%0 Journal Article %1 schrder2015design %A Schröder, Elisabeth %A Thomauske, Klaus %A Schmalzbauer, Jens %A Herberger, Sabrina %A Gebert, Christoph %A Velevska, Marina %D 2015 %J Geothermics %K 2015 flow geothermal heat-capacity instrument %N 0 %P 202 - 212 %R 10.1016/j.geothermics.2014.06.001 %T Design and test of a new flow calorimeter for online detection of geothermal water heat capacity %U http://dx.doi.org/10.1016/j.geothermics.2014.06.001 %V 53 %X Net power output of geothermal power plants depends on thermal heat, which is delivered by the geothermal water flow. In order to determine the potential, knowledge of temperature, mass flux and heat capacity of thermal water is important. On-site heat capacity of thermal water is only roughly estimated because dissolved gases and minerals influence heat capacity significantly. In order to address this knowledge gap, a new flow calorimeter was constructed which allows for on-site detection of specific heat capacity of geothermal water. It operates at high maximum temperatures (170 °C) and pressures (3 MPa), and can be installed as a bypass loop in geothermal power plants. The flow calorimeter was tested using water and aqueous sodium chloride solutions at a range of temperatures (20–160 °C) and absolute pressures (0.2–2.6 MPa). The experimental results deviate by about 1% from existing data reported in the academic literature.

@article{schrder2015design, abstract = {Net power output of geothermal power plants depends on thermal heat, which is delivered by the geothermal water flow. In order to determine the potential, knowledge of temperature, mass flux and heat capacity of thermal water is important. On-site heat capacity of thermal water is only roughly estimated because dissolved gases and minerals influence heat capacity significantly. In order to address this knowledge gap, a new flow calorimeter was constructed which allows for on-site detection of specific heat capacity of geothermal water. It operates at high maximum temperatures (170 °C) and pressures (3 MPa), and can be installed as a bypass loop in geothermal power plants. The flow calorimeter was tested using water and aqueous sodium chloride solutions at a range of temperatures (20–160 °C) and absolute pressures (0.2–2.6 MPa). The experimental results deviate by about 1% from existing data reported in the academic literature.}, added-at = {2014-07-04T11:54:10.000+0200}, author = {Schröder, Elisabeth and Thomauske, Klaus and Schmalzbauer, Jens and Herberger, Sabrina and Gebert, Christoph and Velevska, Marina}, biburl = {https://www.bibsonomy.org/bibtex/258d5658e283444705c2882214cadffb2/thorade}, description = {Design and test of a new flow calorimeter for online detection of geothermal water heat capacity}, doi = {10.1016/j.geothermics.2014.06.001}, interhash = {b66a6f3ae9c110e73e1a6fc487fa364b}, intrahash = {58d5658e283444705c2882214cadffb2}, issn = {0375-6505}, journal = {Geothermics }, keywords = {2015 flow geothermal heat-capacity instrument}, number = 0, pages = {202 - 212}, timestamp = {2014-07-04T11:54:10.000+0200}, title = {Design and test of a new flow calorimeter for online detection of geothermal water heat capacity }, url = {http://dx.doi.org/10.1016/j.geothermics.2014.06.001}, volume = 53, year = 2015 }