Storage options

Comparison of volumetric, gravimetric energy capacity, and costs of various storage options. [Pg.373]

Burke, A.F. and Gardiner, M. Hydrogen Storage Options Technologies and Comparisons for Light-duty Vehicle Applications, Research Report UCD-ITS-RR-05-01, Institute of Transportation Studies, University of California, Davis, 2005. [Pg.379]

Sarkar, A. and Banerjee, R. Net energy analysis of hydrogen storage options, International Journal of Hydrogen Energy, 30,867-877, 2004. [Pg.379]

Lasher, S., Comparison of hydrogen storage options, NHA Annual Hydrogen Conference 2005, Washington, March 29-April 1, 2005. [Pg.407]

Table 6.2. Estimated storage potential of the most promising geological storage options...

Case study, Germany comparison of different storage options for surplus wind electricity... [Pg.485]

A summary of the simulation results is shown in Table 16.1. In the first scenario, no surplus electricity is generated, because the grid is extended to cope with this amount of wind energy. In the fourth scenario, the surplus electricity increases to 17.3% of the wind generation. If the surplus electricity should be used in a storage system, it is necessary to dimension the storage option. If the storage option should... [Pg.489]

The carbon emission reduction of the two considered storage options is calculated with reference to a conventional gas turbine or gas and steam turbine. The result is shown in Fig. 16.6. The emission reduction refers to 1 kWh surplus wind electricity. The black bars reflect the reference emissions of the conventional gas turbine (GT) and gas-steam turbines (GST). The other bars show the figures for the CAES and the hydrogen paths. The emissions that occur during the storage paths are marked in grey the emission reduction is visualised in grey and white stripes. [Pg.491]

For the economic comparison of the two storage options, the specific re-electrifi-cation costs of the stored wind energy are calculated. These costs are made up of the investment, operation and maintenance costs, input electricity costs (wind electricity) and the fuel costs (natural gas). As hydrogen technologies are not in a commercial state, the calculation is also performed with target costs for electrolysers. Carbon emissions are also monetarily included, assuming a certificate price of 20/t. Table 16.2 summarises the major economic assumptions. [Pg.491]

Figure 16.6. Carbon emission reduction for 1 kWh stored and re-electrified wind electricity for CAES and hydrogen storage options (Wietschel et al., 2006).

Automotive paths It has been shown that hydrogen as a storage option for surplus wind electricity has no advantages neither with respect to carbon emission reduction... [Pg.492]

In the scope of this case study, alternative storage options for surplus wind electricity production in the region of north-western Germany are analysed. One assumption is that today s limited grid capacity could be extended only by a certain amount. The comparison of the storage option is based on economic and ecological criteria. [Pg.495]

Big Chemical Encyclopedia

Chemical substances, components, reactions, process design ...