Montana Energy Efficiency 30 PDH Discount Package 2

This online engineering PDH course presents guidelines on how to reduce mechanical system water use in residential buildings. Mechanical systems are frequently utilized to provide heating and cooling for residential properties. They typically fall into two categories: centralized and decentralized systems.

Centralized mechanical systems provide heating and cooling from a central location, such as a mechanical room or utility penthouse. These systems are more common in mid- and high-rise multifamily properties and can include cooling towers, boilers, and steam systems, each of which uses water as the heat transfer medium. As a result, the use of water for building heating and cooling can be significant and using sound management practices is a good opportunity for water savings.

Decentralized mechanical systems treat each unit of a multifamily property as its own space, as if each unit were a stand-alone single-family residence. These systems do not typically use process water, so they are not the focus of this water efficiency management guide.

This online engineering PDH course provides basic information about small wind electric systems to help you decide if wind energy will work for you.

Wind is created by the unequal heating of the Earth's surface by the sun. Wind turbines convert the kinetic energy in wind into mechanical power that runs a generator to produce clean electricity.

Can I use wind energy to power my home? More people across the country are asking this question as they look for a hedge against increasing electricity rates and a way to harvest their local wind resources. Although wind turbines large enough to provide a significant portion of the electricity needed by the average U.S. home generally require 1 acre of property or more, approximately 19.3% of the U.S. population lives in rural areas and may own land parcels large enough to accommodate a wind energy system.

This 3 PDH online course is applicable to electrical and mechanical engineers and energy professionals who are interested in learning more about small wind electric systems.

This online engineering PDH course provides guidance in new motor purchase decisions, and helps in identifying the energy and cost savings for motors that should be replaced with premium efficiency units.

The National Electrical Manufacturers Association (NEMA) adopted a NEMA Premium® efficiency motor standard in August of 2001. A motor can be marketed as a NEMA Premium motor if it meets or exceeds a set of minimum full-load efficiency levels.

These premium efficiency motor standards cover the 1 horsepower (hp) to 500 hp three-phase low-voltage NEMA Design A and B general, special, and definite purpose induction motors that are in widespread use in U.S. industrial facilities. The energy savings from replacing in-service standard and energy efficient motors with premium efficiency motor models can be substantial.

This online engineering PDH course offers a thorough introduction to hydrogen as a critical energy carrier for achieving a clean, sustainable energy future.

This course provides an overview of the science, technologies, and applications that enable hydrogen production, delivery, storage, and utilization in fuel cells. It introduces key concepts and examines both conventional and renewable production methods, including steam methane reforming, water electrolysis, and biological processes. Additionally, it explores advanced storage solutions such as compressed gas and metal hydrides, along with logistical considerations for hydrogen delivery using pipelines, tube trailers, and cryogenic transport.

Furthermore, this course delves into the operation and applications of fuel cells, focusing on Polymer Electrolyte Membrane (PEM) fuel cells commonly used in vehicles. It highlights the role of the Hydrogen and Fuel Cell Technologies Office (HFTO) and initiatives like H2@Scale, which aim to address various technological, economic, and institutional challenges.

This 8 PDH online course is applicable to energy engineers and other technical professionals interested in understanding the role of hydrogen in the transition to net-zero emissions.

This online engineering PDH course provides insight on how to estimate the positive environmental effects of green roof installations in cities. This is accomplished by providing a brief introduction to the basic concepts and definitions relating to urban environmental pollution, followed by a case study of the Kansas City metropolitan area.

A green roof—also called a vegetated roof or eco-roof—is a roof with soil and plants placed on top of a conventional roof. Green roofs are growing in popularity, as they have proven to be a cost-effective strategy for creating more livable and sustainable cities. Integrating nature-based solutions like green roofs into the urban landscape has several benefits to the environment, public health, and society.

This online engineering PDH course describes basic process heating applications and equipment, and outlines opportunities for energy and performance improvements. It also discusses the merits of using a systems approach in identifying and implementing these improvement opportunities for Fuel-Based and Electric-Based heating systems. Furthermore, it provides recommendations to financially justify process heating improvement projects (System Economics).

Process heating is essential in the manufacture of most consumer and industrial products, including those made out of metal, plastic, rubber, carbon fiber, concrete, glass, and ceramics. Process heating systems are broken into three basic categories: Fuel-Based Process Heating, Electric-Based Process Heating, and Steam-Based Process Heating all of which are discussed in details.

This 5 PDH online course is applicable to mechanical, industrial and process engineers, designers, manufacturers and all personnel involved in the planning, design and installation of process heating systems.

This online engineering PDH course introduces the different types of solid, liquid, and gaseous fuels commonly fired in industrial, commercial and institutional boilers. It describes the characteristics of fossil and non-fossil fuels with emphasis on coal, oil, natural gas, biomass, and refuse-derived fuels (RDFs). This course also presents the principle emissions from combustion boilers that are regulated under the Clean Air Act (CAA); mechanisms by which they are formed as well as the various control techniques for reducing them.

This 2 PDH online course is applicable to mechanical engineers, designers, contractors, building professionals, and manufacturers who are interested in gaining a better understanding of the various boiler fuels and their emissions.

This online engineering PDH course presents the technical, economic, and feasibility assessment for converting to all-electric heating solutions.

Electrification of building loads presents a significant opportunity to reduce site-level greenhouse gas (GHG) emissions, especially when combined with renewable and zero-carbon electricity resources. Electrification involves the conversion of a building system that would traditionally use fossil fuels (such as, natural gas, fuel oil, or propane) to the use of electrical power, which could be a key strategy in decarbonization. The course focuses on electrification and decarbonization of space heating and water heating loads using electric heat pump systems.

This 1 PDH online course is applicable to mechanical, energy, and facility engineers as well as other technical professionals interested in learning about electrification and decarbonization of space and water heating loads using electric heat pump systems.