ANSÖKAN OM FORSKNINGSSTÖD Datum Dnr 1 (6) Projektnr Sökande Företag/organisation Organisationsnummer KTH, Kungliga Tekniska Högskolan 202100-3054 Institution/avdelning Postgiro/Bankgiro/Bankkonto Energiteknik, Avd. Tillämpad Termodynamik och Kylteknik PG: 1 56 53-9, BG: 895-9223 Postadress Brinellvägen 68 Postnummer Ort Länskod Kommunkod Land 10044 Stockholm 01 80 Sverige Projektledare (förnamn, efternamn) Per Lundqvist, Joachim Claesson Telefon 08 7907452 08 20 41 61 E-postadress Fax Webbplats Perlundq@energy.kth.se, http://www.kth.se/itm/inst/energiteknik joachim.claesson@energy.kth.se Eventuell medsökande (ange organisation) Hatef Madani, Energiteknik, Avd. Tillämpad Termodynamik och Kylteknik, KTH Projektet Ansökan avser nytt projekt Projekttitel (på svenska) Kapacitetsreglering i värmepumpsystem Projekttitel (på engelska) Capacity control in heat pump systems Fortsättning på tidigare projekt, ange projektnummer: P05 Sammanfattning (på svenska). Sammanfattningen skall omfatta max 250 ord och skall skrivas både på svenska och på engelska. Sammanfattningen skall skrivas så att den i ämnet oinvigde med lätthet förstår projektets innehåll och syfte. I det tidigare projektet Dynamiska värmepumpsystem med kapacitetsreglering utvecklades en generisk modell som är kapabel att fånga dynamiken hos ett verkligt system. Modellen består av ett antal olika undermodeller, såsom värmepumpsenheten, byggnaden, värmesystemet, värmekällan, klimat, osv. Modellen har använts till att utvärdera kvantitativt olika tekniker för kapacitetsreglering av värmepumpar, t.ex. varvtalsstyrd kompressor eller pumpar. För att validera modellerna och erhålla förståelse av kapacitetsreglerade värmepumpenheter har fältmätningar och laboratorier-mätningar genomförts. Till exempel har förlusterna i varje steg identifierats, dvs frekvensomriktaren och kompressorns olika förluster. Målet med det föreslagna projektet, som är en fortsättning av det förra, är att använda de utvecklade modellerna till att utvärdera årsprestanda för några av de nyare teknikerna och nya utvecklade strategier för kapacitetsreglering i värmepumpssystem. Exempelvis kommer årsprestandan för en ny systemkonfiguration samt ett system med kompressor med permanentmagnetiserad elektrisk motor att utvärderas. Dessutom kommer de experimentella studierna kring varvtalsreglerade värmepumpssystem att fortsätta och fokusera på hur förlusterna i systemet beter sig vid olika lastfall samt att eftersöka optimala STEM038 ver.n-1.1, 2005-09-14 Sekretariatet EFFSYS+ Institutionen för Energiteknik Avdelningen Tillämpad termodynamik och kylteknik Kungliga Tekniska Högskolan 100 44 Stockholm Besöksadress Brinellvägen 68 Telefax 08-204161 E-post Effsysplus@energy.kth.se
Datum 2 (6) designparametrar, såsom frekvensomriktarens inre frekvens både ur ett elektrisk och termodynamiskt perspektiv. Den experimentuppställning som redan är byggd vid KTH Energiteknik kommer att användas för detta ändamål. Sammanfattning på engelska enligt ovan (max 250 ord). During the previous project called Dynamiska värmepumpsystem med kapacitetsreglering, a generic model has been developed which is able to represent the dynamics of the real system as a whole. The developed model consists of different sub-models such as heat pump unit components, building, heating distribution system, heat source, climate, etc. The model has been used to quantitatively evaluate different techniques for capacity control of heat pumps such as using variable speed compressor, variable speed pump. In order to validate the models and also to have a better understanding about a capacity controlled heat pump unit, in-situ field measurements and experimental studies were carried out. The loss behavior at every component in the heat pump system such as inverter, compressor, etc. is an example of the results from the experimental studies. The aim of this new proposed project, as the continuation of the previous one, is to use the models already developed in order to evaluate the annual performance of some of the most recent techniques and strategies for capacity control in heat pump systems. For example, the annual performance of new system configurations and new variable speed compressor with permanent magnet motor will be evaluated. Furthermore, the experimental studies on the variable speed heat pump systems will be continued in order to find the loss behavior in the system and also optimum design parameters, such as optimum switching frequency from both an electrical and thermo dynamical point of views. The experimental setup which was already built in KTH will be used for the studies. Enskilt projekt Datum för projektstart Forskningsprogram, ange vilket: EFFSYS+ 101001 121001 Totalt sökt belopp 1 136 kkr Tidpunkt då projektet beräknas vara genomfört
Datum 3 (6) Motivering; Energi-/miljö-/näringslivsrelevans, max 250 ord. Ange koppling till resultat från tidigare genomfört program eller projekt. The heat pump system in a wider sense, i.e. the heat pump unit, the heat source (ground or air, etc.), buildings as the heat sinks, climate, user behavior, pumps, fans, and the control devices have a complex dynamic interaction during the heating season and a small change in one of them may have a considerable impact on the overall performance of the system. Therefore, it is very hard to evaluate the annual performance of the heat pump system just only by focusing on the heat pump unit COP at a specific operating condition. The generic model of the heat pump system developed in the previous project considers the dynamic interaction among all the components and it can been used in order to evaluate the annual performance of the heat pump systems with a large variety of component characteristics control techniques and strategies system configurations It would, then, be a great opportunity to use the available models and experimental setups in order to assess the performance of most recent components and control techniques such as new variable speed compressors with permanent magnet motor or a new inverter technology. Furthermore, via the available model, the annual performance of innovative system configurations, e.g. a combination of a variable capacity heat pump, heat recovery system and solar heating system can be evaluated and compared to the conventional systems at different climatic conditions. Evaluation of system performance in such a systematic way, in cooperation with several well-known manufacturers, may lead to save a considerable amount of energy, and consequently reduction of CO2 emissions. Bakgrund; vad har gjorts tidigare?, vad är nytt i detta projekt?, forskargruppens verksamhet?, samarbeten? etc, max 1 A4-sida During the previous project called Dynamiska värmepumpsystem med kapacitetsreglering, both modeling and experiments were done in order to evaluate the annual performance of capacity controlled heat pump systems. During this project, several modeling, simulation and experiments were done upon the requests from the heat pump manufacturers such as Thermia, NIBE, CTC Enertech, ETM Kylteknik, etc. As the conclusion of the project, a new solution was suggested in order to cover the peak hours demand and eliminate the electrical auxiliary heater in the system. The loss behavior and distribution in the components of a variable capacity heat pump system such as variable speed compressor and inverter are some other examples of the results from the former project. During the project, four scientific papers were submitted to three international journals and 7 papers were published and presented in several international conferences such as IEA heat pump conference, ASHRAE RAL conference, ASME heat transfer conference, International conference in Applied Energy, etc. As the continuation of the previous project, the new project focuses on Annual modeling of some new system configurations, upon the requests from the project partners. for example, evaluation of the annual performance of a new combination of a capacity controlled heat pump and heat recovery systems and the possible combination of solar heating and heat pumps. Experimental studies on the variable speed compressor with a permanent magnet motor as one of the most recent techniques for capacity control in heat pumps Evaluation of new inverter and variable speed compressor technologies
Datum 4 (6) Some of the world leading companies in this field such as Copeland (Emersun) from Belgium, HKT GmbH from Germany, Thermia (Danfoss), IVT (Bosch), and NIBE from Sweden will participate in the project, making the project a platform to share the most recent results about the capacity control in heat pump systems. The results of the new project will be published and presented in at least two international conferences and scientific journals (four abstracts were already sent to IIR congress and IEA heat pump conferences). Mål; Ange enkla, tydliga och mätbara mål i exempelvis kwh, max 250 ord. The project aims of using the available models developed in the previous project to evaluate the annual performance of some of the most recent techniques for capacity control in heat pump systems, e.g. use of variable speed compressor with permanent magnet motors or variable speed pumps which are predicted to improve the Seasonal Performance Factor (SPF) of the heat pump system by more than 15%. Moreover, the experimental studies on the variable speed heat pump systems will be continued in order to find the loss behavior in every component of a variable capacity heat pump system. The project also aims at finding the optimum value for some key design parameters, such as optimum switching frequency which yields the optimum performance from both electrical and thermo dynamical point of views. Genomförande, max 250 ord. Upon the requests from the project partners, annual modeling and simulation of different heat pump systems with different configurations are done in KTH. The project partners form an expert panel consisting of specialists, experts and entrepreneurs from different fields. For example, there are experts from the academic researchers from KTH with a vast experience in this field the most well-known Swedish heat pump manufacturers such as Thermia, NIBE, IVT, CTC Enertech, etc. one of the world s leading compressor manufacturers such as Copeland and HKT GmbH one of the leading companies in inverter technology, NFO The national Heat Pump Association (SVEP) The KTH s team will coordinate the panel and it will have several individual and group meetings on a regular basis to direct the project. The project partners provide most of the required components to be tested and share their own test results; however, no brand or company name will be mentioned in the publications.
Datum 5 (6) Kostnader Projektets totala kostnad Projektets totala kostnader per år % av heltid KALENDERÅR 2010 2011 2012 Lönekostnader 2396481 290185 1185741 920556 Laboratoriekostnad 35000 5000 20000 10000 Datorkostnad 15000 5000 5000 5000 Utrustning 25000 5000 10000 10000 Material 15000 5000 5000 5000 Resor 45000 5000 20000 20000 Övriga kostnader 15000 5000 5000 5000 Ev förvaltningskostnader 294519 36815 147256 110444 SUMMA 2841000 357000 1398000 1086000 Finansiering inkl. samfinansiärer Andel i kronor och procent av projektets totala kostnader/år FINANSIÄR År 2010 År 2011 År 2012 År År Total (%) Energimyndigheten 142000 568000 426000 1136000 40 Copeland 50000 200000 150000 400000 14.1 Thermia 52500 210000 157500 420000 14.8 NIBE 25000 100000 75000 200000 7.04 IVT 12000 50000 38000 100000 3.51 Climacheck 30000 100000 110000 240000 8.5 NFO 12500 50000 37500 100000 3.51 ETM Kylteknik 25000 100000 75000 200000 7.04 Palne Mogensen AB 3000 15000 12000 30000 1 Nowab 5000 5000 5000 15000 0.5 SVEP SUMMA 357000 1398000 1086000 2841000 100 Detta projekt är i sin helhet i vissa delar lika med ansökan till annan myndighet, ange vilken: Sökt stöd för dyr utrustning (Vetenskapsrådet, Wallenbergsstiftelsen e.d.) Gäller endast högskola. Namn på doktorand Hatef Madani Namn på doktorand Namn på doktorand Namn på doktorand Övriga samarbetspartners (ange organisation och namn) Resultatredovisning (ange här om resultatet kommer att redovisas på något ytterligare sätt än det obligatoriska, se information). The project will lead to a PhD degree on the same subject. Furthermore, similar to the research program effsys2, the regular progress report will be submitted and the project will be presented in the form of scientific papers, articles in international magazines and journals, and oral presentation in international conferences such as coming IIR congress, etc.
Datum 6 (6) Bilagor Intyg med underskrifter från samfinansiärer Gantt-schema 2010 2011 2012 Aktivitet/kvartal 4 1 2 3 4 1 2 3 Continuation of Experiments on variable speed HP unit x x Continuation of system modeling (e.g. SPF comparison of different control strategies) x x Experiments on the new variable capacity systems x x x x Modeling HP systems with innovative configurations (e.g. combination of HP, heat recovery, and solar systems) x x x x Annual modeling of HP systems based on the experimental studies x x x x Dissemination of results (scientific journal publications) x x x Övriga bilagor Datum Datum 2010-11-29 2010-11-29 Behörig firmatecknares (prefekt motsv.) underskrift Projektledarens underskrift Namnförtydligande, titel och telefon Namnförtydligande och titel Björn Palm, professor 08 790 74 53 Per Lundqvist, professor 08 790 74 52
Confirmation of inte rest This letter certifies that Climacheck reported interest in participating in the "Effsysplus" project called "Capacity controi in heat pump systems". The project has been started September 2010 and it will be finished September 2012. The expected contribution these two years. ;V~ck""L /~ from Climacheck will be 240000 SEK(in-kind) over fc (C-.5 /.3c --:; (oi; i/o C({~~ Ch c;> C k 5-ve/cp"/ /?6
The report of company's contribution, Effsys Project called "Dynamic heat pump Company's name: Copeland Europe Time period: 10/2010 to10/2012 company's contribution Number Time constant sum (företagsinsatser) Man-Hour (Euro) ( ) Cash contribution 4000 Salary senior researcher 64 80 5 120 Salary technical researcher 160 50 8 000 Salary Routine work 160 50 8 000 Laboratory cost Equipment Material 8 000 Travel 8 000 Other costs SUM 41 120