Fulltext results:
- PB 41: Planning tools for the summer situation in non-residential buildings @phi_publications:pb_41
- ndary conditions that are relevant for the summer can differ significantly from those in residential buildings. Sometimes concentrated internal heat loads m... uisition and application of suitable models, this can predict the thermal conditions inside the buildin... r in this Protocol Volume. The room being studied can be situated in the centre of one side of the buil
- Greenhouse effect and climate protection @basics:energy_and_ecology
- emission of greenhouse gases into the atmosphere can be tremendous and irreversible. Some of these eff... table - at least in part. The worst consequences can be avoided by taking responsible action, right no... ouse Institute has been working on concepts which can help to avert some of the worst consequences. Th... ibute to climate protection, so that our children can inherit from us an Earth where life is worth livi
- The Passive House in summer @basics
- e|[PHPP 2007] ]]. Each planner of a Passive House can determine the influences, as dealt with below, fo... he hot period in the room "South Top Floor". One can see that all indoor temperatures in this time per... ouse, even **during the critical hot period**, it can be seen that with this method, an **excellent ind... Passive House suitable ventilation systems – and can be achieved by means of a bypass or a summer cass
- Energy Efficiency in Domestic Electrical Energy Use @sinfonia
- s adds to this. Particularly stand-by consumption can be large. The latter is also true for telephone/D... ard energy consumption figures from energy labels can indeed be used to make a reasonable estimate of t... \\ \\ \\ \\ \\ \\ \\ \\ \\ \\ \\ \\ \\ \\ \\ As can be seen in Fig. 4 the electricity usage is spread... to 2715 kWh/a per household. \\ A 24% reduction can be expected if a routine energy consulting encour
- Passive House – the next decade | Determining application-specific PER factors @basics:passive_house_-_assuring_a_sustainable_energy_supply:passive_house_the_next_decade
- sufficient storage used for natural gas), significantly increases costs for the applications that need... ating, e.g.) because of high losses; this problem can also be solved (with improved efficiency).)), sin... e medium-term grid storage (pumped storage, etc.) can generally balance them out. The situation is different when an application's demand has significant seasonal fluctuations, such as when heating drop
- Insulation vs. thermal mass @planning:thermal_protection:thermal_protection_works
- e full (German) version of the summary given here can be ordered from the following link: [[https://sho... oved principles, the serious scientific community cannot thoroughly prove any of its statements.** In f... ts possible today. Furthermore, these statements can be checked by everyone, even regarding the topic ... author himself experienced that: the temperatures can sink to below zero – the water in the flower vase
- Efficiency of household appliances and their impact on the primary energy demand of residential buildings @basics:passive_house_-_assuring_a_sustainable_energy_supply
- , the energy demand from appliances (white goods) can be the largest share [Ottinger 2017]. It is then ... e efficiency of household appliances and how they can contribute to reducing the total primary energy u... fixed boundary conditions, while the norm demand can be changed. It must be noted that for certificati... ese devices. For the cases where the design teams can select efficient appliances, their contribution t
- Dynamic simulation of a building's thermal performance @planning:calculating_energy_efficiency
- heat conduction in solids and non-flowing fluids can be described by Fourier's dynamic heat conduction... the flow problem for a room in a stationary case can be tackled numerically with some effort today usi... ith under the boundary conditions that are significantly determined by the other components. This is on... l (e.g. Fourier problem with boundary conditions) can no longer be solved analytically. Already here yo
- Are Passive Houses cost-effective? @basics:affordability:investing_in_energy_efficiency
- others claim that a profit of over "200,000 Euro" can be made with a single-family Passive House. Anti... he roof will have to met some 0.12 W/(m²K), which can be achieved in a lot of different ways and what w... floor areas result. Since the value of such areas can be set to be high or low and this has very little... orresponding to n<sub>50</sub>=0.4 h<sup>-1</sup> can be achieved** with this approach. There are no ex
- Energy efficiency of the Passive House Standard: Expectations confirmed by measurements in practice @operation:operation_and_experience:measurement_results
- ngs. The reliability of the Passive House concept can be judged from these results. \\ With all building standards there are significant differences in consumption due to user behaviour... ed homes so that utilisation-dependent influences can be averaged out, thereby enabling a comparison of... sive House homes in Germany. A number of insights can be gained from these measurement results.\\ [{{ :
- List of Passive House Conference contributions since 1996 @phi_publications
- t |Frankfurt am Main, Passive House Capital - how can the success story continue? |73 | |2013 |17 |Pa... ting the real heat loss of a Passivhaus building: Can the UK’s energy performance gap be bridged? |169 ... ting the real heat loss of a Passivhaus building: Can the UK’s energy performance gap be bridged? |159 ... gy sustainability: what the Passive House concept can do up to 2060 |503 | |2013 |17 |Nachhaltigkeit
- Efficiency vs. Efficiency Factor @basics
- hing to do with energy. For example, the benefit can be a mileage (unit "miles"). For example, the effort can be the fuel required (unit "gallons") and the eff... example, the efficiency factor of heating boilers cannot be increased to more than 100% (law of energy ... ng application (e.g. heated space/heating energy) can be improved almost as far as you want by applying
- Energy balances - Background @planning:calculating_energy_efficiency
- s conserved** - it is never lost. However, energy can leave a certain area, resulting in **"energy loss... his specific area. Consequently, energy balances can only be prepared for restricted spatial areas wit... e, is only a replacement of this heat loss \\ and can therefore be reduced as required by more effectiv... of the heat gains.** |\\ \\ As the heat losses can be easily and relatively acurately calculated (th
- Introduction: Retail stores as Passive Houses @planning:non-residential_passive_house_buildings
- g. For example, in the food sector this is significantly less than 10 years. Conversely, this means tha... heating which dominates in existing buildings and can be easily influenced in terms of planning. Added ... plays a secondary role here. Much greater savings can be realised in other areas. This will be discusse... owards the outside so that internal heating loads can be limited.**}}] In the food sector in smaller r
- Airtightness and airtightness measurement @planning:refurbishment_with_passive_house_components:thermal_envelope
- he air change rate necessary for good quality air can be ensured with mechanical ventilation. At the v... auses discomfort and heat losses because the heat cannot be recovered from air lost through building jo... irtightness ===== The airtightness of a building can be measured by means of an air pressure test (air... per 2000] ]]). Such excellent airtightness levels can also be achieved for modernised buildings if airt
- 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
- Aspects of efficient ventilation in hospitals @planning:non-residential_passive_house_buildings:ph_hospitals
- Overall retrofit plan for step-by-step retrofits to EnerPHit Standard @planning:refurbishment_with_passive_house_components
- The world’s first Passive House, Darmstadt-Kranichstein, Germany @examples:residential_buildings:multi-family_buildings:central_europe
- Baseline study - implementing the Passive House concept in hospitals @planning:non-residential_passive_house_buildings:ph_hospitals
- Economy and financing of efficiency: new buildings, renovation and step by step retrofit @basics:affordability:investing_in_energy_efficiency
- Life Cycle energy balances, Embodied energy and the Passive House Standard @basics:energy_and_ecology
- Erfurt University of Applied Sciences – Faculty of Architecture @education_training:university_programmes
- Passive House schools – How to go about it @planning:non-residential_passive_house_buildings:passive_house_schools
- 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
- Influence of retrofitting on daylighting @planning:refurbishment_with_passive_house_components:mechanical_systems
- Insulation works – Evidence no.1 "Measurements at a highly insulated wall" @planning:thermal_protection:thermal_protection_works
- Internal heat gains in relation to living area @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Renewable primary energy demand in residential buildings with high energy intensity @basics:passive_house_-_assuring_a_sustainable_energy_supply
- 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
- Playing on the Passive House hill - the new kindergarten in the Heidenau city park @examples:non-residential_buildings:passive_house_kindergartens:central_europe
- Experience with drain water heat recovery @planning:building_services:heating_and_dhw:experience_with_drain_water_heat_recovery
- Special features and characteristics of components in contact with the ground @basics:building_physics_-_basics:thermal_bridges:tbcalculation:ground_contact
- Evaluation of server and server room efficiency for non-residential buildings that exceed the primary energy criterion @certification
- 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
- Passive House - 6 reasons why you still need opening windows @planning:building_services:ventilation
- PHPP - validated and proven in practice @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- St. Josef Caritas-Haus, Germany - the first prefabricated large module Passive House nursing home @examples:residential_buildings:nursing_homes:central_europe
- Exterior wall on floor slab @basics:building_physics_-_basics:thermal_bridges:tbcalculation:examples
- Introduction - Passive House buildings in different climates @basics:passive_houses_in_different_climates
- Component Award 2016: Affordable ventilation solutions for retrofits @planning:refurbishment_with_passive_house_components
- Basic principle for calculating thermal bridges @basics:building_physics_-_basics:thermal_bridges:tbcalculation
- Playing in a Passive House - A timber/mudbrick building for children @examples:non-residential_buildings:passive_house_kindergartens:central_europe
- Philips Experimental House Research 1974ff: Passive versus Active Measures in Europe & America @basics:the_passive_house_-_historical_review
- Building Integrated Photovoltaics (BIPV) in Step by Step Retrofitting Projects @planning:refurbishment_with_passive_house_components
- 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
- Improving thermal bridges and airtightness in existing buildings @planning:refurbishment_with_passive_house_components:thermal_envelope
- Multi-family Passive House buildings in Germany @examples:residential_buildings:multi-family_buildings:central_europe
- The Nestwerk Residential Project in Dresden @examples:residential_buildings:multi-family_buildings:central_europe
- Comparison of energy performance of ventilation systems using passive vs. active heat recovery @planning:building_services:ventilation
- “designPH” plugin for Trimble Sketchup @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Energy use for heating in a well insulated new building @planning:thermal_protection:thermal_protection_works
- Neuwerk Caritas-Haus, Germany - the world’s first Passive House nursing home for the elderly @examples:residential_buildings:nursing_homes:central_europe
- Electric Energy Efficiency for Households – Doing the whole step towards energy efficiency @sinfonia
- Prospects for the modernisation of existing buildings using highly efficient components @planning:refurbishment_with_passive_house_components
- Software for calculating thermal bridges @basics:building_physics_-_basics:thermal_bridges:tbcalculation
- Certification of terraced houses and semi-detached/duplex houses according to Passive House Institute criteria @certification
- Refurbishment with Passive House components - introduction @planning:refurbishment_with_passive_house_components
- Riedberg Passive House School, Frankfurt, Germany @examples:non-residential_buildings:passive_house_schools
- Checklist: Test reports of airtightness measurements @planning:airtight_construction:general_principles
- 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
- Ventilation in commercial kitchens @planning:non-residential_passive_house_buildings:cafeterias_and_commercial_kitchens
- Riedberg Passive House School, Frankfurt, Germany @examples:non-residential_buildings:passive_house_schools:central_europe
- 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
- Recommended procedure for calculating thermal bridges of components in contact with the ground @basics:building_physics_-_basics:thermal_bridges:tbcalculation:ground_contact
- Passive House – the next decade | Methodology @basics:passive_house_-_assuring_a_sustainable_energy_supply:passive_house_the_next_decade
- PHPP calculations in hot and humid climates @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Sound generation, sound dispersion and sound proofing in heat pumps @planning:building_services:heating_and_dhw:heating:heat_pumps
- The overall heat transfer coefficient or U-value @planning:calculating_energy_efficiency:phpp_-_the_passive_house_planning_package
- Variant calculations and economic assessment with PHPP 9 @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