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Ukraine and Greece – Two Diasporas: Engagement and Disengagement with the Homeland at Times of Crisis

Foteini Kalantzi Iryna Lapshyna
Central and Eastern European Migration Review | 2020 | vol. 9 | No 2 | 15-33
Keywords diaspora diasporic engagement homeland Greece Ukraine crisis
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Abstract

This article focuses on the interrelationship between homeland and diaspora at times of crisis. It adopts a comparative lens to look into diasporic (dis)engagement with the homeland, specifically analysing the cases of Greece and Ukraine. The main research issues are how crises affect the engagement between homeland and diaspora – taking Greece and Ukraine as case studies – and which the defining contextual factors are that transform the diaspora engagement. The article unpacks the homeland–diaspora nexus concerning two states with different socio-political backgrounds, both going through severe political and economic crises. In so doing, the article gives prominence to the differentiation between the en-gagement of the two different diasporas with their home countries at times of crisis. Evidence suggests substantial engagement in the Ukrainian case while, in the Greek case, a more mixed attitude – leaning towards disengagement – is apparent.

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Authors and Affiliations

Foteini Kalantzi
Iryna Lapshyna

Analysis of the use of waste heat from a glass melting furnace for electricity production in the organic Rankine cycle system

Arkadiusz Mateusz Musiał Łukasz Antczak Łukasz Jedrzejewski Piotr Klonowicz
Archives of Thermodynamics | 2021 | vol. 42 | No 1 | 15-33 | DOI: 10.24425/ather.2021.136945
Keywords energy efficiency distributed generation Organic Rankine cycle ORC Industrial waste heat
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Abstract

In most production plants, waste heat is usually discharged into the environment, contributing to a reduction in the energy efficiency of industrial processes. This is often due to the low thermal parameters of the carriers in which this energy is contained, such as oils, water, exhaust gases or other post-process gases, which means that their use for electricity production in a conventional Rankine cycle may prove to be economically unprofitable. One of the technologies enabling the use of lowand medium-temperature waste heat carriers is the organic Rankine cycle (ORC) technology. The paper present results of calculations performed to evaluate potential electricity production in ORC using waste heat from a natural gas-fired glass melting furnace. The analysis was carried out assuming the use of a single-stage axial turbine, whose efficiency was estimated using correlations available in the literature. The calculations were carried out for three working fluids, namely hexamethyldisiloxane, dimethyl carbonate, and toluene for two scenarios, i.e. ORC system dedicated only to electricity production and ORC system working in cogeneration mode, where heat is obtain from cooling the condenser. In each of the considered cases, the ORC system achieves the net power output exceeding 300 kW (309 kW for megawatts in the cogenerative mode to 367 kW for toluene in the non-cogenerative mode), with an estimated turbine efficiency above 80%, in range of 80,75 to 83,78%. The efficiency of the ORC system, depending on the used working fluid and the adopted scenario, is in the range from 14.85 to 16.68%, achieving higher efficiency for the non-cogenerative work scenario.
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Authors and Affiliations

Arkadiusz Mateusz Musiał
1 2
Łukasz Antczak
1
Łukasz Jedrzejewski
3
Piotr Klonowicz
3
  1. Marani Sp. z o.o., Szybowa 14c, 41-808 Zabrze, Poland
  2. Silesian University of Technology, Akademicka 2A, 44-100 Gliwice, Poland
  3. Institute of Fluid Flow Machinery Polish Academy of Sciences, Fiszera 14, 80-231 Gdansk, Poland

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