25 research outputs found
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Relations between structural and dynamic thermal characteristics of building walls
The effect of internal thermal structure on dynamic characteristics of walls is analyzed. The concept of structure factors is introduced and the conditions they impose on response factors are given. Simple examples of multilayer walls, representing different types of thermal resistance and capacity distribution, are analyzed to illustrate general relations between structure factors and response factors. The idea of the ``thermally equivalent wall``, a plane multilayer structure, with dynamic characteristics similar to those of a complex structure, in which three-dimensional heat flow occurs, is presented
PV/Wind hybrid system for the low energy family house
Przeprowadzono analiz臋 funkcjonowania w ci膮gu 10-ciu lat hybrydowej instalacji solarno-wiatrowej, zaopatruj膮cej w energi臋 elektryczn膮 ma艂y energooszcz臋dny dom jednorodzinny, w warunkach klimatu Warszawy. R贸wnocze艣nie obliczono zapotrzebowanie budynku na ciep艂o, przy wykorzystaniu danych pogodowych Typowego Roku Meteorologicznego, oraz energi臋 na przygotowanie ciep艂ej wody u偶ytkowej. Instalacja mo偶e dostarczy膰 艣rednio 75% potrzebnej energii elektrycznej i dodatkowo 26% energii na cwu.Photovoltaic-wind hybrid system for the low energy small family house with four inhabitants has been analyzed, using 10-year hourly meteorological data for Warsaw. Energy demand for space heating has been calculated using the Typical Meteorological Year data, together with energy demand for domestic water heating. The system can deliver, on average, 75% of the necessary energy for electricity and 26% for water heating
Effectiveness of photovoltaic systems in the climatic conditions of Poland
Przeprowadzono analiz臋 wydajno艣ci, w warunkach klimatu Polski, modu艂贸w fotowoltaicznych i instalacji po艂膮czonych z sieci膮, odpowiednich dla inwestor贸w indywidualnych.Effectiveness of the photovoltaic modules and on-grid systems appropriate for family-houses, in the climatic conditions of Poland, has been analyzed
Dynamic test method of PCM content in fiberous insulation
Przedstawiono koncepcj臋 metodyki prowadzenia testowych pomiar贸w zawarto艣ci materia艂u fazowo-zmiennego, w du偶ych i w za艂o偶eniu jednorodnych pr贸bkach izolacji z w艂贸kna szklanego lub celulozy, z u偶yciem aparatu p艂ytowego. Podano spos贸b szacowania sta艂ej czasowej pr贸bki w procesie ustalania si臋 strumienia ciep艂a po skoku temperatury.Dynamic test method of PCM content in fiberous insulation is considered. Heat balance of a sample of material with PCM is analyzed. Time constants for 7.6 cm thick samples of PCM-Enhanced Cellulose Insulation are estimated
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The performance check between whole building thermal performance criteria and exterior wall measured clear wall R-value, thermal bridging, thermal mass, and airtightness
At the last IEA Annex 32 meeting it was proposed that the annex develop the links between level 1 (the whole building performance) and level 2 (the envelope system). This paper provides a case study of just that type of connection. An exterior wall mockup is hot box tested and modeled in the laboratory. Measurements of the steady state and dynamic behavior of this mockup are used as the basis to define the thermal bridging, thermal mass benefit and air tightness of the whole wall system. These level two performance characteristics are related to the whole building performance. They can be analyzed by a finite difference modeling of the wall assembly. An equivalent wall theory is used to convert three dimensional heat flow to one dimensional terms that capture thermal mass effects, which in turn are used in a common whole building simulation model. This paper illustrates a performance check between the thermal performance of a Massive ICF (Insulating Concrete Form) wall system mocked up (level 2) and Whole Building Performance criteria (level 1) such as total space heating and cooling loads (thermal comfort)
Thermal load mitigation and passive cooling in residential attics containing PCM-enhanced insulations
Residential attics has the potential to be one of the most energy efficient building components by combining thermal processes of attic floor insulation, attic air space, ventilation in attics, and solar collecting roof decks. Large amounts of solar energy collected by the roofs in cooling-dominated and mixed climates generate excess cooling loads, which need to be removed from the building by the space conditioning systems. This paper investigates potential ways to improve the thermal design of the residential home attics to minimize the cooling energy consumption in the cooling-dominated and mixed climates. Dynamic thermal characteristics of thick attic floor insulations and blends of phase change materials (PCMs) with insulations are analyzed. Both approaches can provide notable reductions of thermal loads at the attic level. In addition, a significant time shift of peak-hour loads can move a major operation time for air conditioning system from the daytime peak hours to nighttime low demand hours. A reverse heat flow direction can be observed during the day in the case of really thick layers of bulk insulation or PCM-enhanced insulations, compared to the rest of the building envelope components. This effect may provide free passive cooling to the building, and can be very useful in locations of double electrical tariffs with high daytime peak-hour electric energy rates and less-expensive off-peak energy cost. In both of the above cases, an addition of PCM to the bulk insulation brings substantial performance enhancement not available for traditional insulation applications. This paper presents a short overview of dynamic material characteristics and energy performance data necessary for future dynamic applications of different configurations of the attic floor insulation and PCM-insulation blends in residential homes. A series of whole-building scale and material scale numerical simulations were performed on a single story ranch house to analyze potential energy savings and optimize location of PCM within the attic insulation
A new approach for analysis of complex building envelopes in whole building energy simulations
The ability for reduction of whole-building energy consumption depends, in large scales, from correct predictions of building thermal loads with the building's envelope characteristics being one of the most important factors. Since most of today's building envelopes are complex three-dimensional networks of structural, insulation, and finish materials, the potential for correct predictions of their thermal performance depends on availability of acceptable, scientifically valid, consensus procedures for accurately implementing a building's envelope thermal characteristics into whole-building energy simulation programs. This paper is discusses a joint LBNL and Fraunhofer CSE project, focused on the upgrade of the already existing THERM program and its integration with EnergyPlus, a whole-building energy simulation tool. It is expected that these two programs, combined together, will eliminate typical analytical limitations of most of existing whole building energy tools, capable to simulate only simplified one-dimensional envelopes. The main research challenge is the design of an easy to implement upgrade of the THERM numerical tool to allow analysis of complex building envelope structures. The new version of THERM needs to be able to modify thermal characteristics of the complex three-dimensional (3-D) wall assemblies, in a way to enable their use in whole building energy simulation programs. It will be achieved through an application of the unique theoretical procedure, which will allow a generation of the simplified one-dimensional (1-D) wall geometry and material characteristics to fully and accuratly capture the dynamic effects of thermal bridges. At this stage of the project, the research team focuses on development of theoretical bases for necessary changes in the THERM framework. This paper explains the theoretical methodology which is used and presents some results from the series of steady-state and dynamic heat transfer simulations performed on building envelopes architectural components, to illustrate the accuracy limitations associated with thermal calculation methods recommended by building energy codes worldwide