ISOLATION TRISO-SUPER 12 BOOST R Attestation d éligibilité aux dispositifs d incitation à la rénovation énergétique (CITE, CEE, aides de l ANAH, ) L éligibilité des matériaux d isolation aux dispositifs du crédit d impôts transition énergétique (CITE) et des certificats d économies d énergie (CEE) pour l isolation des rampants de toiture requiert une valeur de résistance thermique R 6 m 2.K/W. L éligibilité des matériaux d isolation réfléchissants à ces dispositifs est en outre subordonnée au respect de deux exigences particulières : - Afficher une valeur de résistance thermique mesurée selon la norme EN 16012. - Justifier cette valeur par un rapport d essai délivré par un organisme accrédité pour réaliser des tests selon la norme EN 16012. Pour les systèmes d isolation composés de plusieurs matériaux, l Administration exige également que chaque composant soit testé séparément selon la norme EN 16012 et que la résistance thermique du système soit ensuite calculée selon la norme EN ISO 6946 en fonction de la destination du produit (toitures, murs etc ). TRISO-SUPER 12 BOOST R étant un système d isolation, la résistance thermique de chacun de ses composants a été mesurée séparément selon la norme EN 16012 puis la résistance thermique du système a été déterminée par calcul selon la norme EN ISO 6946 pour sa destination en rampants de toiture. Norme Rapports d essai Composant TRISO HYBRID EN 16012 037-11 SF/15U Composant BOOST R HYBRID EN 16012 037-10 SF/15U Système TRISO-SUPER 12 BOOST R EN ISO 6946 037-10/11(C) SF/15 TRISO-SUPER 12 BOOST R affiche, quelque soit la configuration de toiture, une valeur de R > 6,21 m 2.KW justifiée par un rapport d essai délivré par un organisme accrédité pour réaliser des tests selon la norme EN 16012. Il est éligible aux dispositifs du crédit d impôts transition énergétique (CITE) et des certificats d économies d énergie (CEE) pour l isolation des rampants de toiture. Fait à Limoux le 01/12/2015, Robert MENRAS Directeur Juridique
INSTITUTE OF ARCHITECTURE AND CONSTRUCTION OF KAUNAS UNIVERSITY OF TECHNOLOGY LABORATORY OF BUILDING PHYSICS Notified Body number: 2018 TEST REPORT No. 037-10/11(C) SF/15 Date: 26 of November 2015 page (pages) 1 (3) Determination of installed thermal resistance into a roof of TRISO-SUPER 12 BOOST R according to EN ISO 6946:2007 Test method: (test name) Determination of installed thermal resistance into a roof of TRISO-SUPER 12 BOOST R according to EN ISO 6946:2007 (number of normative document or test method, description of test procedure, test uncertainty) Product name: TRISO-SUPER 12 BOOST R Customer: Manufacturer: Calculation results: (identification of the specimen) ACTIS SA Avenue de Catalogne, 11300 Limoux, France (name and address of enterprise) ACTIS SA Avenue de Catalogne, 11300 Limoux, France Roof slope angle, Calculation method reference no. Calculation result, R, (m 2 K)/W Flat roof ( = 0 ) EN ISO 6946:2007 6,22 Pitched roof ( = 20 ) EN ISO 6946:2007 6,29 Pitched roof ( = 30 ) EN ISO 6946:2007 6,33 Pitched roof ( = 45 ) EN ISO 6946:2007 6,40 R value for others pitched sloop (different value) can be determined by linear interpolation between two calculated R values Calculation made by: Laboratory of Building Physics, Institute of Architecture and Construction of Kaunas University of Technology (Name of the organization) Products used in calculation: TRISO HYBRID (test report no. 037-11 SF/15 U) BOOST R HYBRID (test report no. 037-10 SF/15 U) Additions information: Application, 2015-10-12 Annex: 1 Calculation results (the numbers of the annexes should be pointed out) Technical manager: J. Ramanauskas (approves the test results) (n., surname) (signature) Tested by K. Banionis (calculation made by) (n., surname) (signature) S.P. Validity the named data and results refer exclusively to the tested and described specimens. Notes on publication no part of this document may be photocopied, reproduced or translated to another language without the prior written consent of the Science Laboratory of Building Thermal Physics. Tunelio g. 60, LT - 44405 Kaunas, Lithuania (tel. +370 37 453558, +370 37 350799, fax +370 37 451810; Web site: www.ktu.edu/asi/en/ ; E.mail: statybine.fizika@ktu.lt
Laboratory of Building Physics IAC KUT TEST REPORT No. 037-10/11(C) SF/15 2 (3) Annex 1: Calculation results Table 1: Products R-core values according to LST EN 16012:2012+A1:2015 Product Calculated R-core thermal resistance, (m 2 K)/W TRISO HYBRID (test report n 037-11 SF/15 U) 2,750 BOOST R HYBRID (test report n 037-10 SF/15 U) 2,450 Figure 1. Roof construction design 1 Unventilated Air cavity # 1 2 TRISO HYBRID 3 Unventilated Air cavity # 2 4 BOOST' R' HYBRID 5 Ventilated Air cavity # 3 Table 2: Roof construction calculation results for slope = 0 (EN ISO 6946) TRISO-SUPER 12 BOOST' R' installed on roof Angle: α = 0 Layer R value Unit Ascendant Heat Flux (Winter period) Unventilated Air cavity # 1 0,448 m².k/w TRISO HYBRID 2,750 m².k/w Unventilated Air cavity # 2 0,473 m².k/w BOOST' R' HYBRID 2,450 m².k/w Ventilated Air cavity # 3 0,100 m².k/w R Total 6,22 m².k/w Table 3: Roof construction calculation results for slope = 20 (EN ISO 6946) TRISO-SUPER 12 BOOST' R' installed on roof Angle: α = 20 Layer R value Unit Ascendant Heat Flux (Winter period) Unventilated Air cavity # 1 0,482 m².k/w TRISO HYBRID 2,750 m².k/w Unventilated Air cavity # 2 0,511 m².k/w BOOST' R' HYBRID 2,450 m².k/w Ventilated Air cavity # 3 0,100 m².k/w R Total 6,29 m².k/w Validity the named data and results refer exclusively to the tested and described specimens. Notes on publication no part of this document may be photocopied, reproduced or translated to another language without the prior written consent of the Science Laboratory of Building Thermal Physics. Tunelio g. 60, LT - 44405 Kaunas, Lithuania (tel. +370 37 453558, +370 37 350799, fax +370 37 451810; Web site: www.ktu.edu/asi/en/ ; E.mail: statybine.fizika@ktu.lt
Laboratory of Building Physics IAC KUT TEST REPORT No. 037-10/11(C) SF/15 3 (3) Table 4: Roof construction calculation results for slope = 30 (EN ISO 6946) TRISO-SUPER 12 BOOST' R' installed on roof Angle: α = 30 Layer R value Unit Ascendant Heat Flux (Winter period) Unventilated Air cavity # 1 0,501 m².k/w TRISO HYBRID 2,750 m².k/w Unventilated Air cavity # 2 0,532 m².k/w BOOST' R' HYBRID 2,450 m².k/w Ventilated Air cavity # 3 0,100 m².k/w R Total 6,33 m².k/w Table 5: Roof construction calculation results for slope = 45 (EN ISO 6946) TRISO-SUPER 12 BOOST' R' installed on roof Angle: α = 45 Layer R value Unit Ascendant Heat Flux (Winter period) Unventilated Air cavity # 1 0,532 m².k/w TRISO HYBRID 2,750 m².k/w Unventilated Air cavity # 2 0,567 m².k/w BOOST' R' HYBRID 2,450 m².k/w Ventilated Air cavity # 3 0,100 m².k/w R Total 6,40 m².k/w Requirements for calculation validity: Calculations of R values are valid for a pitched roof ( α is generally from 10 to 45 ), and Ceiling (α is equal to 0 ), Calculations of R values are valid when TRISO-SUPER 12 BOOST R is installed from the internal side of the Roof or the external part of the Roof, Calculations of R values are valid when TRISO-SUPER 12 BOOST R is installed in agreement with the installation guidelines described into the manufacturer brochure, Calculations of R values are valid when unventilated air cavities are at least 20 mm thick. Validity the named data and results refer exclusively to the tested and described specimens. Notes on publication no part of this document may be photocopied, reproduced or translated to another language without the prior written consent of the Science Laboratory of Building Thermal Physics. Tunelio g. 60, LT - 44405 Kaunas, Lithuania (tel. +370 37 453558, +370 37 350799, fax +370 37 451810; Web site: www.ktu.edu/asi/en/ ; E.mail: statybine.fizika@ktu.lt