed s\u00edlu magnetu konzistentn\u00ed v \u010dase. Nav\u00edc pe\u010dliv\u011b kontrolujeme slo\u017een\u00ed materi\u00e1lu, aby na\u0161e magnety neztr\u00e1cely sv\u00e9 vlastnosti, kdy\u017e se bl\u00ed\u017e\u00ed teplotn\u00edm limit\u016fm.<\/p>\n<p>P\u0159izp\u016fsoben\u00ed je kl\u00ed\u010dovou sou\u010d\u00e1st\u00ed na\u0161\u00ed pr\u00e1ce. NBAEM m\u016f\u017ee upravit t\u0159\u00eddy magnet\u016f a povrchov\u00e9 \u00fapravy tak, aby odpov\u00eddaly va\u0161im specifick\u00fdm tepeln\u00fdm po\u017eadavk\u016fm, co\u017e v\u00e1m pom\u016f\u017ee naj\u00edt spr\u00e1vnou rovnov\u00e1hu mezi n\u00e1klady a v\u00fdkonem. To je obzvl\u00e1\u0161\u0165 u\u017eite\u010dn\u00e9 pro motory, senzory a elektroniku, kter\u00e9 pracuj\u00ed za n\u00e1ro\u010dn\u00fdch podm\u00ednek.<\/p>\n<p>Nap\u0159\u00edklad jeden klient z automobilov\u00e9ho sektoru vyu\u017eil na\u0161e vysokoteplotn\u00ed neodymov\u00e9 magnety pro prototyp elektrick\u00e9ho motoru. S na\u0161\u00edm p\u0159izp\u016fsoben\u00fdm \u0159e\u0161en\u00edm si udr\u017eeli magnetickou s\u00edlu a\u017e do 120\u00b0C, co\u017e je v\u00fdrazn\u011b nad standardn\u00edmi limity, \u010d\u00edm\u017e zlep\u0161ili celkovou \u00fa\u010dinnost a odolnost motoru.<\/p>\n<p>Stru\u010dn\u011b \u0159e\u010deno, p\u0159\u00edstup NBAEM kombinuje v\u011bdu o materi\u00e1lech a flexibiln\u00ed v\u00fdrobu, aby splnil jedine\u010dn\u00e9 pot\u0159eby z\u00e1kazn\u00edk\u016f na trhu v \u010cesk\u00e9 republice, kte\u0159\u00ed po\u017eaduj\u00ed vysokov\u00fdkonn\u00e9 magnety za tepla.<\/p>\n<\/div>\n<div class=\"post-footer\">\n<div class=\"post-tags\">\n<div class=\"article-categories\"><\/div>\n<\/div>\n<\/div>\n<\/div>\n<nav class=\"post-navigation thw-sept\">\n<div class=\"row no-gutters\">\n<div class=\"col-12 col-md-6\">\n<div class=\"post-previous\"><\/div>\n<\/div>\n<\/div>\n<\/nav>","protected":false},"excerpt":{"rendered":"<p>Objevte kl\u00ed\u010dov\u00e9 rozd\u00edly mezi Maxim\u00e1ln\u00ed provozn\u00ed teplotou a Curie teplotou v magnetick\u00fdch materi\u00e1lech pro optim\u00e1ln\u00ed v\u00fdkon a spolehlivost.<\/p>","protected":false},"author":1,"featured_media":1766,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"om_disable_all_campaigns":false,"_mi_skip_tracking":false,"footnotes":""},"categories":[1],"tags":[],"class_list":["post-1768","post","type-post","status-publish","format-standard","has-post-thumbnail","hentry","category-uncategorized"],"jetpack_featured_media_url":"https:\/\/nbaem.com\/wp-content\/uploads\/2025\/08\/Curie_Temperature_and_Ferromagnetic_Phase_Transition_wWb.webp","_links":{"self":[{"href":"https:\/\/nbaem.com\/cs\/wp-json\/wp\/v2\/posts\/1768","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/nbaem.com\/cs\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/nbaem.com\/cs\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/nbaem.com\/cs\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/nbaem.com\/cs\/wp-json\/wp\/v2\/comments?post=1768"}],"version-history":[{"count":2,"href":"https:\/\/nbaem.com\/cs\/wp-json\/wp\/v2\/posts\/1768\/revisions"}],"predecessor-version":[{"id":1813,"href":"https:\/\/nbaem.com\/cs\/wp-json\/wp\/v2\/posts\/1768\/revisions\/1813"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/nbaem.com\/cs\/wp-json\/wp\/v2\/media\/1766"}],"wp:attachment":[{"href":"https:\/\/nbaem.com\/cs\/wp-json\/wp\/v2\/media?parent=1768"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/nbaem.com\/cs\/wp-json\/wp\/v2\/categories?post=1768"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/nbaem.com\/cs\/wp-json\/wp\/v2\/tags?post=1768"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}