IEA Solar Heating and Cooling Programm - NachhaltigWirtschaften.at
IEA Solar Heating and Cooling Programm - NachhaltigWirtschaften.at IEA Solar Heating and Cooling Programm - NachhaltigWirtschaften.at
IEA SHC Task 38 Solar Air Conditioning and Refrigeration Subtask C2-A, November 9, 2009 One of the pre-defined system configurations is selected and the input box for the solar thermal collector description is opened. 60% eingesparte Primärenergie 50% 40% 30% 20% 10% 160 180 200 220 240 260 280 55 65 75 85 95 105 115 125 135 Speichervolumen, l/m 2 0.28 Kosten eingesparte PE, €/kWh 0.26 0.24 0.22 0.2 0.18 0.16 0.14 160 180 200 220 240 260 280 0.12 55 65 75 85 95 105 115 125 135 Speichervolumen, l/m 2 Example of simulation results: For a defined system configuration and load data file, the savings in primary energy consumption (compared to a reference system calculation) and specific cost per saved kWh of primary energy are displayed as a function of the system size (storage volume is shown at the x.-axis, the collector area is represented by the different curves) EasyCool is used internally by Fraunhofer ISE and currently not disseminated for public use. page 16
IEA SHC Task 38 Solar Air Conditioning and Refrigeration Subtask C2-A, November 9, 2009 INSEL Antoine Dalibard ZAFH.NET (Stuttgart University of Applied Sciences) The acronym INSEL stands for INtegrated Simulation Environment Language. This graphical programming language has been developed at the Faculty of Physics of Oldenburg University (Germany) in the early 1990’s and was originally designed for the modelling of renewable electrical energy systems. Today INSEL covers the whole range of renewable energy systems, including building simulation and communication technologies. The software can be adapted by the user for completely own software developments and offers a transparent software solution from the planning phase to automation and simulation based control of any energy plants. Basic idea of INSEL The graphical programming language INSEL is based on the principle of “structured programming” on blocks diagrams. It consists of connecting blocks in order to obtain block diagrams that express a solution for a certain simulation task. Application areas of INSEL The main application areas of the program INSEL are: • Energy meteorology • Photovoltaic systems • Solar thermal systems • Solar thermal power plants • Building simulation (under development) • Building automation (under development) • Facility management (under development) Main uses of INSEL INSEL is a block diagram simulator that can be used by researchers, planers, designers, operators and investors for: • Design of complex energy systems • Visualisation and Internet monitoring • Monitoring and control of energy plants • Highly precise yield prognoses and economic calculations of energy systems. page 17
- Page 442 and 443: IEA SHC Task 38 Solar Air Condition
- Page 444 and 445: IEA SHC Task 38 Solar Air Condition
- Page 446 and 447: IEA SHC Task 38 Solar Air Condition
- Page 448 and 449: IEA SHC Task 38 Solar Air Condition
- Page 450 and 451: IEA SHC Task 38 Solar Air Condition
- Page 452 and 453: IEA SHC Task 38 Solar Air Condition
- Page 454 and 455: IEA SHC Task 38 Solar Air Condition
- Page 456 and 457: IEA SHC Task 38 Solar Air Condition
- Page 458 and 459: IEA SHC Task 38 Solar Air Condition
- Page 460 and 461: IEA SHC Task 38 Solar Air Condition
- Page 462 and 463: IEA SHC Task 38 Solar Air Condition
- Page 464 and 465: IEA SHC Task 38 Solar Air Condition
- Page 466 and 467: IEA SHC Task 38 Solar Air Condition
- Page 468 and 469: IEA SHC Task 38 Solar Air Condition
- Page 470 and 471: IEA SHC Task 38 Solar Air Condition
- Page 472 and 473: IEA SHC Task 38 Solar Air Condition
- Page 474 and 475: IEA SHC Task 38 Solar Air Condition
- Page 476 and 477: IEA SHC Task 38 Solar Air Condition
- Page 478 and 479: IEA SHC Task 38 Solar Air Condition
- Page 480 and 481: IEA SHC Task 38 Solar Air Condition
- Page 482 and 483: IEA SHC Task 38 Solar Air Condition
- Page 484 and 485: IEA SHC Task 38 Solar Air Condition
- Page 486 and 487: IEA SHC Task 38 Solar Air Condition
- Page 488 and 489: IEA SHC Task 38 Solar Air Condition
- Page 490 and 491: IEA SHC Task 38 Solar Air Condition
- Page 494 and 495: IEA SHC Task 38 Solar Air Condition
- Page 496 and 497: IEA SHC Task 38 Solar Air Condition
- Page 498 and 499: IEA SHC Task 38 Solar Air Condition
- Page 500 and 501: IEA SHC Task 38 Solar Air Condition
- Page 502 and 503: IEA SHC Task 38 Solar Air Condition
- Page 504 and 505: IEA SHC Task 38 Solar Air Condition
- Page 506 and 507: IEA SHC Task 38 Solar Air Condition
- Page 508 and 509: IEA SHC Task 38 Solar Air Condition
- Page 510 and 511: IEA SHC Task 38 Solar Air Condition
- Page 512 and 513: IEA SHC Task 38 Solar Air Condition
- Page 514 and 515: IEA SHC Task 38 Solar Air Condition
- Page 516 and 517: IEA SHC Task 38 Solar Air Condition
- Page 518 and 519: IEA SHC Task 38 Solar Air Condition
- Page 520 and 521: IEA SHC Task 38 Solar Air Condition
- Page 522 and 523: IEA SHC Task 38 Solar Air Condition
- Page 524 and 525: IEA SHC Task 38 Solar Air Condition
- Page 526 and 527: IEA SHC Task 38 Solar Air Condition
- Page 528 and 529: IEA SHC Task 38 Solar Air Condition
- Page 530 and 531: IEA SHC Task 38 Solar Air Condition
- Page 532 and 533: IEA SHC Task 38 Solar Air Condition
- Page 534 and 535: IEA SHC Task 38 Solar Air Condition
- Page 536 and 537: IEA SHC Task 38 Solar Air Condition
- Page 538 and 539: IEA SHC Task 38 Solar Air Condition
- Page 540 and 541: IEA SHC Task 38 Solar Air Condition
<strong>IEA</strong> SHC Task 38 <strong>Solar</strong> Air Conditioning <strong>and</strong> Refriger<strong>at</strong>ion Subtask C2-A, November 9, 2009<br />
INSEL<br />
Antoine Dalibard<br />
ZAFH.NET (Stuttgart University of Applied Sciences)<br />
The acronym INSEL st<strong>and</strong>s for INtegr<strong>at</strong>ed Simul<strong>at</strong>ion Environment Language. This graphical<br />
programming language has been developed <strong>at</strong> the Faculty of Physics of Oldenburg<br />
University (Germany) in the early 1990’s <strong>and</strong> was originally designed for the modelling of<br />
renewable electrical energy systems. Today INSEL covers the whole range of renewable<br />
energy systems, including building simul<strong>at</strong>ion <strong>and</strong> communic<strong>at</strong>ion technologies. The software<br />
can be adapted by the user for completely own software developments <strong>and</strong> offers a<br />
transparent software solution from the planning phase to autom<strong>at</strong>ion <strong>and</strong> simul<strong>at</strong>ion based<br />
control of any energy plants.<br />
Basic idea of INSEL<br />
The graphical programming language INSEL is based on the principle of “structured<br />
programming” on blocks diagrams. It consists of connecting blocks in order to obtain block<br />
diagrams th<strong>at</strong> express a solution for a certain simul<strong>at</strong>ion task.<br />
Applic<strong>at</strong>ion areas of INSEL<br />
The main applic<strong>at</strong>ion areas of the program INSEL are:<br />
• Energy meteorology<br />
• Photovoltaic systems<br />
• <strong>Solar</strong> thermal systems<br />
• <strong>Solar</strong> thermal power plants<br />
• Building simul<strong>at</strong>ion (under development)<br />
• Building autom<strong>at</strong>ion (under development)<br />
• Facility management (under development)<br />
Main uses of INSEL<br />
INSEL is a block diagram simul<strong>at</strong>or th<strong>at</strong> can be used by researchers, planers, designers,<br />
oper<strong>at</strong>ors <strong>and</strong> investors for:<br />
• Design of complex energy systems<br />
• Visualis<strong>at</strong>ion <strong>and</strong> Internet monitoring<br />
• Monitoring <strong>and</strong> control of energy plants<br />
• Highly precise yield prognoses <strong>and</strong> economic calcul<strong>at</strong>ions of energy systems.<br />
page 17