Fulltext results:
- Greenhouse effect and climate protection @basics:energy_and_ecology
- vailable on this topic for those who want to know more about it, predominantly from [[http://www.ipcc.ch... irreversible. Some of these effects are becoming more and more apparent today, for example, melting glaciers.\\ \\ |{{ :picopen:see_eis_wf.gif }}|//**The nor... cator for the increase in\\ temperature: To learn more about this phenomenon, please\\ read the followin
- Are Passive Houses cost-effective? @basics:affordability:investing_in_energy_efficiency
- fits should not be expected. The Passive House is more stable, more secure and more worthwhile than the alternative. Whoever wants “easy money” should try something else (... heaper; * this way it will be possible to gain more room height in the upper floor in spite of the sl
- The Passive House in summer @basics
- e results for the summer case could be determined more easily. This PHI Summer Case procedure has been... ve factor** for the assessment of summer comfort; moreover, air humidity (sultriness limit!) and air spe... in operation only in winter, * in the summer (more exactly: from 15th April to 30th September) the v... . From around 10th July temperatures of 25 °C or more are prevalent in all rooms, during very hot perio
- Primary energy – quantifying sustainability @basics:energy_and_ecology
- d determines the impact on the environment. To be more exact: * The total primary energy demand from n... owever, at some time the energy will be generated more and more from renewable sources - and this will change the picture completely. After all, the risks and... \ //Note 2: The world is furtunately substituting more and more not renewable energy sources by renewabl
- PB 41: Planning tools for the summer situation in non-residential buildings @phi_publications:pb_41
- n passively cooled buildings, will be examined in more detail for non-residential buildings. Verificati... ion of inhabited buildings. Two examples provide more information regarding the scope of application of... eached when the internal loads are increased once more by a factor of 3, which is not unrealistic in the... the simulation for the standard year, but almost more than those for the extreme year. According to
- Passive House – the next decade | Determining application-specific PER factors @basics:passive_house_-_assuring_a_sustainable_energy_supply:passive_house_the_next_decade
- 6 hours. Seasonal storage capacity (with a little more than two cycles but low efficiency) accounts for ... supply system, since it is not needed at all for more than half the year (summer!) and then is dispropo... wind turbines on the coast do deliver (slightly) more electricity in the winter, the seasonal simultane... y energy, the PER factor for heating increases to more than 2.6 kWh<sub>PER</sub>/kWh<sub>el</sub>. Clea
- Types of ventilation @planning:building_services:ventilation:basics
- e air should not be too dry either. You can find more information on the page about [[planning:building... This is just as true today – in fact it is even more important today because in these modern times we are surrounded by even more substances than before, like it or not. \\ Th... other things that have changed: - Buildings are more airtight; draughts are not acceptable any more.
- Don’t save on the insulation @planning:thermal_protection
- the following list. Taking no action will be much more expensive than carrying out insulation measures h... ney – and the better the level of insulation, the more money will be saved. The other features are also ... investment in thermal protection measures creates more employment in Europe and * the reduced energy c... * Don't save on the insulation thickness! Some more insulation material won't cost that much – otherw
- Efficiency of household appliances and their impact on the primary energy demand of residential buildings @basics:passive_house_-_assuring_a_sustainable_energy_supply
- water generation and household appliances becomes more relevant for the total primary energy demand of t... the total primary energy use of a building. Even more so where projects are seeking to achieve the rene... iance must be used, unless there is evidence that more efficient appliances have been installed. Figure ... HPP and standard values for all appliances. For a more detailed description of the methodology, please r
- Baseline study - implementing the Passive House concept in hospitals @planning:non-residential_passive_house_buildings:ph_hospitals
- . The influence of different applications becomes more relevant the more efficient the building is. Conventional energy balances, such as DIN V 18599, do not,... nces, such as DIN V 18599. These processes become more important as the building envelope and building services become more energy efficient. The applications not taken into
- Internal heat capacity @basics
- nough. For example, if temperatures of 25 °C (and more) prevail under conditions with increased solar ra... low the building to heat up on end in the summer, more heat would be stored even towards autumn and reta... tween the smallest and highest daily value is not more than 4 °C. It is evident that during the hot spe... s delays the start of the heating operation. The more heat capacity there is inside, the more pronounce
- Energy Efficiency in Domestic Electrical Energy Use @sinfonia
- to a lack of demand for higher spec’ed (and hence more expensive) smart plugs.) \\ For configuration an... iency improvements and virtually replaced by new, more efficient units. The household efficiency rating ... t of the share of energy use via the smart plugs. Moreover, utility bills were analysed for the electric... value less than half the average and the highest more than twice this value. The area-specific value’s
- Zero-energy and zero heating energy houses @basics:energy_and_ecology
- er, experience with low-energy houses has shown a more practical and easier approach: cost-efficient hig... ective: the low-energy house (LEH) proved to be a more cost-effective and simpler standard which could b... t possible to recover any further investments any more because the Passive House already dispenses with ... duction in the internal heat sources, e.g. due to more efficient lighting with the latest generation of
- Thermal insulation @planning:thermal_protection
- ation has always proven to be effective; to learn more please go to the following page: [[planning:therm... sses through external walls and roofs account for more than 70% of the total heat losses in existing bui... oil per square metre and year compared with 15 or more litres per square metre of living space used by s... sually accomplished for averaging time periods of more than one month.)). In Central Europe, the average
- Energy efficiency of the Passive House Standard: Expectations confirmed by measurements in practice @operation:operation_and_experience:measurement_results
- The world’s first Passive House, Darmstadt-Kranichstein, Germany @examples:residential_buildings:multi-family_buildings:central_europe
- Passive House and the Sustainable Development Goals (SDGs): Connecting an international building standard with global aims @basics
- Classic, Plus, Premium: The Passive House classes and how they can be reached @certification:passive_house_categories
- PER-factors for electricity use: Location & application specific decarbonisation @certification:passive_house_categories
- Passive House Schools - Boundary Conditions @planning:non-residential_passive_house_buildings:passive_house_schools
- Renewable primary energy demand in residential buildings with high energy intensity @basics:passive_house_-_assuring_a_sustainable_energy_supply
- Refurbishment with Passive House components - introduction @planning:refurbishment_with_passive_house_components
- Passive House schools – How to go about it @planning:non-residential_passive_house_buildings:passive_house_schools
- Introduction - Passive House buildings in different climates @basics:passive_houses_in_different_climates
- Aspects of efficient ventilation in hospitals @planning:non-residential_passive_house_buildings:ph_hospitals
- Certification of buildings in which the ground floor is used for commercial purposes (for PHPP 9, revised 5-Sep-2016) @certification
- Erfurt University of Applied Sciences – Faculty of Architecture @education_training:university_programmes
- Component Award 2016: Affordable ventilation solutions for retrofits @planning:refurbishment_with_passive_house_components
- Building Integrated Photovoltaics (BIPV) in Step by Step Retrofitting Projects @planning:refurbishment_with_passive_house_components
- Economy and financing of efficiency: new buildings, renovation and step by step retrofit @basics:affordability:investing_in_energy_efficiency
- Passive House - 6 reasons why you still need opening windows @planning:building_services:ventilation
- PHPP calculations in hot and humid climates @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- PHPP - validated and proven in practice @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Airtightness and airtightness measurement @planning:refurbishment_with_passive_house_components:thermal_envelope
- Evaluation of server and server room efficiency for non-residential buildings that exceed the primary energy criterion @certification
- Philips Experimental House Research 1974ff: Passive versus Active Measures in Europe & America @basics:the_passive_house_-_historical_review
- Overall retrofit plan for step-by-step retrofits to EnerPHit Standard @planning:refurbishment_with_passive_house_components
- Riedberg Passive House School, Frankfurt, Germany @examples:non-residential_buildings:passive_house_schools
- Variant calculations and economic assessment with PHPP 9 @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Insulation works – Evidence no.1 "Measurements at a highly insulated wall" @planning:thermal_protection:thermal_protection_works
- Riedberg Passive House School, Frankfurt, Germany @examples:non-residential_buildings:passive_house_schools:central_europe
- “Am Buir”, Wassenberg, Germany – the world’s smallest Passive House @examples:residential_buildings:single_-_family_houses:central_europe
- Experience with drain water heat recovery @planning:building_services:heating_and_dhw:experience_with_drain_water_heat_recovery
- PHI window certification: previous success and new climate zones @planning:thermal_protection:windows:window_certification
- Interior walls on floor slabs @basics:building_physics_-_basics:thermal_bridges:tbcalculation:examples
- Certification of terraced houses and semi-detached/duplex houses according to Passive House Institute criteria @certification
- Inhabitants report about living in a Passive House in the hot climate of Granada, Spain @experiences
- Economic analysis for the retrofit of a detached single family house to the EnerPHit standard @planning:refurbishment_with_passive_house_components
- Step-by-step deep retrofit and building integrated façade/roof on a 'million program' house @planning:refurbishment_with_passive_house_components
- Step-by-step Retrofits towards EnerPHit Standard in social housing in Spain @planning:refurbishment_with_passive_house_components
- Checklist: Test reports of airtightness measurements @planning:airtight_construction:general_principles
- “designPH” plugin for Trimble Sketchup @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Internal heat gains in relation to living area @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Insulation measures for the external envelope @planning:refurbishment_with_passive_house_components:thermal_envelope
- Energy use for heating in a well insulated new building @planning:thermal_protection:thermal_protection_works
- Basic principle for calculating thermal bridges @basics:building_physics_-_basics:thermal_bridges:tbcalculation
- Examples of thermal bridge calculations @basics:building_physics_-_basics:thermal_bridges:tbcalculation
- Comparison of in-situ measurements and hygrothermal simulations of four different interior insulation systems @planning:thermal_protection:thermal_protection_works:comparison_of_in_situ_measurements_and_hygrothermal_simulations_of_four_different_interior_insulation_systems
- Exterior wall on floor slab @basics:building_physics_-_basics:thermal_bridges:tbcalculation:examples
- Special features and characteristics of components in contact with the ground @basics:building_physics_-_basics:thermal_bridges:tbcalculation:ground_contact
- Recommended procedure for calculating thermal bridges of components in contact with the ground @basics:building_physics_-_basics:thermal_bridges:tbcalculation:ground_contact
- Electric Energy Efficiency for Households – Doing the whole step towards energy efficiency @sinfonia
- Life Cycle energy balances, Embodied energy and the Passive House Standard @basics:energy_and_ecology
- The promotion of low energy construction and the Passive House Standard: Successful strategies for forming a Passive House Association @experiences:connecting_the_passive_house_community
- Prospects for the modernisation of existing buildings using highly efficient components @planning:refurbishment_with_passive_house_components
- Passive House – the next decade | Methodology @basics:passive_house_-_assuring_a_sustainable_energy_supply:passive_house_the_next_decade
- Comparison of energy performance of ventilation systems using passive vs. active heat recovery @planning:building_services:ventilation
- Calculation guide for temperature reduction factors to temperature zone "X" in the PHPP "Areas" worksheet @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Energy efficiency in cafeterias and commercial kitchens @planning:non-residential_passive_house_buildings:cafeterias_and_commercial_kitchens
- Ventilation in commercial kitchens @planning:non-residential_passive_house_buildings:cafeterias_and_commercial_kitchens
- Influence of retrofitting on daylighting @planning:refurbishment_with_passive_house_components:mechanical_systems
- Improving thermal bridges and airtightness in existing buildings @planning:refurbishment_with_passive_house_components:thermal_envelope
- Secondary School in Baesweiler, Germany @examples:non-residential_buildings:passive_house_schools:central_europe
- Multi-family Passive House buildings in Germany @examples:residential_buildings:multi-family_buildings:central_europe