Beauty, functionality, and wellness-enhancing can co-exist in design, with the right products. This article explores solutions that help architects achieve these important multi-benefits. Pavers that create beautiful outdoor spaces that are easy to maintain. Skylights that allow daylight and fresh air into the interior. Underlayment that improves acoustics and sound management, while protecting the integrity of the interior air quality. Each improves the functionality of the space and the wellness of the people in the built environment.

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.

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.

As architects and clients alike demand the creation of what’s next, design teams rely on new product systems and solutions to help them push the boundaries of form and function. This article profiles a few solutions that enable architects to create distinct building envelopes that don’t sacrifice on the efficient performance or sustainable design considerations that also occupy prominent spots on almost every client’s wish list.

HSW Justification:
This article explores solutions that enable architects to deliver a desired aesthetic that also performs efficiently and offers sustainable design benefits. For example, thermal barriers in the aluminum framing that hold the glazing in place allows architects to complete historic renovation projects that exceed thermal performance targets, without compromising the integrity of the historical aesthetic. Composite metal panel systems that support very unique applications and creative demands from design teams can also offer top-tier performance in terms of fire-, water-, and impact-resistance. Extruded aluminum trim beautifully meshes different types of exterior cladding, while helping the envelope to better manage moisture.

Learning Objective 1:
Explain how incorporating thermal barriers into the aluminum framing in the fenestration of the Crosstown Concourse helped the project become the world’s largest LEED Platinum historic rehabilitation project, while maintaining the integrity of its historic aesthetic.

Learning Objective 2:
Specify a composite metal panel system that offers the resistance to fire, water, and impact best-suited to the needs of a particular project.

Learning Objective 3:
List the aesthetic and sustainability-related benefits of specifying extruded aluminum trim on an exterior cladding.

Learning Objective 4:
Describe how the different finishes of precast concrete used in the façade of the Ale Asylum were reverse engineered to perfectly match the concept originally pitched and accepted by the city.

Dynamic lighting, also known as tunable, color-changing, and circadian lighting, is being adopted and employed in current lighting designs.  There are many studies showing the benefits of dynamic lighting in built environments.  Early adopters have seeded the market and several lighting manufacturers now employ some level of Dynamic Lighting. This course is intended to explore what  Dynamic Lighting is, how it works in commercial luminaires, how to control it, and where the lighting community is being directed by standards, regulation, and voice of the customer. 

At the end of this course, participants will learn:

1. Define elements of dynamic lighting.
2. Learn the uses of dynamic lighting.
3. See illustrations of how to control dynamic lighting.
4. Become aware of the regulations, standards, and customer requests that are driving adoption.

This course will equip participants to compare features, benefits and limitations of particleboard and medium density fiberboard (MDF) with considerations of product grades and their physical properties for proper end-use selection.

Learning Objective 1:
To help students understand the health benefits of composite products and how testing is an essential means to verify performance.

Learning Objective 2:
To explain to attendees the alternative resin technologies used in the manufacturing process.

Learning Objective 3:
To help students to become familiar with various composite panel products and their environmentally-friendly make-up.

Learning Objective 4:
To familiarize attendees with the variety of ways that composite panels contribute to LEED credits.

Permeable interlocking concrete pavers (PICP) have the ability to create solid, strong surfaces for pedestrians and a range of vehicular uses, and can help maintain a site’s existing natural hydrologic function. This course discusses the goals of a PICP system and the materials used. It compares PICP with other stormwater management systems and describes the proper installation of a permeable paver system.

HSW Justification:
Permeable paver systems help prevent flooding that can contribute to injury, accidents, and property damage. Additionally, permeable paver systems properly installed help maintain more purified groundwater by providing a filter medium and detention reservoirs, reducing turbidity and pollution from runoff.

Learning Objective 1:
Students will be able to identify benefits and opportunities for using permeable pavers.

Learning Objective 2:
Students will be able to analyze the goals and criteria for using a permeable paver system.

Learning Objective 3:
Students will be able to list permeable paver materials and understand how to design different solutions

Learning Objective 4:
Students will be able to evaluate and compare permeable pavers to other traditional stormwater solutions.

Learning Objective 5:
Students will understand different installation procedures for permeable pavers.

Program: Architecture, Design, and Building Science

The purpose of this presentation is to give you a clear understanding of the features and benefits of textured metals and discover how to best specify stainless steel and metal alloys in your projects. The first part of our talk will introduce the ecological and economic properties of textured stainless steel as well as educate you on the composition of metals and alloys. The second portion of this presentation will illustrate the process of texturing metals and their applications, as well as how to specify them. The session will also review projects that use textured metals - with beautiful results.

HSW Justification:
Most of this course is dedicated to explaining the aesthetic, ecological and economic advantages of textured metals. Most often, the metal used in stainless steel, which is very long-lived, valuable and 100 percent recyclable. The case studies focus on many beautiful installations that enhance the lives of occupants and visitors through the art and craftsmanship of the installations.

Learning Objective 1:
Students will understand ecological, economic, health and safety benefits of utilizing metals that can be deep textured.

Learning Objective 2:
Students will explore current applications that employ deep textured metals because of their ecological benefits, enhanced performance, and aesthetic attributes.

Learning Objective 3:
Students will learn compositions of metals that can be deep textured, how each performs under varying environmental constraints, and how to safely and economically specify deep textured metals.

Learning Objective 4:
Students will discover end user benefits of deep texturing metals, including performance enhancement, material usage reduction and longer product lifecycles.

Addressing student behaviors, improving the learning environment, and enhancing the sustainability of educational buildings with design.

Learning Objective 1:
After reading this article, you should be able to: describe how the inclusive restroom design concept addresses the bad behaviors plaguing bathroom spaces and improves student safety

Learning Objective 2:
After reading this article, you should be able to: summarize the ways that acoustical surfaces, lighting, and HVAC systems are being used to improve the comfort of the learning environment, helping students perform better in class.

Learning Objective 3:
After reading this article, you should be able to: identify various solutions that can be incorporated to heighten security throughout a school.

Learning Objective 4:
After reading this article, you should be able to: explain some of the sustainability strategies making schools more environmentally friendly.

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.