Thermal Conductivity Measurement of Bulk Solids

Hlosta, Jakub; Žurovec, David; Gelnar, Daniel; Zegzulka, Jiří; Nečas, Jan

doi:10.1002/ceat.201700018

Cited by 6 publications

(4 citation statements)

References 29 publications

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“…The correct measurement and characterization of the thermal conductivity of bulk materials such as activated carbon can pose a number of problems. For example, the loss of heat input power, resulting in the generation of heat for heating the activated carbon samples, can be very difficult to quantify [38]. The bulk thermal conductivity for the tests did not dramatically increase with increased power to the test section heater.…”

Section: Resultsmentioning

confidence: 97%

Experimental Measurement of Bulk Thermal Conductivity of Activated Carbon with Adsorbed Natural Gas for ANG Energy Storage Tank Design Application

2020

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The development of adsorptive natural gas storage tanks for vehicles requires the synthesis of many technologies. The design for an effective Adsorbed Natural Gas (ANG) tank requires that the tank be filled isothermally within a five-minute charge time. The heat generated within the activated carbon is on the order of 150 MJ/m 3 of storage volume. The tank can be effectively buffered using Phase Change Material (PCM) to absorb the heat. The effective design of these tanks requires knowledge of the thermal properties of activated carbon with adsorbed methane. This paper discusses experimental measurements of the thermal conductivity of activated carbon with adsorbed methane. It was found that within the tank the thermal conductivity remains almost constant within the temperature and pressure ranges that ANG tanks will operate.

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Section: Resultsmentioning

confidence: 97%

Experimental Measurement of Bulk Thermal Conductivity of Activated Carbon with Adsorbed Natural Gas for ANG Energy Storage Tank Design Application

2020

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“…This shows that the torrefaction process at temperatures below 300 • C does not contain any risks related to material self-heating, thermal runaway and fire ignition at large-scale plant. In general, it is expected that the difference in thermal conductivity values of both torrefied biomass samples are small due to the similar cross-grain fiber orientation in non-treated olive residues and wood [109]. Thus, the first peak of torrefied biomass from treatment below 270 The residence time of torrefied olive stones had a negligible influence on the CO 2 reactivity leading to the peak temperature shift from 940 to 975 • C when the residence time was increased from 30 to 120 min.…”

Section: Bulk Thermal Conductivitymentioning

confidence: 99%

The effect of particle size, temperature and residence time on the yields and reactivity of olive stones from torrefaction

et al. 2020

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“…Data obtained from geological mapping and the geological inventory of the core wells,confirming act and limestone dolomites, are presented in Table 1. After all needed geological data were obtained, rock mass parameters were determined on the basis of the generalized Hoek-Brown failure criterion [11,12]. The computer program RocLab was applied [13].…”

Section: Determination Of the Rock Mass Parametersmentioning

confidence: 99%

Concept of Underground Gas Storage in the Limestone Rocks in Slovenia

Vukelić¹,

Vulić²

2018

Adv. Sci. Technol. Res. J.

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The paper provides research and results for underground storage of gas (UGSG) in limestone rocks, which were carried out in Slovenia-Central Europe. The areas was geological surveyed and in addition structural boreholes were drilled up to the depth of 350 m. The cores were logged with emphasis on stratigraphy, layering, rock joints, tectonic zones, RQD… and addition characteristics samples were taken for the laboratory rocks geomechanical characteristics investigations. In boreholes geophysical, pressiometric and hydro-geological investigations were also carried out. In the area where the researches have been carried out, limestone, dolomites and breccias are prevalent. Storage should be built for pressure between 15 and 20 MPa. Explorations confirmed that there is a possibility of building a high-pressure underground storage of gas (UGSG) and using applied mechanics for design LRC (Lined Rock Cavern) technology. The construction of underground storage facilities for natural gas storage is important in cases, where the gas supply does not meet the required capacity for operation of the thermal power plant.

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Thermal Conductivity Measurement of Bulk Solids

Cited by 6 publications

References 29 publications

Experimental Measurement of Bulk Thermal Conductivity of Activated Carbon with Adsorbed Natural Gas for ANG Energy Storage Tank Design Application

Experimental Measurement of Bulk Thermal Conductivity of Activated Carbon with Adsorbed Natural Gas for ANG Energy Storage Tank Design Application

The effect of particle size, temperature and residence time on the yields and reactivity of olive stones from torrefaction

Concept of Underground Gas Storage in the Limestone Rocks in Slovenia

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