Presentation for RTD trainees - StorHy Hydrogen Storage

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Storage Material Magnesium Alanate • Mg(AlH4 ) 2 : Solvent-free and fast synthesis • Deuterised Mg(AlD4 ) 2 for neutron diffraction • Structure of Mg(AlH 4 ) 2 : Neutron and synchrotron X-ray diffraction • Details of thermal and isothermal decomposition of Mg(AlH4 ) 2 Sodium Alanate • Purification of NaAlH4 and synthesis of NaAlD4 Catalyst • Improved synthesis of catalyst: Ti13 *6THF Hydrogen and Fuel Cell Review Days 2007, Brussels 10th-11th October 2. Alignment to SRA/DS StorHy: Characterisation of Alanates First step: Magnesium and Sodium Alanates Automotive Challenges Scale-up strategies promising, but reversibility not sufficient! Source: IFE Source: FZK Scale-up strategies promising, but material storage density of 3 wt. % not sufficient Source: IFE, FZK
Storage Material Screening experiments for synthesis and characterization for new mixed alanates: • Mg-Al-Li-H, Mg-Al-Ca-H, Ca-Al-Li-H, Ca-Al-Na-H • Mg-Al-Li-H, Mg-Al-Ca-H, Mg-Al-Na-H, Mg-Al-K-H • Mg-Al-Li-H, Mg-Al-Ca-H, Ca-Al-K-H Synthesis and stabilisation of aluminium hydride AlH3 (Alane) – basic research purpose vial Hydrogen and Fuel Cell Review Days 2007, Brussels 10th-11th October 2. Alignment to SRA/DS StorHy: Screening for new Alanates Second step: Adaptation of work programme stainless steel impactor liquid nitrogen Spex 6750 freezer mill for cryomilling Source: IFE, FZK, GKSS INTENSITY (arb. units) 8000 6000 4000 2000 800 0 α'-AlD 3 and α-AlD 3 PND, Kjeller -800 10 20 30 40 50 60 70 80 90 100 110 120 130 2θ(º) Automotive Challenges No new reversible hydrogen storage compound found No break-through up to now High material storage density 10.1%, but not reversible! Simplified method to synthesize AlH 3 by milling at liquid nitrogen temperature, compared to wet chemistry Work in progress to change the stability of AlH 3
Page 1 and 2: STORHY “Hydrogen Storage Systems
Page 3 and 4: Source: Daimler Chrysler Gas: 700 b
Page 5 and 6: Consumer Expectations Driving range
Page 7 and 8: 700 bar Type III vessel with metall
Page 9 and 10: Hydrogen and Fuel Cell Review Days
Page 11 and 12: Ring winding head with modular siph
Page 13 and 14: High pressure H 2 V 1 Booster Coole
Page 15 and 16: Advanced C-H 2 700 bar filling devi
Page 17 and 18: Structure and coating concepts for
Page 19 and 20: Weight [kg] Mass comparison of gaso
Page 21: International technology watch �
Page 25 and 26: Calculated performance of tanks bas
Page 27 and 28: -90° Development of test procedure
Page 29 and 30: Multi-criteria evaluation � Five
Page 31 and 32: Medium-class Car: Fuel cell vehicle
Page 33 and 34: Today: Tomorrow: Bi-Fuel (L-H 2 + G
Page 35 and 36: L-H 2 storage � Storage densities
Page 37 and 38: Solid Storage (2) � Further resea
Page 43 and 44: Source: Dynetek Hydrogen and Fuel C
Page 45 and 46: Source: DC Hydrogen and Fuel Cell R
Page 47 and 48: Type Measure Effort Contribution IV
Page 49 and 50: Development of test procedures for
Page 51 and 52: Tests of optical fibre sensors for
Page 53 and 54: Cost reduction of C-H 2 storage sys
Page 55: Complex mixed Alanates: The followi

Presentation for RTD trainees - StorHy Hydrogen Storage

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