The page in the presentation regarding 190 C temperature and "hydrogenation" at 1000 psi regards the process of taking the 'empty' liquid and putting hydrogen into it. That process is done at the plant. So under elevated temperature and pressure, the liquid is hydrogenated. Once the hydrogen has been 'put in' and the temperature brought back down to ambient, the hydrogen can't come back out. You could have it sitting in an open cup and no hydrogen would break free from the carrier. In order to have the hydrogen separate from the carrier liquid, heat must be applied. Note also that a catalyst is used for both hydrogenation and dehydrogenation as indicated on sheet 4 of the presentation. Sheet 12 of the presentation shows rates of dehydrogenation given various temperatures and the overall conversion rate. Conversion rate is the percent of hydrogen removed from the liquid carrier.Topher925 said:If there was a leak at STP at about what rate would the H2 dissipate from the liquid? Your link has data for extraction at 190C+ under pressure but would the H2 sort of "extract" if there was a liquid leak from the storage tank?
Hydrogen storage on the blackboard involves using a chemical reaction to produce hydrogen gas and then collecting and storing it in a container. This can be achieved by using a metal such as zinc or aluminum, which reacts with an acid or base to release hydrogen gas.
Blackboard methods for hydrogen storage are relatively simple and inexpensive compared to other methods. They also do not require specialized equipment and can be easily scaled up for larger storage needs.
One limitation of blackboard methods is that they can only store small amounts of hydrogen at a time, making them more suitable for small-scale applications. They also require regular maintenance and monitoring to ensure the chemical reactions are still producing hydrogen gas.
Yes, hydrogen stored on a blackboard can be used as a fuel source. Once collected and stored, the hydrogen gas can be transferred to a fuel cell or combustion engine to produce energy. However, the amount of hydrogen produced from blackboard methods may not be sufficient for large-scale energy needs.
It is important to handle the chemicals used for blackboard hydrogen storage with caution, as they can be corrosive and produce flammable or explosive gases. Proper ventilation and protective gear should be used when conducting experiments. Additionally, the storage container for the collected hydrogen gas should be securely sealed and stored in a well-ventilated area away from any potential ignition sources.