<?xml version="1.0" encoding="UTF-8" ?><OAI-PMH xmlns="http://www.openarchives.org/OAI/2.0/" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://www.openarchives.org/OAI/2.0/ http://www.openarchives.org/OAI/2.0/OAI-PMH.xsd"><responseDate>2026-07-06T07:19:26Z</responseDate><request identifier="10.35097/1483" metadataPrefix="datacite" verb="GetRecord">https://www.radar-service.eu/oai/OAIHandler</request><GetRecord><record><header><identifier>10.35097/1483</identifier><datestamp>2023-11-15T14:45:02Z</datestamp><setSpec>radar4kit</setSpec></header><metadata><resource xmlns="http://datacite.org/schema/kernel-4"
          xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance"
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   <identifier identifierType="DOI">10.35097/1483</identifier>
   <creators>
      <creator>
         <creatorName>Lyons, K.</creatorName>
         <givenName>K.</givenName>
         <familyName>Lyons</familyName>
         <affiliation/>
      </creator>
   </creators>
   <titles>
      <title>Fuel Cells and Hydrogen Joint Undertaking (FCH JU)</title>
   </titles>
   <publisher>Karlsruhe Institute of Technology</publisher>
   <dates>
      <date dateType="Created">2021</date>
   </dates>
   <publicationYear>2023</publicationYear>
   <subjects>
      <subject>Engineering</subject>
      <subject>Liquid hydrogen</subject>
      <subject>dispersion</subject>
      <subject>ignition</subject>
      <subject>congestion</subject>
      <subject>explosion</subject>
   </subjects>
   <resourceType resourceTypeGeneral="Dataset"/>
   <rightsList>
      <rights rightsURI="info:eu-repo/semantics/openAccess">Open Access</rights>
      <rights schemeURI="https://spdx.org/licenses/"
              rightsIdentifierScheme="SPDX"
              rightsIdentifier="CC-BY-SA-4.0"
              rightsURI="https://creativecommons.org/licenses/by-sa/4.0/legalcode">Creative Commons Attribution Share Alike 4.0 International</rights>
   </rightsList>
   <contributors>
      <contributor contributorType="RightsHolder">
         <contributorName>Lyons, K.</contributorName>
      </contributor>
   </contributors>
   <descriptions>
      <description descriptionType="Abstract">Work package five of the PRESLHY project focusses on the combustion phenomena of liquid&#xD;
hydrogen (LH 2 ). The experimental programme was designed to provide insight into a number&#xD;
of credible and poorly understood LH 2 combustion scenarios. One such scenario is the effect of&#xD;
congestion or confinement on an ignited hydrogen cloud stemming from a release of LH 2 ,&#xD;
potentially leading to deflagration to detonation transition (DDT).&#xD;
This report summarises the large-scale experiments carried out at the HSE Science and&#xD;
Research Centre in Buxton investigating the effect of differing levels of congestion and&#xD;
confinement on the combustion properties of a hydrogen cloud developing from a release of&#xD;
LH2.&#xD;
Various combustion parameters were measured, including; the overpressure, heat flux, and&#xD;
noise. Monitoring of ambient and release conditions were also made to allow for a thorough&#xD;
analysis of the results. A total of 23 ignited trials were completed and involved releasing LH2&#xD;
using the same initial conditions as in the rainout experiments of work package 3, meaning that&#xD;
the dispersion patterns should remain similar.&#xD;
The congestion and confinement was created by a configurable steel structure placed directly in&#xD;
the path of the release. Two congestion levels, confinement and pool experiments were&#xD;
planned, however due to the safe noise level being reached, only the congestion experiments&#xD;
were completed. To compensate for this, multiple repeats and experiments with a wide variety&#xD;
of source conditions were conducted.&#xD;
From the results, it is clear that higher levels of volumetric congestion increases the measured&#xD;
overpressures in releases with the same initial conditions. The results also show that an&#xD;
increasing hydrogen inventory, either through an increased release pressure or larger nozzle,&#xD;
can result in a larger event upon ignition. However, the mixing of the jet also plays a part;&#xD;
some releases through the largest release orifice diameter showed lower overpressures&#xD;
potentially due to the hydrogen cloud being too rich.&#xD;
It was observed that the ambient conditions, in particular the wind speed and direction, were a&#xD;
significant factor in the outcome of each ignition. This was particularly prominent in trials 21&#xD;
to 23.</description>
      <description descriptionType="TechnicalInfo">file consists of data from following sensors, obtained during experiments:&#xD;
    • blast pressure sensor&#xD;
    • noise sensor&#xD;
    • heat flux sensor&#xD;
    • pipework thermocouples &#xD;
    • pressure sensor&#xD;
    • mass flow sensor&#xD;
    • near-field weather station &#xD;
    • far-field wind sensor&#xD;
    • far-field humidity sensor&#xD;
and videos getted during experiments</description>
   </descriptions>
   <alternateIdentifiers>
      <alternateIdentifier alternateIdentifierType="KITopen-DOI">10.5445/IR/1000136285</alternateIdentifier>
   </alternateIdentifiers>
   <sizes>
      <size/>
   </sizes>
   <formats>
      <format>application/x-tar</format>
   </formats>
</resource></metadata></record></GetRecord></OAI-PMH>