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References for:
Achieving climate neutrality in the building sector by 2050
Klimatická neutralita budov do roku 2050
Konstrukce a monitoring první veřejné školy v USA v pasivním standardu
Pasivní dům – rozvoj ve všech směrech
Větrání a kvalita vzduchu v bytech po rekonstrukci s běžným větráním okny a s řízeným větráním
Comparison of accounted costs of renovation: a low energy building and a Passive House side by side
The Passive House as a prototype of the "Nearly Zero Energy Building"
Las Vegas: A location in a hot, dry climate
Dubai: A location in a hot, humid climate
Condensation on exterior surfaces in tropical climates
Design guidelines for tropical Passive Houses
Free-running buildings in tropical climates
Interior insulation in tropical climates
Mechanical services in tropical climates
Design guidelines for tropical Passive Houses
Mumbai: A location in a tropical climate
Mumbai: Dynamic building simulation for a Reference Passive House
Salvador da Bahia: A location in a tropical climate
Salvador da Bahia: Dynamic building simulation for a Reference Passive House
Singapore: A location in a tropical climate
Singapore: Dynamic building simulation for a Reference Passive House
Hygrothermal analysis of building components for the location Singapore
Hygrothermal analysis of building components for tropical climates
Summary of the parametric studies for tropical climates
Frost protection for ventilation heat recovery
Frost-free foundations
Yekaterinburg: A location in a cold climate
Yekaterinburg: Findings
Yekaterinburg: Parameter variations
Results of the parameter studies - Basement Ceiling Insulation
Results of the parameter studies - Compactness
Results of the parameter studies - Infiltration
Results of the parameter studies - Roof Insulation
Results of the parameter studies - Wall Insulation
Results of the parameter studies - Window Area
Dynamic building simulation for a Reference Passive House
Passive House in warm climates - best-practice strategies
Passive Houses in South-West Europe - a theoretical analysis
Shanghai: A location in a subtropical, mild climate
Solutions for heating and cooling supply in moist-warm climates
Version 1: Supply air heating and cooling
Version 2: heating, cooling, and dehumidification in all supply air rooms
Version 3: Heating and cooling through tempered intermediate ceilings, central dehumidification
Solutions for high outdoor air humidity in the summer
Tokyo/Hyakuri: A location in a subtropical, mild climate
Passive House in different climate zones - building services
Passive House in different climate zones - technical and economic feasibility
Climate conditions
Description of the calculation model and method
The Passive House concept in New Zealand
The Passive House concept in New Zealand: Conclusion
Conventional building in New Zealand
The Passive House concept in New Zealand: Humidity
Insulation levels
North-oriented window area
The Passive House concept in New Zealand: Orientation
Parameter variations
PHPP
The Passive House concept in New Zealand: Summer comfort
The Passive House concept in New Zealand: Thermal insulation
Thermal mass
The Passive House concept in New Zealand: Ventilation
The Passive House concept in New Zealand: Window quality
Adapted window qualities
Climate data sets from EOSWEB
Choosing locations
Hygrothermal analysis of building components
Reference site: Essen
Dynamic building simulations for Reference Passive Houses
Nuremberg case study: Air exchange and air distribution testing
Nuremberg case study: Examination of the external envelope using thermographic imaging
Nuremberg case study: Testing for airtightness
Nuremberg case study: Thermographic inspection with reference to building services
The logical path - From Passive House to zero-emission house: renting without heating bills
Certification and primary energy balance calculation for compact heat pumps
Air conveyance
Airtightness
Chimneys
Wood Stoves
Non-room-sealed operation
Room-sealed operation
Safety considerations
Available systems, example application and analysis
Heating and DHW systems in Passive Houses - Appendix
Heating and DHW systems in Passive Houses - Case study: Schrecksbach, Germany
Heating and DHW systems in Passive Houses - Cost development
Systems adapted for the Passive House
The specific PE value - parameters
Biomass heating in Passive Houses
Sound protection measures for heat pumps - Analysis of sound paths
Sound protection measures for heat pumps - Dimensioning sound insulation
Sound protection measures for heat pumps - Excitation sources in heat pumps
Sound protection measures for heat pumps
Conditions for dimensioning
Possibilities and limitations for setting up devices
Practical implementation of the encasing (enclosure)
Prevention of airborne sound through walls
Sound protection simulation based on EN 12354
Soundproofing of doors
Suspended ceiling with duct installation
Passive House heating systems in practice - A brief description of the projects
Passive House heating systems in practice - Classification and procedures
Passive House heating systems in practice - Electricity consumption
Passive House heating systems in practice - Heat consumption and heating load
Passive House heating systems in practice - Primary energy
Passive House heating systems in practice - Total useful energy and losses
Method
Parameter variation
Reduction of the supply air rate in the living room
Conclusions / planning tips
Automatic volume flow balancing in ventilation units
Flow rate adjustment in ventilation systems
Calculating the Treated Floor Area
Comparison with dynamic simulation
PHPP: Active cooling algorithms
Climate data tool
Climate data tool for the Southern Hemisphere
PHPP - Solar DHW worksheet
Comfort
Dynamic response of a commercial kitchen
Energy balance according to PHPP
Energy flows in cooking equipment
Energy flows in dishwashers
Exemplary approaches for kitchen appliances – "solutions in the appliance"
Reducing demand for extract air
Air Quality in Schools
Impact of additional reveal shading (external insulation) on the daylight factor
Obstructions and atria
Visual transmission through multi-pane glazing
Overview of inter-dependence of individual energy efficiency measures
Heating balances of modernisation variants
Home ventilation
Improved airtightness in existing buildings
Passive House windows
Structural thermal protection measures
Suggestions for promoting implementation
Special features of modernisations
Main objectives of refurbishments with Passive House components
Improving thermal bridges and airtightness in existing buildings
Basement ceiling insulation
Roof insulation
Thermal insulation of the exterior wall
Interior Insulation – basics
Minimising thermal bridges in existing buildings
Basic principles for windows - research on energy efficient modernisation
Integration of ventilation ducts
Optimization of roller shutters and exterior blinds
Passive House windows completely redesigned
Required U-values for Passive House windows
Adapting the certification criteria and glazing for European climate zones
Heat pumps in Passive Houses – PHPP application

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