Relative Humidity - What is it and why should you care?
Presented by David Hill, President, Eneready Products
Relative humidity is a measure of moisture content in the air compared to the maximum that air could hold if it were fully saturated (i.e. steamy bathroom).
Absolute moisture, a less used but still important term, is a measure of weight in 'grains of water' contained in 1 pound of dry air.
Maintaining the correct relative humidity (RH) is important for the health of:
a) the residence itself and
b) our ultimate customer, 'Ms Smith' its owner/occupant.
Although the 2 ideal RHs levels are slightly different, the difference between them is small and in good buildings, a compromise will satisfy both. HVAC systems are a part of the solution, but unfortunately only 1/2 of that required for effective RH control. The builder's attention to detailing of the air barrier and insulation layer is critical, but that is not always done well.
Due to ground breaking research at the Vancouver Test Hut, (read Leaky Condo Research Project) Mark Gauvin (builder) and Dr. Joe Lstiburek P.Eng. (researcher) have shown that wood frame homes, an inherently affordable method of construction can satisfy both and provide decades of good service if they are:
a) externally insulated,
b) have an effective (sealed) air barrier and in when located in coastal areas
c) have a ventilated rain screen (cavity) incorporated beneath the exterior cladding.
In a building devoid of either or both a) & b) above, if we were to forcibly raise the relative humidity in aide of Ms Smith's lung health, the risk of damage to the house is real and will likely show up with:
a) excess moisture in the attic and/or
b) mildew/moisture in cool dead corners of closets and basements ultimately compromising respiratory health.
In defence of adding RH is winter, Dr. Stephanie Taylor's recent research has shown that our natural human immunity against infectious bacteria and viruses increases when relative humidity levels rise above 40% in a well-built home, a good HVAC system will have an effect and can:
- Lower RH using ventilation in the winter and A/C in summer and
- Raise RH with humidification. While in winter this will increase the moisture stress across the exterior wall and ceiling this can be done, in moderation without risk
David Hill will share his experience and first-hand knowledge on this often misunderstood topic.
TECA Discussion on Air-to-Water Heat Pumps
Presented by Jeremy Young, TECA Board Member and Quality First Instructor
Jeremy Young presents an overview of currently available technologies for residential hydronic heating, chilled water cooling and domestic hot water using air-source heat pumps. The presentation includes details on suitable applications, strategies to enhance efficiency and reliability, as well as defining the common mistakes made by experienced designers and installers who come from backgrounds with fossil-fuel based hydronic heat sources and how to mitigate those risks.
Principles of Radiant Cooling and Heating
Presented by SAEED DANESH, Technical Project Specialist - Building Technology, REHAU
This TECA presentation covers the principles of radiant heating and cooling systems, highlighting how they function and integrate within modern building design. Key benefits such as improved thermal comfort, enhanced energy efficiency, and alignment with electrification and carbon-reduction goals are discussed. Real-world project references are also shared to demonstrate practical applications and performance outcomes.
A2L & Low Global Warming Potential (GWP) Transition
Presented by: Micah van der Heide, RSE/Technical Support & Training Manager, Refrigerative Supply
Micah will present on Low GWP / A2L refrigerants and discuss some of the important upcoming changes that will impact the HVAC industry. The transition to refrigerants with lower global warming potential (GWP) is driven by worldwide initiatives to decrease greenhouse gas emissions.
The U.S. Environmental Protection Agency (EPA) mandated a switch to refrigerants with a GWP of 700 or less by January 1, 2025.
The Canadian government enacted the Regulations Amending the Ozone-depleting Substances and Halocarbon Alternatives Regulations, which set a phasedown of HFC consumption. This means the HVAC/R industry is phasing down the production and consumption of Hydrofluorocarbons (HFCs) refrigerants and is transitioning to lower GWP refrigerants such as R-454B and R-32.
Modeling a Refuge Room Using CSA F280 Standards
Todd Backus presents his approach to use CSA F280 guidelines to model cooling in a single living space in order to meet the requirements for maintaining a 26°C indoor air temperature in one living space which is outlined in section 9.33.3.1. of the BCBC. The CSA F280 standard was not designed to model a single room, therefore, some assumptions are required to generate an accurate model.
Todd discusses appropriate strategies and design considerations to meet code minimums and improve the thermal comfort of the occupants when determining which areas should be cooled. Todd also identifies how the internal loads of a building are calculated and why buildings with low summer design temperatures still generate a significant heat gain load.
Several challenges for proving that active cooling is not required are also highlighted and the information that would be required to make the argument that active cooling is not required to meet the intent of the code are also discussed.
LEEP Workshops for HVAC Trades - Introduction
Introduction by: Sneha Bernard
Project Lead, Local Energy Efficiency Partnerships (LEEP)
Natural Resources Canada/Government of Canada
The following series of videos are from a LEEP heat pump workshop that examines a case study home in Burnaby, BC. The presenters walk through a design approach that uses best practices to accurately size a heat pump system in a retrofit application. Although many HVAC contractors make estimates on equipment sizing based on past experience and simple calculations of a certain number of BTUH per square foot of a building, the more sophisticated method of modeling and measuring critical design data will result in a more efficient and cost-effective installation on some projects.
LEEP Workshops for HVAC Trades - Part 1 | Sizing Heat Pumps for Retrofit Applications
Presented by: Gilles Lesage, Total Home Solutions Inc.
This video discusses the use of CSA F280 for calculating the heat loss & heat gain of a building. It highlights how accurate calculations assists with correctly sizing HVAC equipment, as oversizing heat pumps can cause cascading problems throughout the design process.
LEEP Workshops for HVAC Trades - Part 2 | Electrical Service Impacts of Heat Pump Retrofits
Presented by:
Gary Hamer, BC Hydro
Ben Guidici. Riverside Energy Systems
This presentation discusses how design decisions can facilitate or even avoid an electrical service upgrade during a renovation. Careful electrical load analysis by a professional, as outlined in the CEC is a powerful tool. In some cases, a demonstrated load might be the right solution for avoiding an unnecessary electrical upgrade.
LEEP Workshops for HVAC Trades - Part 3 | Mastering Control Systems for Optimal Heat Pump Performance
Presented by: Gilles Lesage, Energy Advisor, Total Home Solutions Inc.
This video discusses different control strategies for a dual fuel system and how the selection of a balance point impacts the performance and cost of a heating and cooling system. Understanding the economics and the priorities of a client are critical to making informed decisions on control schemes.
LEEP Workshops for HVAC Trades - Part 4 | Air Source Heat Pump (ASHP) Sizing & Selection Tool
Presented by: Jérémie Leger, NRCan
NRCan has produced a free air source heat pump sizing & selection tool. Jérémie provides an introduction on how this powerful tool can be used to compare and select heat pumps for a specific project, providing better systems at more competitive process.
For more information about ASHP tool, its download options and how to use the toolkit guides, please visit the following link: https://natural-resources.canada.ca/maps-tools-and-publications/tools/modelling-tools/toolkit-for-air-source-heat-pump-sizing-and-selection/23558
TECA's Hydronic Systems Design course explained
Presented by Todd Backus, P.Eng.
TECA Manager & Programs Development
TECA's Hydronic Systems Design manual with Hydronic & Combo Guidelines forms the basis of our Registered Designer program. Trains those working with hot water heating to properly design a residential hot water heating system to meet the guidelines established by the Residential Hot Water Heating Association of BC. Quality First Registered Hydronic Designers receive a numbered certificate, wallet card and stamp for submitting system drawings from the Guidelines to inspection authorities. These Guidelines are used in conjunction with the TECA Hydronics Systems Design Manual when designing systems. The drawings in these guidelines are approved boiler room and system layouts and are used by many BC authorities having jurisdiction for inspections of hydronic installations.
Quality First Registered Hydronic Designers receive a numbered certificate, wallet card and optional stamp for submitting system drawings from the Guidelines to inspection authorities.
