INTRODUCCIÓ ENERGIES RENOVABLES A LA XARXA DE CALOR I FRED DE PARC DE L ALBA

Smart and flexible 100% renewable district heating and cooling systems for European cities INTRODUCCIÓ ENERGIES RENOVABLES A LA XARXA DE CALOR I FRED DE PARC DE L ALBA Energy Efficiency: Systems, Buildings and Communities Research Group Laura Sisó, IREC Barcelona, 28 de Gener del 2017

Energies Renovables a les xarxes DHC Font: Euroheat and Power

Casos d estudi a Catalunya Residential and tertiary buildings Tertiary buildings C-16 C-17 C-25 4 Girona BADALONA 1 L Estrella 2 CERDANYOLA del Vallès Parc de l Alba Lleida A-2 3 AP-7 Industrial area School buildings AP-2 2 1 Barcelona AP-7 Tarragona 3 GRANOLLERS Ecocongost 4 SANT JOAN LES FONTS Escola i Llar d infants AP-7 Heat and resources mapping MAP VIEWER

Índex 1. Situació actual Sistema Poligeneració 2. Demanda energètica 3. Metodologia 4. Solucions tècniques 5. Resultats de l estudi 6. Conclusions

Sector Parc de l Alba DIR. SUD UNIVERSITAT UAB I PARC DE RECERCA ESTACIÓ INTERMODAL CENTRE COMERCIAL PARC CIENTÍFIC I TECNOLÓGIC ZONA RESIDENCIAL CERDANYOLA CORREDOR BIOLÒGIC SINCROTRÓ ALBA XARXA DE PARCS URBANS EQUIPAMENTS PARC TECNOLÒGIC VALLÈS ESADECREAPOLIS PARC NATURAL DE COLLSEROLA 340 ha 1.9 Mm 2 1,3 Mm 2 4,088 180 ha SUPERFÍCIE TOTAL 65% US PÚBLIC 50% ZONES VERDES SOSTRE TOTAL 70% PRODUCTIU 24% RESIDENCIAL SOSTRE PRODUCTIU (31,000 TREBALLADORS) 70% PUBLIC NOUS HABITATGES (11,100 RESIDENTS) 40% PUBLICS ZONES VERDES 25 ha EQUIPAMENTS 0 1 Mm 2 ESPAI COMERCIAL Font: Consorci Públic Parc de l Alba; Carlos Dapena

Xarxa de distribució de fred i calor (DHC) ST-5 ST-4 Cobertura: Parc de la ciència i la tecnologia, zona comercial i equipaments (terciari) Xarxa 4 tubs: canonada preaïllada, diàmetres DN150-DN800 Longitud: 16.8 km (actual) 32.3 km (final) Aigua calenta: impulsió 90 ºC retorn 75 ºC Aigua freda: impulsió 6.5 ºC retorn 13.5 ºC Font: Consorci Públic Parc de l Alba; Carlos Dapena

Planta de poligeneració ST4 (calor, fred, electricitat) Unit type Quantity Output (each unit) Comments Cogeneration Engine 3 3.28 MW of heating 3.35 MW of electricity Single Effect Absorption Chiller Double Effect Absorption Chiller 1 3 MW of cooling 1 5 MW of cooling Driven by hot water at 90 ºC Driven by exhaust gases at 398 ºC Natural gas boiler 1 5 MW of heating Back-up Compression Chiller 1 5 MW of cooling Back-up Chilled Water Storage Tank 1 21 MWh of cold storage 8 MW of cooling Total Capacity 9.84 MW of heating 10.05 MW of electricity

2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030 MWh/year Previsió de creixement de la demanda 2016-2030 160 000 Parc de l'alba Energy Demand Foreseen 140 000 120 000 100 000 80 000 60 000 40 000 20 000 0 heating demand cooling demand electricity sold to Synchrotron

Anàlisi energètica, econòmica i ambiental MODELS ENERGÈTICS EnergyPro (EMD International A/S) ESTRATEGIA OPERACIÓ Prioritat: 1. Renovables 2. Benefici CÀLCULS ECONÒMICS VAN 30 anys 10% DEMANDA Perfils de demanda horaris TIME-SERIES Preus electricitat exportada i importada, combustibles CÀLCULS ENERGÈTICS I AMBIENTALS Dimensionat equips Consum energies Emissions CO 2 Energia Primària

Models energètics i eina de càlcul: energypro

Solucions tècniques analitzades 2016 2018 2020 2022 2024 2026 2028 2030 ST-4 CHP+ABS 8 MWc 10 MWt 10 MWe Biogàs 1.5 MW CHP+ABS 5 MWc 7 MWh 7 MWe ST-5 Escenari SCBC Solar Tèrmica PTC 0.3 MWt ABS 3.8 MWc Biomassa 2.5 MWt ABS 30 MWc Biomassa 28 MWt ABS 25 MWc Biomassa 25 MWt Escenari GSHP PV 0.3 MWe Bomba calor geotèrmica 4 MWc 5 MWt Bomba calor geotèrmica 30 MWc 40 MWt ABS 25MWc Biomassa 25 MWt

2016-2018 Caldera biogàs

2020 2025 2030 SCBC: biomassa i solar tèrmica de concentració amb màquines d absorció

GSHP escenari: bombes de calor geotèrmiques i suport d energia fotovoltaica 2020 2025 2030

SCBC. Anàlisi Econòmica

2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030 k /year GSHP. Anàlisi Econòmica 150 000 GSHP Economic Assessment 100 000 50 000 0-50 000-100 000 cash-flow accumulated CAPEX accumulated CAPEX

Comparativa entre escenaris GSHP escenari SCBC escenari 2020 2025 2030 Total primary energy (MWh) 165,845 277,440 316,694 Difference in primary energy with SCBC scenario 9% 4% 15% CO 2 emissions (tons) 30,699 39,705 45,389 Difference in emissions with SCBC scenario 3% -27% -18% Total CAPEX ( ) 119,013,991 NPV ( ) 43,850,410 Difference in NPV with SCBC scenario -115% 2020 2025 2030 Total primary energy (MWh) 152,125 268,033 275,477 Difference in primary energy with GSHP scenario -8% -3% -13% CO 2 emissions (tons) 29,828 54,326 55,153 Difference in emissions with GSHP scenario -3% 37% 22% Total CAPEX ( ) 55,383,819 NPV ( ) 94,105,589 Difference in NPV with GSHP scenario 53%

CONCLUSIONS La introducció d energies renovables en el sistema de poligeneració de Parc de l Alba en el servei de subministrament de calor i fred es viable tècnica y econòmicament. Les solucions estudiades han estat: Biogàs Biomassa amb solar de concentració i màquines d absorció (SCBC) Geotèrmica i fotovoltaica (GSHP) El sistema biomassa+solar concentració (SCBC) presenta un 13 % d estalvi d energia primària% i un VAN un 53 % millor, respecte al cas geotèrmia+fv (GSHP). Les emissions de CO 2 son un 18 % superiors en el cas SCBC que en el GSHP.

Agraïments Present study has been developed in the framework of SMARTREFLEX Project (Smart and Flexible 100% Renewable District Heating and Cooling Systems for European Cities) co-funded by the Intelligent Energy Europe Programme of the European Union by means of Grant Agreement number IEE/13/434/SI2.674873. As a consequence, software energypro, which is sponsored by EMD International A/S for SMARTREFLEX, has been used to develop energy calculations. Institut Català del Sòl (INCASOL) de la Generalitat de Catalunya is also partner of Smartreflex and has contributed providing urban planing data of both case studies. Consorci Urbanístic del Centre Direccional de Cerdanyola del Vallès (Parc de l Alba) and ST4 Plant in Parc de l Alba from Grupo San José have contributed providing data about real performance and future development planning of district heating and cooling system in Parc de l Alba. Parc de l Alba_Barcelona Synchroton Park is a public consortium between the City Council of Cerdanyola del Vallès and the Catalan Land Institute (INCASÒL). Saad Saleem saadsaleem2005@gmail.com student of KIC RENE Programe has developed his Master Thesis based on Case Study of Parc de l Alba in the framework of Smartreflex. Results of his work has been used to write this article. For further information contact Laura Sisó, Senior Researcher at IREC lsiso@irec.cat

Back-up slides

Caldera biogàs 2016-2018 Unit type Quantity Specifications (each unit) Investment in 2024 ( ) Biogas Boiler 1 1.5 MW heating 147,500 Total Investment 147,500 Total new capacity 1.5 MW of heating

2024 Ampliació tecnologies actuals Unit type Quantity Cogeneration Engines 2 Double Effect Absorption chiller 1 Specifications (each unit) 3.28 MW of heating 3.35 MW of electricity Electrical efficiency: 44.9% 5 MW of cooling COP : 1.3 Investment in 2024 ( ) 3,629,701 1,100,074 Total Investment 4,729,776 5 MW of cooling Total new capacity 6.56 MW of heating 6.70 MW of electricity

Solar Cooling system SCBC: biomassa i solar tèrmica de concentració amb màquines d absorció Parabolic Trough Collectors Absorption Chiller Biomass Boilers Absorption Chillers 2020 2025 2030 Area of collectors : 1,088 m 2 Max Thermal output : 298 kwth Max Cooling output : 417.2 kwc Cooling output : 450 kwc COP : 1.4 Heating output : 2,500 kwth Heating output : 2,500 kwth Efficiency : 90% Efficiency : 90% Modulation: down to 10% Modulation: down to 10% Units : 1 Units : 1 Heating output : 5,000 kwth Heating output : 5,000 kwth Efficiency : 90% Efficiency : 90% Modulation: down to 10% Modulation: down to 10% Units : 5 Units : 5 Cooling output: 3,300 kwc Cooling output: 3,300 kwc COP:1.4 COP:1.4 Units:1 Units:1 Cooling output: 5,000 kwc Cooling output: 5,000 kwc COP:1.4 COP:1.4 Units:6 Units:3 CAPEX 5,730,128 23,226,067 21,548,658 Total cooling capacity (MWc) Total heating capacity (MWth) 3.7 30.0 18.3 2.5 27.5 25.0

GSHP escenari: bombes de calor geotèrmiques i suport d energia fotovoltaica 2020 2025 2030 Solar Photovoltaic system Ground Source Heat Pumps Biomass Boilers Absorption Chillers PV field area: 1,800 m 2 Electrical output: 275 kwe Efficiency : 15.4% Type: Monocrystalline Cooling output : 3,900 kwc Heating output : 5,113 kwth Electrical input: 1,214 kwe Cooling output: 30,100 kwc Heating output : 39,461 kwth Electrical input: 9,368 kwe Thermal output: 5,000 kwth Efficiency: 90 % Units: 5 Cooling output : 5,000 kwc COP : 1.4 Units: 5 CAPEX 13,303,429 77,663,244 23,169,352 Total cooling capacity(mwc) Total heating capacity (MWth) 3.9 30.1 25.0 5.1 39.5 25.0

Biogàs 2016-2018. Anàlisi Energètica Energy parameters 2016 2017 2018 TOTAL (MWh) Energy Demands Heat demand 1,426 2,386 2,738 Cooling demand 23,600 25,368 26,048 Energy Production Electricity produced Engines 25,258 39,835 38,769 Fuel Inputs NG Boiler Fuel consumption 1,206 7 71 Engines Fuel consumption 91,684 94,845 92,307 Biogas Boiler 9,176 9,107 2016 2017 2018 Primary Energy Consumption TOTAL (MWh) Imported electricity 39,881 40,154 41,499 Natural gas 111,004 113,348 110,391 Biogas 4,588 4,554 Total primary energy 150,885 158,090 156,444

SCBC. Anàlisis Energètica 2020 2025 2030 Energy parameters TOTAL (MWh) Energy Demands Heat demand 3,398 30,298 46,048 Cooling demand 31,848 88,214 136,639 Energy Production Electricity produced by Engines 39,282 72,804 69,604 Fuel Inputs NG Boiler consumption 0 2,221 88 Engines consumption 93,527 173,342 165,723 Biomass boiler consumption 13,756 101,703 133,096

SCBC. Anàlisis Ambiental i Econòmica 2020 2025 2030 Primary Energy TOTAL (MWh) Imported electricity 39,892 54,777 72,808 Natural gas 111,765 209,798 198,143 Biomass 468 3,458 4,525 Total primary energy 152,125 268,033 275,477 2020 2025 2030 Enviornmental parameters TOTAL (tons) Carbon dioxide 29,828 54,326 55,153 Economics Parameters TOTAL (Euros) Revenues 12,417,529 40,462,474 61,040,565 Operating Costs 7,433,577 21,464,284 31,717,075 EBITDA 4,983,953 18,998,190 29,323,490 Free Cash Flow 3,326,752 10,498,447 19,030,532 NPV 94,105,589

GSHP. Anàlisi Energètica 2020 2025 2030 Energy parameters TOTAL (MWh) Energy Demands Heat demand 3,398 30,298 46,048 Cooling demand 31,848 88,214 136,639 Energy Production Electricity produced by Engines 41,626 62,891 61,935 Fuel Inputs NG Boiler consumption 80 682 47 Engines consumption 98,224 148,854 146,578 GSHP Electricity consumption 4,751 24,155 33,943 Biomass Boiler consumption 24,798

GSHP. Anàlisi Ambiental i Econòmica 2020 2025 2030 Primary Energy TOTAL (MWh) Imported electricity 48,372 98,745 140,634 Natural gas 117,473 178,695 175,217 Biomass 843 Total primary energy 165,845 277,440 316,694 Enviornmental parameters 2020 2025 2030 TOTAL (tons) Carbon dioxide 30,699 39,705 45,389 Economics Parameters TOTAL (Euros) Revenues 12,905,195 37,374,315 56,946,322 Operating Costs 7,299,363 17,579,057 30,037,247 EBITDA 5,605,832 19,795,259 26,909,075 Free Cash Flow 3,680,400 12,429,626 18,047,696 NPV 43,850,410

2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 2027 2028 2029 2030 k /year GSHP Revenues and expenditures 40 000 35 000 30 000 25 000 20 000 15 000 10 000 5 000 0 electricity revenues expenditures heating & cooling revenues