This article explores some of the latest products and solutions improving the air quality, thermal comfort, electric light, and daylight control that can be incorporated into a project. Each improves the wellness of the people in the built environment.

HSW Justification:
“Increased evidence shows that indoor environmental conditions substantially influence health and productivity. Building services engineers are interested in improving indoor environments and quantifying the effects. Potential health and productivity benefits are not yet generally considered in conventional economic calculations pertaining to building design and operation. Only initial costs plus energy and maintenance costs are typically considered. A few sample calculations have also shown that many measures to improve indoor air environment are cost-effective when the health and productivity benefits resulting from an improved indoor climate are included in the calculations (Djukanovic et al. 2002, Fisk 2000, Fisk et al. 2003, Hansen 1997, van Kempski 2003, Seppanen and Vuolle 2000, Wargocki, 2003.) This article explores some of the latest products and solutions improving the air quality, thermal comfort, electric light, and daylight control that can be incorporated into a project. Each improves the wellness of the built environment.

Learning Objective 1:
Explain how air circulation improves thermal comfort and alertness.

Learning Objective 2:
Describe the ways that increasing the presence of plants and greenery on a project have been shown to clean the air, reduce urban heat island effect, and positively affect the health and wellbeing of people in the built environment.

Learning Objective 3:
Summarize how circadian LED lighting technology delivers health benefits—improving overall sleep quality, daytime productivity, and feelings of wellbeing—that modern architectural lighting lacks.

Learning Objective 4:
Discuss how using an underfloor air distribution system (UFAD) improves indoor air quality.

Learning Objective 5:
Identify the latest advancements in smart window technology that allows these solutions to control glare and solar heat gains, while maintaining views to the outdoors.

Program: The Art and Technology of Lighting

This course will explore the use of exterior lighting to illuminate building facades, landscapes, pathways, plazas, and points of interest, like statues. Popular techniques (moonlighting, wall washing, grazing, etc.) will be defined and the performance of various lighting fixtures will be compared to help designers identify the fixtures best-suited for particular applications. Important considerations including: energy codes, dark sky criteria, and occupant safety will be addressed. The renovation of the exterior lighting at the Greater Columbus Convention Center, designed by Ardra Zinkon, will be profiled.

HSW Justification:
Exterior lighting can facilitate the enjoyment of an outdoor space and enhance the feeling of safety and security people experience in these areas, but the design of exterior lighting systems must accomplish more than bathing an area in illumination indiscriminately. Energy codes limit the amount of energy that the lighting system can consume and define lighting controls requirements to minimize energy waste. In addition, the Model Lighting Ordinance (MLO), developed by the International Dark Sky Association (IDA) and the Illuminating Engineering Society (IES), provides guidance on ways to reduce light pollution and glare that can be created by outdoor lighting. This course will provide designers with tips on how to create exterior lighting solutions that satisfy energy codes and dark sky criteria, while providing ample illumination to create beautiful and inviting outdoor spaces.

Learning Objective 1:
Create exterior lighting designs that provide the recommended levels of illumination for highlighting facades, supporting wayfinding, and accenting features of the outdoor space, while satisfying code-mandated energy use and controls requirements as well as dark sky criteria.

Operable glass walls can provide for flexible interior spaces, safer interior environments, rapid and highly accessible connections to exterior spaces and all the benefits that ensue, such as fresh air, light, unobstructed views and rapid egress in the event of emergency. This course examines how operable glass walls meet those challenges and then shows the application of those principals in several case studies.

Solar shading devices, while available in numerous weaves, textures, and colors, go beyond contributing to the aesthetics of a space. Specified correctly, solar shading devices can maximize daylighting benefits and contribute to occupant well-being, productivity, and engagement, while mitigating the detrimental effects of UV rays and glare.

Learning Objective 1:
Students will understand the benefits daylighting, including the psychological and physiological well-being of occupants, as well as its drawbacks, such as glare and solar heat gain

Learning Objective 2:
Students will become familiar with the types of solar shading fabrics available for use in commercial settings and their components, including operating systems, weave, color, and openness factor, and the ways in which these contribute to the control of daylighting.

Learning Objective 3:
Students will explore the benefits of solar shading devices that extend beyond light management, such as sound mitigation, sustainability, and antimicrobial properties.

Learning Objective 4:
Students will determine how to select the right fabric for an application, taking into account aesthetics and room conditions

This course aims to help educate the designer about what performance fabrics are, the content of various fabrics, how they work, and the benefits to a sustainable design in meeting and maximizing your goals of occupant health, safety, well-being, and sustainability. Windows, views, and openings in buildings present the classic battle between form and function. The designer naturally wants the building’s occupants to enjoy views and light, but the solar heat gain from these openings can wreak havoc on sustainable goals. Sophisticated and high-performing solar control fabrics can help reconcile the form and function of light, views, and sustainability.

HSW Justification:
Substantially all of this course is dedicated to a discussion of the health, safety and welfare aspects of performance fabrics through their appropriate specification, their fabrics' chemical composition, their proper use, their ability to meet safety and performance standards, and their aesthetic contribution.

Learning Objective 1:
The student will learn how to analyze shading fabrics for solar light management including energy reduction, glare and outward visibility, using published shading coefficient data.

Learning Objective 2:
The student will be able to list certification requirements for indoor air quality, anti-bacterial protection, flame retardancy, and environmental regulations.

Learning Objective 3:
The student will be able to identify fabric composition options with an emphasis on sustainable design.

Learning Objective 4:
The student will be able to apply their knowledge of performance fabric features to unique, real-world applications in healthcare, hospitality, government, business, and residential projects.

NFPA 70, the national electrical code details 2 different types of Emergency Lighting Control Devices—devices that guarantee that life safety lighting will be on at desired illumination levels in the event of an emergency. This course will help mitigate the confusion regarding the specification of these devices and understand their applications in the real world.

Prerequisite Knowledge: Knowledge of life safety systems, particularly a high-level understanding of the purpose of emergency lighting inverters and generators. In particular, ISO-1001/ISO-1002 would be a perfect lead into this course.

HSW Justification: This deals with life safety, the safe egress, and illumination of buildings in the event of an emergency.

Learning Objective 1:
Understand the background technology where ALCR and BCELTS devices need to be deployed.

Learning Objective 2:
Learn the difference between the technologies and reviews how they sit within one-line diagrams.

Learning Objective 3:
Understand some of the real world tradeoffs between the device types as it relates to wiring, proximity and ease of testing.

Learning Objective 4:
Understand the integration of lighting controls with the different types of ELCDs and review some tricks for how to reduce costs in systems.

This course will describe the benefits of moveable glass walls in education environments from K-12 through higher education. It includes a comprehensive look at design options, framing and installation options, interior and exterior connecting applications, acoustical attenuation, daylighting, and 21st Century Educational design.

HSW Justification:
Privacy, daylighting, on-demand teaching flexibility, improved teaching outcomes and student and teacher health benefits are the primary focus of this course.

Learning Objective 1:
Identify and recognize the significance of flexible space in school design to safely accommodate variable educational needs

Learning Objective 2:
Assess the health and welfare aspects of glass wall systems in terms of providing daylight and views to students, teachers and staff.

Learning Objective 3:
Explain the importance of acoustics and the impact on student performance, and creating a better indoor environment.

Learning Objective 4:
Determine ways to incorporate the design principles presented into building project documentation as shown in project examples.

This course will cover the aesthetic, design, health, safety and welfare aspects of, and certifications achieved by wallcoverings laminated with DuPont™ Tedlar® polyvinyl fluoride film. Because Dupont™ is the only source for Tedlar® film there is no comparable competitive product in the market place. Therefore, we will be referring to the product from time to time by using its registered trademark brand name, Tedlar®.

HSW Justification:
Tedlar PVF film is applied to wallcovering to prevent off-gassing of building materials behind the wall. The film also is repeatedly and frequently cleanable without damage or deterioration. It does not support the growth o=f microorganisms, mold or mildew and is therefore excennent in restaurant and hospital settings. Additionally, the film is impossible to permanently stain. Stains wipe off with ease. Learning objectives cite additional HSW benefits.

Learning Objective 1:
The architect will recognize the aesthetic and design advantages of using PVF film on wallcoverings and architectural surfaces.

Learning Objective 2:
The architect will understand the health and safety advantages of using PVF film wallcoverings in occupied spaces.

Learning Objective 3:
The architect will be able to identify appropriate interior and exterior applications for wallcoverings protected by PVF film.

Learning Objective 4:
And, the architect will understand the ratings and certifications achieved by Tedlar® laminated wallcoverings.

Because Dupont™ is the only source for Tedlar® film there is no comparable competitive product in the market place. Therefore, we will be referring to the product from time to time by using its registered trademark brand name, Tedlar®.

Owing to the unique nature of this product, an architectural specification describing the PVF film known as Tedlar®. You will need to download this document to begin the course. At least one of the concluding quiz questions is based on this supplemental material.

This course will cover introductory level descriptions of various sectional door styles and how they impact energy efficiency, maximize ambient light, add to design aesthetics, and protect the health and safety of building occupants. Additionally, applicable varieties of industrial doors will also be included.

The building envelope separates the conditioned interior space from the environmental elements of the great outdoors, and this course explores a few solutions to equip the building envelope to defend the interior from nature's onslaughts, manage moisture, improve thermal performance, and admit daylight without glare.

HSW Justification:
Improper use of vapor barriers is one of the leading causes of moisture-related issues in buildings today. Those moisture related issues can include the growth of mold and mildew, which compromises the quality of the indoor environment and can even cause structural damage. Designing a proper air barrier system is crucial to moisture protection and protecting the thermal performance of the original design. This article provides best practices for designing an air barrier system that will function properly. We also discuss some solutions that can improve the functionality of the building envelope’s thermal performance. The course explores a translucent and an opaque solution that improve the thermal performance of the envelope, while offering additional benefits. Translucent wall panels allow diffuse, glare-free daylight into an interior, without compromising thermal efficiency at the opening and precast structural panels offer code-exceeding thermal performance and structural load-bearing capabilities.

Learning Objective 1:
Students will be able to explain why controlling air leakage in the building envelope is crucial to safeguarding the quality of the interior environment and protecting the energy efficiency of the building.

Learning Objective 2:
Students will learn to apply best practices to design an air barrier system that will effectively manage moisture intrusion and avoid moisture-related issues in the building envelope.

Learning Objective 3:
Students will be able to describe how translucent daylight panels allow daylight into the interior, mitigate glare and provide better thermal performance than many other glazing solutions.

Learning Objective 4:
Students will learn to use structural precast concrete panels to reduce the amount of perimeter steel needed on a project, while achieving and exceeding code-compliant thermal performance.