{"id":45432,"date":"2019-10-18T05:25:11","date_gmt":"2019-10-18T04:25:11","guid":{"rendered":"https:\/\/www.thermal-engineering.org\/quel-est-lexemple-de-la-premiere-loi-de-la-thermodynamique-sur-le-cycle-de-brayton-definition\/"},"modified":"2020-02-25T10:30:17","modified_gmt":"2020-02-25T09:30:17","slug":"quel-est-lexemple-de-la-premiere-loi-de-la-thermodynamique-sur-le-cycle-de-brayton-definition","status":"publish","type":"post","link":"https:\/\/www.thermal-engineering.org\/fr\/quel-est-lexemple-de-la-premiere-loi-de-la-thermodynamique-sur-le-cycle-de-brayton-definition\/","title":{"rendered":"L&#8217;exemple de le premi\u00e8re principe de la thermodynamique sur le cycle de Brayton &#8211; D\u00e9finition"},"content":{"rendered":"<div class=\"su-quote su-quote-style-default\">\n<div class=\"su-quote-inner su-clearfix\">L&#8217;exemple de le premi\u00e8re principe de la thermodynamique sur le cycle de Brayton montre pourquoi les ing\u00e9nieurs utilisent si souvent l&#8217;enthalpie dans les calculs de processus thermodynamiques.\u00a0G\u00e9nie thermique<\/div>\n<\/div>\n<div class=\"su-divider su-divider-style-dotted\"><\/div>\n<div class=\"lgc-column lgc-grid-parent lgc-grid-100 lgc-tablet-grid-100 lgc-mobile-grid-100 lgc-equal-heights lgc-first lgc-last\">\n<div class=\"inside-grid-column\">\n<div class=\"su-spacer\"><\/div>\n<h2>Exemple: Premi\u00e8re loi de la thermodynamique et du cycle de Brayton<\/h2>\n<p>Supposons le\u00a0<strong>cycle de Brayton id\u00e9al<\/strong>\u00a0qui d\u00e9crit le fonctionnement d\u2019un\u00a0<strong>moteur \u00e0 chaleur \u00e0\u00a0<\/strong><strong>pression constante<\/strong>\u00a0.\u00a0<strong>Les<\/strong>\u00a0moteurs \u00e0\u00a0<strong>turbine \u00e0 gaz<\/strong>\u00a0et les\u00a0<strong>turbor\u00e9acteurs modernes<\/strong>\u00a0suivent \u00e9galement le cycle de Brayton.\u00a0Ce cycle comprend quatre processus thermodynamiques:<\/p>\n<ol>\n<li>\n<figure id=\"attachment_16843\" class=\"wp-caption alignright\" aria-describedby=\"caption-attachment-16843\"><a href=\"https:\/\/thermal-engineering.org\/wp-content\/uploads\/2019\/05\/first-law-example-brayton-cycle.png\"><img loading=\"lazy\" class=\"size-medium wp-image-16843 lazy-loaded\" src=\"https:\/\/thermal-engineering.org\/wp-content\/uploads\/2019\/05\/first-law-example-brayton-cycle-300x244.png\" alt=\"premi\u00e8re loi - exemple - cycle de brayton\" width=\"300\" height=\"244\" data-lazy-type=\"image\" data-src=\"https:\/\/thermal-engineering.org\/wp-content\/uploads\/2019\/05\/first-law-example-brayton-cycle-300x244.png\" \/><\/a><figcaption id=\"caption-attachment-16843\" class=\"wp-caption-text\">Le cycle de Brayton id\u00e9al comprend quatre processus thermodynamiques.\u00a0Deux processus isentropiques et deux processus isobares.<\/figcaption><\/figure>\n<p><strong>Compression isentropique<\/strong>\u00a0&#8211; L&#8217;air ambiant est aspir\u00e9 dans le compresseur o\u00f9 il est mis sous pression (1 \u2192 2).\u00a0Le travail requis pour le compresseur est donn\u00e9 par\u00a0<strong>W\u00a0<\/strong><strong><sub>C<\/sub><\/strong><strong>\u00a0= H\u00a0<\/strong><strong><sub>2<\/sub><\/strong><strong>\u00a0&#8211; H\u00a0<\/strong><strong><sub>1<\/sub><\/strong><strong>\u00a0.<\/strong><\/li>\n<li><strong>Addition de chaleur isobare<\/strong>\u00a0&#8211; l&#8217;air comprim\u00e9 passe ensuite dans une chambre de combustion, o\u00f9 le carburant est br\u00fbl\u00e9 et o\u00f9 de l&#8217;air ou un autre moyen est chauff\u00e9 (2 \u2192 3).\u00a0C&#8217;est un processus \u00e0 pression constante, car la chambre est ouverte aux entr\u00e9es et aux sorties.\u00a0La chaleur nette ajout\u00e9e est donn\u00e9e par\u00a0<strong>Q\u00a0<\/strong><strong><sub>add<\/sub><\/strong><strong>\u00a0= H\u00a0<\/strong><strong><sub>3<\/sub><\/strong><strong>\u00a0&#8211; H\u00a0<\/strong><strong><sub>2<\/sub><\/strong><\/li>\n<li><strong>expansion isentropique<\/strong>\u00a0&#8211; l\u2019air chauff\u00e9, sous pression, se dilate ensuite dans une turbine et c\u00e8de de l\u2019\u00e9nergie.\u00a0Le travail effectu\u00e9 par turbine est donn\u00e9 par\u00a0<strong>W\u00a0<\/strong><strong><sub>T<\/sub><\/strong><strong>\u00a0= H\u00a0<\/strong><strong><sub>4<\/sub><\/strong><strong>\u00a0&#8211; H\u00a0<\/strong><strong><sub>3<\/sub><\/strong><\/li>\n<li><strong>rejet de chaleur isobare<\/strong>\u00a0&#8211; la chaleur r\u00e9siduelle doit \u00eatre rejet\u00e9e pour fermer le cycle.\u00a0La chaleur nette rejet\u00e9e est donn\u00e9e par\u00a0<strong>Q\u00a0<\/strong><strong><sub>re<\/sub><\/strong><strong>\u00a0= H\u00a0<\/strong><strong><sub>4<\/sub><\/strong><strong>\u00a0&#8211; H\u00a0<\/strong><strong><sub>1<\/sub><\/strong><\/li>\n<\/ol>\n<p>Comme on peut le constater, nous pouvons d\u00e9crire et calculer (par exemple, l\u2019efficacit\u00e9 thermodynamique) de tels cycles (de la m\u00eame mani\u00e8re pour le\u00a0<strong>cycle de Rankine<\/strong>\u00a0) en utilisant des\u00a0<a title=\"Qu'est-ce que l'enthalpie?\" href=\"https:\/\/www.nuclear-power.com\/nuclear-engineering\/thermodynamics\/what-is-energy-physics\/what-is-enthalpy\/\">enthalpies<\/a>\u00a0.<\/p>\n<\/div>\n<\/div>\n<div class=\"lgc-column lgc-grid-parent lgc-grid-100 lgc-tablet-grid-100 lgc-mobile-grid-100 lgc-equal-heights lgc-first lgc-last\">\n<div class=\"inside-grid-column\">\n<div class=\"su-accordion\">\n<div class=\"su-spoiler su-spoiler-style-default su-spoiler-icon-arrow\" data-anchor=\"References\">\n<div class=\"su-spoiler-content su-clearfix\">\n<p>&nbsp;<\/p>\n<\/div>\n<p>&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;&#8230;.<\/p>\n<p>Cet article est bas\u00e9 sur la traduction automatique de l&#8217;article original en anglais. Pour plus d&#8217;informations, voir l&#8217;article en anglais. Pouvez vous nous aider Si vous souhaitez corriger la traduction, envoyez-la \u00e0 l&#8217;adresse: translations@nuclear-power.com ou remplissez le formulaire de traduction en ligne. Nous appr\u00e9cions votre aide, nous mettrons \u00e0 jour la traduction le plus rapidement possible. Merci<\/p>\n<\/div>\n<\/div>\n<\/div>\n<\/div>\n","protected":false},"excerpt":{"rendered":"<p>L&#8217;exemple de le premi\u00e8re principe de la thermodynamique sur le cycle de Brayton montre pourquoi les ing\u00e9nieurs utilisent si souvent l&#8217;enthalpie dans les calculs de processus thermodynamiques.\u00a0G\u00e9nie thermique Exemple: Premi\u00e8re loi de la thermodynamique et du cycle de Brayton Supposons le\u00a0cycle de Brayton id\u00e9al\u00a0qui d\u00e9crit le fonctionnement d\u2019un\u00a0moteur \u00e0 chaleur \u00e0\u00a0pression constante\u00a0.\u00a0Les\u00a0moteurs \u00e0\u00a0turbine \u00e0 gaz\u00a0et &#8230; <a title=\"L&#8217;exemple de le premi\u00e8re principe de la thermodynamique sur le cycle de Brayton &#8211; D\u00e9finition\" class=\"read-more\" href=\"https:\/\/www.thermal-engineering.org\/fr\/quel-est-lexemple-de-la-premiere-loi-de-la-thermodynamique-sur-le-cycle-de-brayton-definition\/\" aria-label=\"En savoir plus sur L&#8217;exemple de le premi\u00e8re principe de la thermodynamique sur le cycle de Brayton &#8211; D\u00e9finition\">Lire la suite<\/a><\/p>\n","protected":false},"author":1,"featured_media":0,"comment_status":"closed","ping_status":"closed","sticky":false,"template":"","format":"standard","meta":[],"categories":[8],"tags":[],"yoast_head":"<!-- This site is optimized with the Yoast SEO plugin v15.4 - https:\/\/yoast.com\/wordpress\/plugins\/seo\/ -->\n<title>L&#039;exemple de la premi\u00e8re loi de la thermodynamique sur le cycle de Brayton - D\u00e9finition<\/title>\n<meta name=\"description\" content=\"L&#039;exemple de la premi\u00e8re loi de la thermodynamique sur le cycle de Brayton montre pourquoi les ing\u00e9nieurs utilisent si souvent l&#039;enthalpie dans les calculs de processus thermodynamiques. 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