EN 50380_2003[1]--铭牌要求-solarbe文库

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SVENSK STANDARD SS-EN 50380 Fastställd Utgåva Sida Ingår i Svenska Elektriska Kommissionen, SEK 2003-05-26 1 1 17 SEK Område 82 © Copyright SEK. Reproduction in any form without permission is prohibited. ICS 27.160 Denna standard är fastställd av Svenska Elektriska Kommissionen, SEK, som också kan lämna upplysningar om sakinnehållet i standarden. Postadress SEK, Box 1284, 164 29 KISTA Telefon 08 - 444 14 00. Telefax 08 - 444 14 30 E-post seksekom.se. Internet www.sekom.se Solceller Angivande av data för solcellsmoduler Datasheet and nameplate information for photovoltaic modules Som svensk standard gäller europastandarden EN 503802003. Den svenska standarden innehåller den officiella engelska språkversionen av EN 503802003. Standarder underlättar utvecklingen och höjer elsäkerheten Det finns många fördelar med att ha gemensamma tekniska regler för bl a säkerhet, prestanda, dokumentation, utförande och skötsel av elprodukter, elanläggningar och metoder. Genom att utforma sådana standarder blir säkerhetskraven tydliga och utvecklingskostnaderna rimliga samtidigt som marknadens acceptans för produkten eller tjänsten ökar. Många standarder inom elområdet beskriver tekniska lösningar och metoder som åstadkommer den elsäkerhet som föreskrivs av svenska myndigheter och av EU. SEK är Sveriges röst i standardiseringsarbetet inom elområdet Svenska Elektriska Kommissionen, SEK, svarar för standardiseringen inom elområdet i Sverige och samordnar svensk medverkan i internationell och europeisk standardisering. SEK är en ideell organisation med frivilligt deltagande från svenska myndigheter, företag och organisationer som vill medverka till och påverka utformningen av tekniska regler inom elektrotekniken. SEK samordnar svenska intressenters medverkan i SEKs tekniska kommittéer och stödjer svenska experters medverkan i internationella och europeiska projekt. Stora delar av arbetet sker internationellt Utformningen av standarder sker i allt väsentligt i internationellt och europeiskt samarbete. SEK är svensk nationalkommitté av International Electrotechnical Commission IEC och Comité Européen de Normalisation Electrotechnique CENELEC. Standardiseringsarbetet inom SEK är organiserat i referensgrupper bestående av ett antal tekniska kommittéer som speglar hur arbetet inom IEC och CENELEC är organiserat. Arbetet i de tekniska kommittéerna är öppet för alla svenska organisationer, företag, institutioner, myndigheter och statliga verk. Den årliga avgiften för deltagandet och intäkter från försäljning finansierar SEKs standardiseringsverksamhet och medlemsavgift till IEC och CENELEC. Var med och påverka Den som deltar i SEKs tekniska kommittéarbete har möjlighet att påverka framtida standarder och får tidig tillgång till information och dokumentation om utvecklingen inom sitt teknikområde. Arbetet och kontakterna med kollegor, kunder och konkurrenter kan gynnsamt påverka enskilda företags affärsutveckling och bidrar till deltagarnas egen kompetensutveckling. Du som vill dra nytta av dessa möjligheter är välkommen att kontakta SEKs kansli för mer information. SEK Box 1284 164 29 Kista Tel 08-444 14 00 www.sekom.se EUROPEAN STANDARD EN 50380 NORME EUROPÉENNE EUROPÄISCHE NORM March 2003 CENELEC European Committee for Electrotechnical Standardization Comité Européen de Normalisation Electrotechnique Europäisches Komitee für Elektrotechnische Normung Central Secretariat rue de Stassart 35, B - 1050 Brussels © 2003 CENELEC - All rights of exploitation in any form and by any means reserved worldwide for CENELEC members. Ref. No. EN 503802003 E ICS 27.160 English version Datasheet and nameplate information for photovoltaic modules Spécifications particulières et informations sur les plaques de constructeur pour les modules photovoltaïques Datenblatt- und Typenschildangaben von Photovoltaik-Modulen This European Standard was approved by CENELEC on 2002-12-01. CENELEC members are bound to comply with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this European Standard the status of a national standard without any alteration. Up-to-date lists and bibliographical references concerning such national standards may be obtained on application to the Central Secretariat or to any CENELEC member. This European Standard exists in three official versions English, French, German. A version in any other language made by translation under the responsibility of a CENELEC member into its own language and notified to the Central Secretariat has the same status as the official versions. CENELEC members are the national electrotechnical committees of Austria, Belgium, Czech Republic, Denmark, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Luxembourg, Malta, Netherlands, Norway, Portugal, Slovakia, Spain, Sweden, Switzerland and United Kingdom. EN 503802003 – 2 – Foreword This European Standard was prepared by the Technical Committee CENELEC TC 82 former BTTF 86-2, Solar photovoltaic energy systems. The text of the draft was submitted to the formal vote and was approved by CENELEC as EN 50380 on 2002-12-01. The following dates were fixed – latest date by which the EN has to be implemented at national level by publication of an identical national standard or by endorsement dop 2003-12-01 – latest date by which the national standards conflicting with the EN have to be withdrawn dow 2005-12-01 __________ – 3 – EN 503802003 Contents Page 1 Scope.4 2 Normative references 4 3 Data sheet information.4 3.1 Certificate 4 3.2 Constructive material 4 3.3 Electrical performance 4 3.4 General characteristics .5 3.5 Thermal characteristics.5 3.6 Characteristic quantities for system integration 5 3.7 Power rating and production tolerances .6 3.8 Data sheet language.7 4 Nameplate information.7 EN 503802003 – 4 – 1 Scope This document describes data sheet and nameplate information for non-concentrating photovoltaic modules. The intent of this document is to provide minimum information required to configure a safe and optimal system with photovoltaic modules. In this context, data sheet information is a technical description separate from the photovoltaic module. The nameplate is a sign in durable construction at or in the photovoltaic module. 2 Normative references This European Standard incorporates, by dated or undated reference, provisions from other publications. These normative references are cited at the appropriate places in the text, and the publications are listed hereafter. For dated references, subsequent amendments to or revisions of any of these publications apply to this European Standard only when incorporated in it by amendment or revision. For undated references, the latest edition of the publication referred to applies including amendments. EN 61215 1995 Crystalline silicon terrestrial photovoltaic PV modules – Design qualification and type approval IEC 612151993 EN 60904-1 1993 Photovoltaic devices – Part 1 Measurement of photovoltaic current-voltage characteristics IEC 60904-11987 EN 60904-3 1993 Photovoltaic devices – Part 3 Measurement principles for terrestrial photovoltaic PV solar devices with reference spectral irradiance data IEC 60904-31989 IEC 60904-9 1995 Photovoltaic devices – Part 9 Solar simulator performance requirements 3 Data sheet information 3.1 Certificate All relevant certificates shall be listed on the data sheet. 3.2 Constructive material The descriptions of the following materials used to build the PV module are required cell type and material; frame material; front cover type. 3.3 Electrical performance The characteristic quantities in 3.3.1 to 3.3.3 are required. 3.3.1 P max , I sc , V oc and V mpp at STC 1 000 W/m², 25 ± 2 °C, AM 1,5 according to EN 60904-3 For a-Si modules, nominal and minimum values of maximum output power at STC must also be specified. 3.3.2 P max , I sc , V oc and V mpp at at 800 W/m², NOCT, AM 1,5 3.3.3 Reduction of efficiency from an irradiance of 1 000 W/m² to 200 W/m² T Module 25 °C following EN 60904-1 – 5 – EN 503802003 NOTE 1 STC Standard Test Conditions 1 000 W/m² irradiance in the plane of module, module temperature 25 °C and a spectral distribution of irradiance according to air mass 1,5. NOTE 2 NOCT Nominal Operating Cell Temperature Module operation temperature at 800 W/m² irradiance in the plane of module, air temperature 20 °C, wind speed 1 m/s and open circuit condition. NOTE 3 P max maximum electrical power; V oc open circuit voltage “open circuit“; I sc short circuit current “short circuit“; V mpp voltage at point of maximum power “maximum power point“. 3.4 General characteristics Specify information about the connection box such as, dimensions, IP-rating, electrical connection technique e.g. connector or wiring outer dimensions length, width of photovoltaic module, total thickness of photovoltaic module, and the weight. NOTE More detailed information e.g. mounting instructions, detailed dimension drawings, kind and thickness of front cover is recommended. 3.5 Thermal characteristics 3.5.1 NOCT value is required. 3.5.2 Temperature coefficients TC in [1/K] of I sc and V oc are required. NOTE 1 With the help of temperature coefficients “TC”, the electrical characteristic quantity “y reference ” at the reference temperature “T reference ” can be transformed to another operating temperature “T“ y y reference [1 TC T - T reference ] NOTE 2 Temperature coefficients with the dimension [1/K] are calculated from “determination of temperature coefficients“ – EN 61215 qualification tests no additional measurements. NOTE 3 In the case that the TC is non-linear, give more information about the TC. 3.6 Characteristic quantities for system integration Required are 3.6.1 Design open circuit voltage ≡V oc at STC, maximum permissible system voltage and protection classification. 3.6.2 Limiting reverse current I R in [A] reverse current carrying capacity of the photovoltaic module. NOTE 1 Reverse current carrying capacity gives the maximal current for operation of photovoltaic module at V ≥ V oc without permanent damages of the photovoltaic module. For operation voltages higher than open circuit voltage module, the current changes its sign. From the view of the photovoltaic module, it is then a reverse current. NOTE 2 A photovoltaic module can be operated at the limiting reverse current I R V ≥ V oc at 60 ± 2 °C air temperature in the dark for eight hours without a change of maximum power P max of more than 5 at control measurements at STC after the test. P max and V oc are the values at STC see 3.3.1. EN 503802003 – 6 – EXAMPLE Example for an experimental implementation for determination of limiting reverse current see Figure 1. a Determination of maximum electrical power P max at STC at start of experiment. b Impressing a step-by-step increasing current I 1 to I N for V ≥ V oc for eight hours each at 60 ± 2 °C air temperature with no external irradiance V oc at STC after 3.3.1. c Assessment of photovoltaic module before and after each current step according to EN 61215 steps 10.1 to 10.3. d Maximum power at STC after step “i” current I i is P max,i . If ∆P | P max,i - P max | / P max ≤ 0,05 and ∆P | P max,i1 - P max | / P max 0,05, then the current I I I ∈ {1N} can be guaranteed as the limiting reverse current I R . V 1 I U I 1 I N I V N V I i 0 V oc Figure 1 – Schematic explanation of experimental set-up for determination of reverse current carrying capacity NOTE There are different definition systems for voltage and current arrows in use. Therefore this drawing may differ in some countries. 3.7 Power rating and production tolerances 3.7.1 Upper and lower production tolerances in percent for a given maximum power P max are required. NOTE It is possible to agree minimum power values. 3.7.2 The electrical characteristic quantities according to 3.3 have to be detected after pre-ageing in open circuit condition with ≥ 20 kWh/m² irradiance in the plane of module and considering the measurement tolerances of the external test laboratory. NOTE For pre-ageing, natural sunlight or a solar simulator according to IEC 60904-9 has to be used. – 7 – EN 503802003 EXAMPLE A PV module is rated with a nominal power of “P max “ of 50 watts at STC with consideration of pre-ageing at start of operation and production tolerances “± t” of ± 10 . This module is measured in an external test laboratory with measurement tolerances “± m” of ± 4 . In the unfavourable case lower tolerance limit, the photovoltaic module from production has an electrical power “P” of []       −⋅ 100 1 max t PP 1 In this example, P 45 watts. In the unfavourable case lower measurement tolerance, the external test laboratory measures the electrical power “P measurement ” of []       −⋅ 100 1 tmeasuremen m PP 2 In this example, P measurement 43,2 watts. This means in this example that a photovoltaic module, measured with 43,2 watts, agrees with the statement “Nominal power of 50 watts with production tolerances of ± 10 “. 3.8 Data sheet language The data sheet shall be written in English and a local language. 4 Nameplate information – Name and sign of origin of manufacturer or supplier, – Type designation, – Protection classification, – Permissible maximum system voltage, – P max ± production tolerances, I sc , V oc , V mpp all values at STC. NOTE 1 All labels and characteristic signs are in durable construction in or at the photovoltaic module. All labels must be written in English. NOTE 2 A serial number identification containing the name of the manufacturer and the serial number must be placed in such a way it is non-removable preferable by encapsulation and readable after installation. This serial number identification can be located e.g. at the edge of the photovoltaic module. It is allowed that this serial number identification is covered after installation by a frame e.g. in façade installations. NOTE 3 If it is not possible by the nature of the photovoltaic module to fix a nameplate, then it is necessary to announce the details according to Clause 4 to the user in other reliable, unambiguous and effective ways, e.g. in the accompanying documents operating instructions, data sheets. These documents are then part of the photovoltaic module. They have to be enclosed with every photovoltaic module. NOTE 4 STC must be defined as 1 000 W/m² and 25 °C cell temperature.