BS EN 62282-3-201:2017:2018 Edition
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Fuel cell technologies – Stationary fuel cell power systems. Performance test methods for small fuel cell power systems
| Published By | Publication Date | Number of Pages |
| BSI | 2018 | 82 |
IEC 62282-3-201:2017 provides test methods for the electrical, thermal and environmental performance of small stationary fuel cell power systems that meet the following criteria: – rated electric power output of less than 10 kW; – grid-connected/independent operation or stand-alone operation with single-phase AC output or 3-phase AC output not exceeding 1 000 V, or DC output not exceeding 1 500 V; – maximum allowable working pressure of less than 0,1 MPa (gauge) for the fuel and oxidant passages; – gaseous fuel (natural gas, liquefied petroleum gas, propane, butane, hydrogen, etc.) or liquid fuel (kerosene, methanol, etc.); – air as oxidant. This document describes type tests and their test methods only. This document covers fuel cell power systems whose primary purpose is the production of electric power. This new edition includes the following significant technical changes with respect to the previous edition: revision of test set-up, revision of measurement instruments, introduction of ramp-up test, introduction of rated operation cycle efficiency, introduction of electromagnetic compatibility (EMC) test, revision of exhaust gas test, introduction of typical durations of operation cycles.
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 2 | undefined |
| 7 | English CONTENTS |
| 11 | FOREWORD |
| 13 | INTRODUCTION |
| 14 | 1 Scope 2 Normative references |
| 15 | 3 Terms and definitions |
| 20 | 4 Symbols Tables Table 1 – Symbols and their meanings for electric/thermal performance |
| 22 | Figures Figure 1 – Symbol diagram |
| 23 | Table 2 – Additional symbols and their meanings for environmental performance |
| 24 | 5 Configuration of small stationary fuel cell power system |
| 25 | 6 Reference conditions 7 Heating value base Figure 2 – General configuration of small stationary fuel cell power system |
| 26 | 8 Test preparation 8.1 General 8.2 Uncertainty analysis 8.3 Data acquisition plan 9 Test set-up |
| 27 | Figure 3 – Test set-up for small stationary fuel cell power system fed with gaseous fuel which supplies electricity and useful heat |
| 28 | 10 Instruments and measurement methods 10.1 General Figure 4 – Test set-up for small stationary fuel cell power system fed with gaseous fuel which supplies only electricity |
| 29 | 10.2 Measurement instruments 10.3 Measurement points |
| 31 | 10.4 Minimum required measurement systematic uncertainty 11 Test conditions 11.1 Laboratory conditions |
| 32 | 11.2 Installation and operating conditions of the system 11.3 Power source conditions 11.4 Test fuel 12 Operating process |
| 33 | Figure 5 – Operating states of stationary fuel cell power system without battery |
| 34 | 13 Test plan Figure 6 – Operating states of stationary fuel cell power system with battery |
| 35 | 14 Type tests on electric/thermal performance 14.1 General 14.2 Fuel consumption test 14.2.1 Gaseous fuel consumption test |
| 38 | 14.2.2 Liquid fuel consumption test |
| 39 | 14.3 Electric power output test 14.3.1 General 14.3.2 Test method 14.3.3 Calculation of average net electric power output 14.4 Heat recovery test 14.4.1 General |
| 40 | 14.4.2 Test method 14.4.3 Calculation of average recovered thermal power |
| 41 | 14.5 Start-up test 14.5.1 General 14.5.2 Determination of state of charge of the battery |
| 42 | 14.5.3 Test method Figure 7 – Example of electric power chart during start-up time for system without battery |
| 43 | Figure 8 – Example of electric power chart during start-up time for system with battery |
| 44 | 14.5.4 Calculation of results Figure 9 – Example of liquid fuel supply systems |
| 45 | 14.6 Ramp-up test 14.6.1 General |
| 46 | 14.6.2 Test method 14.6.3 Calculation of results Figure 10 – Example of electric power chart during ramp-up for system without battery |
| 47 | 14.7 Storage state test 14.7.1 General 14.7.2 Test method 14.7.3 Calculation of average electric power input in storage state 14.8 Electric power output change test 14.8.1 General 14.8.2 Test method |
| 48 | Figure 11 – Electric power output change pattern for system without battery |
| 49 | 14.8.3 Calculation of electric power output change rate Figure 12 – Electric power output change pattern for system with battery Figure 13 – Example for electric power change stabilization criteria |
| 50 | 14.9 Shutdown test 14.9.1 General 14.9.2 Test method |
| 51 | 14.9.3 Calculation of results Figure 14 – Electric power chart during shutdown time |
| 52 | 14.10 Computation of efficiency 14.10.1 General 14.10.2 Electrical efficiency 14.10.3 Heat recovery efficiency |
| 53 | 14.10.4 Overall energy efficiency 14.11 Rated operation cycle efficiency 14.11.1 General 14.11.2 Calculation of the operation cycle fuel energy input |
| 54 | 14.11.3 Calculation of the operation cycle net electric energy output |
| 55 | 14.11.4 Calculation of the operation cycle electrical efficiency 14.12 Electromagnetic compatibility (EMC) test 14.12.1 General requirement |
| 56 | 14.12.2 Electrostatic discharge immunity test 14.12.3 Radiated, radio-frequency, electromagnetic field immunity test 14.12.4 Electrical fast transient/burst immunity test 14.12.5 Surge immunity test 14.12.6 Immunity test of conducted disturbances induced by radio-frequency fields 14.12.7 Power frequency magnetic field immunity test 14.12.8 Voltage dips and voltage interruptions |
| 57 | 14.12.9 Radiated disturbance (emission) measurement test 14.12.10 Conducted disturbance (emission) measurement test 14.12.11 Power line harmonics emission measurement test 15 Type tests on environmental performance 15.1 General 15.2 Noise test 15.2.1 General 15.2.2 Test conditions |
| 58 | Figure 15 – Noise measurement points for small stationary fuel cell power systems Table 3 – Compensation of readings against the effect of background noise |
| 59 | 15.2.3 Test method 15.2.4 Processing of data 15.3 Exhaust gas test 15.3.1 General 15.3.2 Components to be measured |
| 60 | 15.3.3 Test method 15.3.4 Processing of data |
| 70 | 15.4 Discharge water test 15.4.1 General 15.4.2 Test method 16 Test reports 16.1 General 16.2 Title page |
| 71 | 16.3 Table of contents 16.4 Summary report |
| 72 | Annex A (normative)Heating values for components of natural gases Table A.1 – Heating values for components of natural gases at various combustion reference conditions for ideal gas |
| 74 | Annex B (informative)Examples of composition for natural gases and propane gases Table B.1 – Example of composition for natural gas (%) |
| 75 | Table B.2 – Example of composition for propane gas (%) |
| 76 | Annex C (informative)Example of a test operation schedule Table C.1 – Example of a test operation schedule |
| 77 | Annex D (informative)Typical exhaust gas components Table D.1 – Typical exhaust gas components to be expected for typical fuels |
| 78 | Annex E (informative)Guidelines for the contents of detailed and full reports E.1 General E.2 Detailed report E.3 Full report |
| 79 | Annex F (informative)Selected duration of rated power operation Table F.1 – Selected duration of rated power operation |
| 80 | Bibliography |
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