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 provides fundamental information about Variable Refrigerant Flow (VRF) technology while overviewing three different application projects that feature the design flexibility, efficiency and owner benefits of specifying VRF systems.

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.

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.

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

Designing with Pre-Crimped Woven Wire Mesh is a streaming video course that explores interior and exterior applications and functions for woven metal mesh products in architectural design. The course examines key functions of these materials, details the manufacturing process, and outlines critical specification considerations to ensure beautiful and long lasting installations.

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. Additionally, applicable varieties of industrial doors will also be included.

HSW Justification: Understanding upward acting door and safety device specification and installation contribute to health, safety and welfare of building occupants, including infants, children and the elderly, by helping avoid entrapment, injury, or exposure to exhaust gasses. Additionally, proper installation helps assure comfort control, energy efficiency and better design aesthetics.

Learning Objective 1: Students will be able to recognize and differentiate various types of sectional and industrial doors, with a focus on selecting door types that enhance occupant safety, support energy efficiency, and improve building design aesthetics for a healthier environment.

Learning Objective 2: Students will learn to specify upward-acting doors, prioritizing occupant health and safety by understanding how door selection impacts injury prevention, exhaust gas exposure, and energy conservation, while also enhancing natural light and aesthetic integration.

Learning Objective 3: Students will gain skills in assessing mounting conditions, headroom and side room requirements, and types of lifts and operators, with particular attention to how these considerations affect safety, mechanical reliability, and occupant welfare.

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.

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.

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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.