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.

Neuroarchitecture is a design discipline that seeks to incorporate neuroscience into design to augment the built environment’s positive influence on the emotional and physical health of people.

This course explores the impact of the COVID-19 pandemic on design and construction decisions, particularly focusing on operable glass walls in interior and exterior applications, primarily in the hospitality industry. Students will gain familiarity with terminology, capabilities, and uses of operable glass walls, with an emphasis on addressing health concerns post-pandemic through responsive design. The course highlights how operable glass walls contribute to improving the health, safety, and well-being of building occupants while also providing psychological benefits by creating comfortable environments. Practical design concepts applicable to various commercial projects will be covered, with direct access to manufacturer resources for further assistance.

Learning Objective 1:
You will be able to identify and recognize the significance of the health concerns related to the COVID-19 pandemic as they relate to building design and product selection.

Learning Objective 2:
You will learn how to assess the safety aspects of incorporating design and product selections that protect buildings, occupants, and owners from harm and damage, particularly in light of unexpected violence and vandalism.

Learning Objective 3:
You will be able to explain the welfare aspects of design and product selection that enable equitable access to all, can elevate the human experience with daylight and outdoor access, and benefit the environment through sustainable building design.

Learning Objective 4:
You will be able to determine ways to incorporate the design principles as presented into different building types and applications.

Modern open spaces create a unique set of challenges when it comes to acoustics, particularly because many new buildings are designed with open plans and open plenums. Fortunately, there are innovative acoustic systems on the market that are designed to integrate with open plenums that can help to overcome these challenges. This course will discuss customizable acoustical solutions for open plenum design, including baffles, beams, clouds, and acoustical wall panels, which are available in a variety of materials like metal, wood, fiberglass, and felt. The course will explore the importance of acoustical design and how these open plenum ceiling systems can transform a space aesthetically while maximizing acoustics.

Program: Landscape Environmental Design

This course will describe the replica Green Wall Trend, that is the use of biomimicry in artificial plants in interior and exterior green wall systems. The trend toward biomimicry is driven by low cost, low maintenance, very high quality plant substitutes, and no water, light, power or HVAC resource requirements. Yet, Replica installations provide the same aesthetic and evoke the same desirable biophilic responses as live plants.

HSW Justification:
Replica Green Walls have all the biophilic benefits of green walls, such as promoting healing, reducing anxiety, and attenuating noise. Replica green wall spaces are especially conducive to gathering and can foster community, encourage group meeting and communication, and promote human interaction. In addition, they have added sustainability benefits by eliminating regular maintenance, the need for water for irrigation, or the need for electrical energy for light, or the need for electrical and/or natural gas for heating or cooling.

Learning Objective 1:
Students will be able to define a Replica Green Wall and describe its benefits and advantages

Learning Objective 2:
Students will be able to identify and describe the quality indicators in a green wall, including the types of systems available, the types of foliage available, and the areas of research and development underway.

Learning Objective 3:
Students will be able to describe appropriate applications for a replica green wall.

Learning Objective 4:
Students will be able to list in detail the various methods of installation.

Note: The Continuing Architect is permitting the brand name of this product to be mentioned because it was the only product of its type and is patent pending.

This course is designed to teach the history of synthetic turf, its application in water and energy conservation, pollution abatement, sustainable design, and its versatility in numerous landscaping applications and designs. Participants will become knowledgeable about synthetic turf and innovative applications that could be applied to their residential and commercial projects. The most current technological advances in the industry and the positive role synthetic turf plays in the environment.

Learning Objective 1:
Students will gain an increased awareness of the positive environmental impact of synthetic turf on water use, reduced energy demand and reduction of use of fossil fuels, reduced chemical application, and resulting reduction of water and noise pollution.

Learning Objective 2:
Students will become more informed on the newest synthetic turf material technologies available, including the use of soy based materials, as well as how the proper application of infills and proper material selection can benefit the health and safety of athletes.

Learning Objective 3:
Students will be more knowledgeable about the history and evolution of the technology and of landscaping and sports applications using synthetic turf.

Learning Objective 4:
Students will better understand the versatility of synthetic turf and its many uses in sustainable landscape design.

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.

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.

This course is designed to introduce the architect to egress marking systems that are used for ordinary way finding and building evacuation in emergency situations. These signage systems are meant to be selected and installed according to specific standards established by building codes. Additionally, once installed, these systems must be tested to assure their efficacy in case of an emergency. How to select and specify the appropriate markers and the technological solutions available, as well as testing methods, will all be covered in this course.

HSW Justification:
Building exit markings are critical to the health, safety, and welfare of building occupants during emergency situations.

Learning Objective 1:
When this course is complete the student will will understand egress signage obligations as imposed through building codes and standards.

Learning Objective 2:
The student will further understand the various technologies available to address those signage codes and standards.

Learning Objective 3:
And, the student will learn what the requirements are to conduct on-going testing of egress systems after installation.

The building envelope has a lot of different jobs to do—from insulating the building so that it can be efficiently heated and cooled to providing air and water barriers that keep harmful moisture at bay, as well as providing the aesthetic face of the project. High performance building envelopes do all of those things extremely well. This article explores some of the latest high-performance solutions that can be used to create those high-performance envelopes.

HSW Justification:
A high-performance building envelope is necessary to create a building that is efficient and healthy. This article takes a look at how different components in the building envelope perform—giving architects the information they need to choose high-performance components that will produce a high-performing envelope.

Learning Objective 1:
Compare different types of continuous insulation in terms of the thermal performance they offer and the way they behave when exposed to water and fire.

Learning Objective 2:
Describe how insulated metal panels (IMPs) can be used on the envelope to improve building performance, create efficient and healthy interiors, and enhance design flexibility.

Learning Objective 3:
Explain how PET bottles can be upcycled into insulation creating a new product that contains recycled material and improves thermal performance of the building envelope.

Learning Objective 4:
Describe the ways that architectural metal wall systems enable architects to push the creative boundaries of their designs.