@article{KuperjansGuerzenichRoosen2005, author = {Kuperjans, Isabel and G{\"u}rzenich, D. and Roosen, P.}, title = {Kostenfunktionen im WWW : Unterst{\"u}tzung der Auslegung energietechnischer Anlagen und deren Verschaltungen}, series = {Gasw{\"a}rme international (GWI)}, volume = {54}, journal = {Gasw{\"a}rme international (GWI)}, number = {1}, issn = {0020-9384}, pages = {19 -- 21}, year = {2005}, language = {de} } @article{KuperjansEsserMeyeretal.2000, author = {Kuperjans, Isabel and Esser, J. and Meyer, J{\"o}rg and Donner, O.}, title = {Gestaltung und Bewertung von Energieanlagen unter {\"o}kologischen, wirtschaftlichen und technischen Gesichtspunkten}, series = {Umweltwirtschaftsforum : UWF}, volume = {8}, journal = {Umweltwirtschaftsforum : UWF}, number = {3}, issn = {0943-3481}, pages = {53 -- 58}, year = {2000}, language = {de} } @article{AugensteinHerbergsKuperjans2006, author = {Augenstein, Eckardt and Herbergs, S. and Kuperjans, Isabel}, title = {TOP-Energy : ein Werkzeug zur Optimierung der Geb{\"a}udeenergieversorgung}, series = {KI : K{\"a}lte, Luft, Klimatechnik}, journal = {KI : K{\"a}lte, Luft, Klimatechnik}, number = {5}, issn = {1865-5432}, pages = {198 -- 201}, year = {2006}, language = {de} } @article{PauksztatKuperjansMeyer2005, author = {Pauksztat, Anja and Kuperjans, Isabel and Meyer, J{\"o}rg}, title = {Formeln statt Zahlen : Referenzwerte Formeln zur energetischen Bewertung von Produktionsanlagen}, series = {BWK : das Energie-Fachmagazin}, volume = {57}, journal = {BWK : das Energie-Fachmagazin}, number = {12}, issn = {0006-9612}, pages = {52 -- 55}, year = {2005}, language = {de} } @article{PauksztatKuperjansMeyer2005, author = {Pauksztat, Anja and Kuperjans, Isabel and Meyer, J{\"o}rg}, title = {Produktbezogene Referenzwerte f{\"u}r Energieeffizienz und CO2-Emissionen}, series = {Energiewirtschaftliche Tagesfragen : et ; Zeitschrift f{\"u}r Energiewirtschaft, Recht, Technik und Umwelt}, volume = {55}, journal = {Energiewirtschaftliche Tagesfragen : et ; Zeitschrift f{\"u}r Energiewirtschaft, Recht, Technik und Umwelt}, number = {6}, issn = {0013-743X}, pages = {374 -- 376}, year = {2005}, language = {de} } @article{RuppHandschuhRiekeetal.2019, author = {Rupp, Matthias and Handschuh, Nils and Rieke, Christian and Kuperjans, Isabel}, title = {Contribution of country-specific electricity mix and charging time to environmental impact of battery electric vehicles: A case study of electric buses in Germany}, series = {Applied Energy}, volume = {237}, journal = {Applied Energy}, publisher = {Elsevier}, address = {Amsterdam}, issn = {0306-2619}, doi = {10.1016/j.apenergy.2019.01.059}, pages = {618 -- 634}, year = {2019}, language = {en} } @article{KuperjansStarkeEsseretal.2000, author = {Kuperjans, Isabel and Starke, M. and Esser, J. and Meyer, J. and Donner, O.}, title = {Analyse und Konzeption von Energieanlagen unter {\"o}kologischen, wirtschaftlichen und technischen Gesichtspunkten}, series = {WLB : Umwelttechnik f{\"u}r Industrie und Kommune}, volume = {44}, journal = {WLB : Umwelttechnik f{\"u}r Industrie und Kommune}, number = {11/12}, issn = {0341-2679}, pages = {26 -- 29}, year = {2000}, language = {de} } @article{HoffstadtPohenDickeetal.2020, author = {Hoffstadt, Kevin and Pohen, Gino D. and Dicke, Max D. and Paulsen, Svea and Krafft, Simone and Zang, Joachim W. and Fonseca-Zang, Warde A. da and Leite, Athaydes and Kuperjans, Isabel}, title = {Challenges and prospects of biogas from energy cane as supplement to bioethanol production}, series = {Agronomy}, volume = {10}, journal = {Agronomy}, number = {6}, publisher = {MDPI}, address = {Basel}, issn = {2073-4395}, doi = {10.3390/agronomy10060821}, year = {2020}, abstract = {Innovative breeds of sugar cane yield up to 2.5 times as much organic matter as conventional breeds, resulting in a great potential for biogas production. The use of biogas production as a complementary solution to conventional and second-generation ethanol production in Brazil may increase the energy produced per hectare in the sugarcane sector. Herein, it was demonstrated that through ensiling, energy cane can be conserved for six months; the stored cane can then be fed into a continuous biogas process. This approach is necessary to achieve year-round biogas production at an industrial scale. Batch tests revealed specific biogas potentials between 400 and 600 LN/kgVS for both the ensiled and non-ensiled energy cane, and the specific biogas potential of a continuous biogas process fed with ensiled energy cane was in the same range. Peak biogas losses through ensiling of up to 27\% after six months were observed. Finally, compared with second-generation ethanol production using energy cane, the results indicated that biogas production from energy cane may lead to higher energy yields per hectare, with an average energy yield of up to 162 MWh/ha. Finally, the Farm²CBG concept is introduced, showing an approach for decentralized biogas production.}, language = {en} } @article{Kuperjans2011, author = {Kuperjans, Isabel}, title = {Gute Planung ist alles : Energieeffizienz in der Pharmaproduktion}, series = {Pharma + Food}, volume = {2011}, journal = {Pharma + Food}, number = {2}, publisher = {H{\"u}thig}, address = {Heidelberg}, issn = {1434-8942}, pages = {8 -- 10}, year = {2011}, language = {de} } @article{BlockViebahnJungbluth2024, author = {Block, Simon and Viebahn, Peter and Jungbluth, Christian}, title = {Analysing direct air capture for enabling negative emissions in Germany: an assessment of the resource requirements and costs of a potential rollout in 2045}, series = {Frontiers in Climate}, volume = {6}, journal = {Frontiers in Climate}, publisher = {Frontiers}, address = {Lausanne}, issn = {2624-9553}, doi = {10.3389/fclim.2024.1353939}, pages = {18 Seiten}, year = {2024}, abstract = {Direct air capture (DAC) combined with subsequent storage (DACCS) is discussed as one promising carbon dioxide removal option. The aim of this paper is to analyse and comparatively classify the resource consumption (land use, renewable energy and water) and costs of possible DAC implementation pathways for Germany. The paths are based on a selected, existing climate neutrality scenario that requires the removal of 20 Mt of carbon dioxide (CO2) per year by DACCS from 2045. The analysis focuses on the so-called "low-temperature" DAC process, which might be more advantageous for Germany than the "high-temperature" one. In four case studies, we examine potential sites in northern, central and southern Germany, thereby using the most suitable renewable energies for electricity and heat generation. We show that the deployment of DAC results in large-scale land use and high energy needs. The land use in the range of 167-353 km2 results mainly from the area required for renewable energy generation. The total electrical energy demand of 14.4 TWh per year, of which 46\% is needed to operate heat pumps to supply the heat demand of the DAC process, corresponds to around 1.4\% of Germany's envisaged electricity demand in 2045. 20 Mt of water are provided yearly, corresponding to 40\% of the city of Cologne's water demand (1.1 million inhabitants). The capture of CO2 (DAC) incurs levelised costs of 125-138 EUR per tonne of CO2, whereby the provision of the required energy via photovoltaics in southern Germany represents the lowest value of the four case studies. This does not include the costs associated with balancing its volatility. Taking into account transporting the CO2 via pipeline to the port of Wilhelmshaven, followed by transporting and sequestering the CO2 in geological storage sites in the Norwegian North Sea (DACCS), the levelised costs increase to 161-176 EUR/tCO2. Due to the longer transport distances from southern and central Germany, a northern German site using wind turbines would be the most favourable.}, language = {en} }