Fulltext results:
- Energy Efficiency in Domestic Electrical Energy Use @sinfonia
- used throughout a considerable improvement could be expected, e.g. with modern A+++ Fridge/Freezers u... egory. Entertainment equipment must, however, not be neglected. The recent development to ever larger ... ds to this. Particularly stand-by consumption can be large. The latter is also true for telephone/DSL routers as these are operated 24/7. These should be included in the ecodesign labelling scheme in the
- Airtightness and airtightness measurement @planning:refurbishment_with_passive_house_components:thermal_envelope
- ir change rate necessary for good quality air can be ensured with mechanical ventilation. At the very... iscomfort and heat losses because the heat cannot be recovered from air lost through building joints (... air flowing through it Two similar terms should be clarified: the __wind__tightness of a building co... to increased energy consumption. This should not be confused with __air__tightness that is being disc
- Passive House – the next decade | Determining application-specific PER factors @basics:passive_house_-_assuring_a_sustainable_energy_supply:passive_house_the_next_decade
- ings show that the supply structure that needs to be built and its efficiency depend greatly on energy... ble (pumped storage plants, etc.); it must "only" be expanded, and enough sites need to be found. The problem is, in fact, political, but it should be taken seriously, considering the prevailing attit
- PB 41: Planning tools for the summer situation in non-residential buildings @phi_publications:pb_41
- reater technologisation, these internal loads may be considerably higher than those in residential bui... nd how high the output of the cooling system must be, are therefore particularly relevant when plannin... s for such simplified methods; it is essential to be aware of the limits of this application. The focu... exceeds 25°C in passively cooled buildings, will be examined in more detail for non-residential build
- Are Passive Houses cost-effective? @basics:affordability:investing_in_energy_efficiency
- rs claim that a profit of over "200,000 Euro" can be made with a single-family Passive House. Anticip... esigned competently. But quick profits should not be expected. The Passive House is more stable, more ... urse, the risk of losing a lot of money will also be greater).\\ \\ ===== An analysis using the exampl... f 149 m². It's not a Passive House – but it would be quite easy to build it as a Passive House. For th
- Greenhouse effect and climate protection @basics:energy_and_ecology
- ssion of greenhouse gases into the atmosphere can be tremendous and irreversible. Some of these effect... e - at least in part. The worst consequences can be avoided by taking responsible action, right now.*... y. More possibilities for practical measures will be shown here and on the the other pages of passiped... e in vegetation on the northern \\ hemisphere can be seen clearly. (Data up to 2006. \\ In the meantim
- Dynamic simulation of a building's thermal performance @planning:calculating_energy_efficiency
- measured in detail. A single room ("zone") will be modelled by DYNBIL as shown in fig. 1. In the me... heat gains. General assumptions on heat gains may be tolerable for energy inefficient buildings, but l... bil_multizonal.png|}}| |Fig. 2 Several zones will be connected to a building model with air flows betw... t conduction in solids and non-flowing fluids can be described by Fourier's dynamic heat conduction eq
- Windows in a step-by-step retrofit @planning:refurbishment_with_passive_house_components
- ndows are put in between tenants, or a window may be in such bad shape that it cannot wait. If a façad... any windows renewed “in the meantime” will still be in good shape and not need retrofitting. In addition, building users may not wish to be bothered further. Often, there simply is not enou... nsus. Ideally, windows and façades should always be retrofitted simultaneously whenever possible. Whe
- Airtightness measurements in Passive Houses @planning:airtight_construction
- ss measurements in Passive House buildings are to be carried out uniformly worldwide according to ISO ... of the reference volume for passive houses is to be carried out according to the procedure listed bel... part of the ISO 9972. The resulting volume is to be used for the determination of the n<sub>50</sub>-... \\ For the calculation and documentation, it can be helpful to use the "room data", which is included
- The Passive House in summer @basics
- with which the results for the summer case could be determined more easily. This PHI Summer Case pr... fortable in summer**. Later on, other cases will be dealt with which result in much more favourable i... ve the maximum indoor air temperature. It should be noted that in this base case (except for the smal... ase as a regular annual duration curve; it should be understood as follows: in Zone VI (upper floor so
- Economy and financing of efficiency: new buildings, renovation and step by step retrofit @basics:affordability:investing_in_energy_efficiency
- ==== The economic assessment of buildings has to be based on life cycle costs. From the beginning thi... sult much lower than they are, which turns out to be a strong barrier for the implementation of energy... ildings implies that short payback periods cannot be expected; they are not good indicators since they... he whole life cycle as well as the interests must be regarded. This view is implemented in dynamical m
- Introduction: Retail stores as Passive Houses @planning:non-residential_passive_house_buildings
- n moderately insulated building envelopes have to be cooled all throughout the year. Increasingly long... consumption. The primacy of economy will have to be accepted in all cases: turnover is all-important;... the energy demand of retail stores do not have to be economically viable by themselves; above all, they must be compatible with the sales concept. \\ [{{ :picop
- Thermal insulation @planning:thermal_protection
- ng demand the entire **building envelope** has to be well insulated. The building envelope consists of... ection comes in. -> Good thermal protection can be achieved for **all construction methods** and has... -> An appropriate level of insulation can also be applied to **existing buildings** at any given po... . A high level of insulation has always proven to be effective; to learn more please go to the followi
- Passive House schools – How to go about it @planning:non-residential_passive_house_buildings:passive_house_schools
- hools:Passive House schools – requirements]] can be met with justifiable effort. These recommendations are not meant to be requirements – it is possible to deviate from them, but then compensating measures must generally be taken elsewhere. Calculations using the PHPP for ... gs. A/V ratios of less than 0.4 m²/m³ can usually be achieved if the buildings are well-planned, and n
- Energy balances - Background @planning:calculating_energy_efficiency
- fic area. Consequently, energy balances can only be prepared for restricted spatial areas with clearl... is sinking. However, this is exactly what should be prevented in order to maintain living comfort. Therefore, the energy flowing out has to be replaced: another heat flow must travel from the... eplacement of this heat loss \\ and can therefore be reduced as required by more effective prevention
- Introduction - Passive House buildings in different climates @basics:passive_houses_in_different_climates
- Internal heat gains in relation to living area @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Passive House Schools - Boundary Conditions @planning:non-residential_passive_house_buildings:passive_house_schools
- Certification of buildings in which the ground floor is used for commercial purposes (for PHPP 9, revised 5-Sep-2016) @certification
- The world’s first Passive House, Darmstadt-Kranichstein, Germany @examples:residential_buildings:multi-family_buildings:central_europe
- Overall retrofit plan for step-by-step retrofits to EnerPHit Standard @planning:refurbishment_with_passive_house_components
- Energy efficiency of the Passive House Standard: Expectations confirmed by measurements in practice @operation:operation_and_experience:measurement_results
- Refurbishment with Passive House components - introduction @planning:refurbishment_with_passive_house_components
- Baseline study - implementing the Passive House concept in hospitals @planning:non-residential_passive_house_buildings:ph_hospitals
- Classic, Plus, Premium: The Passive House classes and how they can be reached @certification:passive_house_categories
- Component Award 2016: Affordable ventilation solutions for retrofits @planning:refurbishment_with_passive_house_components
- Aspects of efficient ventilation in hospitals @planning:non-residential_passive_house_buildings:ph_hospitals
- Exterior wall on floor slab @basics:building_physics_-_basics:thermal_bridges:tbcalculation:examples
- Efficiency of household appliances and their impact on the primary energy demand of residential buildings @basics:passive_house_-_assuring_a_sustainable_energy_supply
- PER-factors for electricity use: Location & application specific decarbonisation @certification:passive_house_categories
- Step-by-step Retrofits towards EnerPHit Standard in social housing in Spain @planning:refurbishment_with_passive_house_components
- Evaluation of server and server room efficiency for non-residential buildings that exceed the primary energy criterion @certification
- Step-by-step deep retrofit and building integrated façade/roof on a 'million program' house @planning:refurbishment_with_passive_house_components
- Insulation works – Evidence no.1 "Measurements at a highly insulated wall" @planning:thermal_protection:thermal_protection_works
- Passive House and the Sustainable Development Goals (SDGs): Connecting an international building standard with global aims @basics
- Renewable primary energy demand in residential buildings with high energy intensity @basics:passive_house_-_assuring_a_sustainable_energy_supply
- Recommended procedure for calculating thermal bridges of components in contact with the ground @basics:building_physics_-_basics:thermal_bridges:tbcalculation:ground_contact
- 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
- Passive House - 6 reasons why you still need opening windows @planning:building_services:ventilation
- Erfurt University of Applied Sciences – Faculty of Architecture @education_training:university_programmes
- Economic analysis for the retrofit of a detached single family house to the EnerPHit standard @planning:refurbishment_with_passive_house_components
- 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
- Basic principle for calculating thermal bridges @basics:building_physics_-_basics:thermal_bridges:tbcalculation
- Interior walls on floor slabs @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
- 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
- “designPH” plugin for Trimble Sketchup @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Playing on the Passive House hill - the new kindergarten in the Heidenau city park @examples:non-residential_buildings:passive_house_kindergartens:central_europe
- Building Integrated Photovoltaics (BIPV) in Step by Step Retrofitting Projects @planning:refurbishment_with_passive_house_components
- Improving thermal bridges and airtightness in existing buildings @planning:refurbishment_with_passive_house_components:thermal_envelope
- Experience with drain water heat recovery @planning:building_services:heating_and_dhw:experience_with_drain_water_heat_recovery
- Riedberg Passive House School, Frankfurt, Germany @examples:non-residential_buildings:passive_house_schools
- Comparison of energy performance of ventilation systems using passive vs. active heat recovery @planning:building_services:ventilation
- PHPP - validated and proven in practice @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
- Energy use for heating in a well insulated new building @planning:thermal_protection:thermal_protection_works
- Checklist: Test reports of airtightness measurements @planning:airtight_construction:general_principles
- Insulation measures for the external envelope @planning:refurbishment_with_passive_house_components:thermal_envelope
- Software for calculating thermal bridges @basics:building_physics_-_basics:thermal_bridges:tbcalculation
- PHPP calculations in hot and humid climates @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Single-family Passive House buildings in Germany and Austria @examples:residential_buildings:single_-_family_houses:central_europe
- Sound generation, sound dispersion and sound proofing in heat pumps @planning:building_services:heating_and_dhw:heating:heat_pumps
- Certification of terraced houses and semi-detached/duplex houses according to Passive House Institute criteria @certification
- Danube University Krems, Austria - Postgraduate University Program “Future Building Solutions, MSc” @education_training:university_programmes
- Multi-family Passive House buildings in Germany @examples:residential_buildings:multi-family_buildings:central_europe
- 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
- Philips Experimental House Research 1974ff: Passive versus Active Measures in Europe & America @basics:the_passive_house_-_historical_review
- Prospects for the modernisation of existing buildings using highly efficient components @planning:refurbishment_with_passive_house_components
- Ventilation in commercial kitchens @planning:non-residential_passive_house_buildings:cafeterias_and_commercial_kitchens
- “Am Buir”, Wassenberg, Germany – the world’s smallest Passive House @examples:residential_buildings:single_-_family_houses:central_europe
- PHI window certification: previous success and new climate zones @planning:thermal_protection:windows:window_certification
- Passive House – the next decade | Methodology @basics:passive_house_-_assuring_a_sustainable_energy_supply:passive_house_the_next_decade
- Variant calculations and economic assessment with PHPP 9 @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Playing in a Passive House - A timber/mudbrick building for children @examples:non-residential_buildings:passive_house_kindergartens:central_europe
- Riedberg Passive House School, Frankfurt, Germany @examples:non-residential_buildings:passive_house_schools:central_europe
- Secondary School in Baesweiler, Germany @examples:non-residential_buildings:passive_house_schools:central_europe
- The Nestwerk Residential Project in Dresden @examples:residential_buildings:multi-family_buildings:central_europe
- Influence of retrofitting on daylighting @planning:refurbishment_with_passive_house_components:mechanical_systems
- Floor Replacement: Svartbäcksvägen @planning:refurbishment_with_passive_house_components:thermal_envelope
- Factors that influence the energy balance and affordability of non-residential EnerPHit projects @basics:affordability:investing_in_energy_efficiency:economic_feasibility_of_passive_house_retrofits