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Electric Vehicle Power Transfer

August 22, 2024

mike@standardsmichigan.com

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2023 National Electrical Code | Current Issues and Recent Research

2026 National Electrical Code Workspace

~~August 5, 2021~~

The 2020 National Electrical Code (NEC) contains significant revisions to Article 625 Electric Vehicle Power Transfer Systems. Free access to this information is linked below:

2023 National Electrical Code

2020 National Electrical Code

You will need to set up a (free) account to view Article 625 or you may join our colloquium today.

Public input for the 2023 Edition of the NEC has already been received. The work of the assigned committee — Code Making Panel 12 — is linked below:

NFPA 70_A2022_NEC_P12_FD_PIReport_rev

Mighty spirited debate. Wireless charging from in-ground facilities employing magnetic resonance are noteworthy.

Technical committees meet November – January to respond. In the intervening time it is helpful break down the ideas that were in play last cycle. The links below provide the access point:

Public Input Report Panel 12

Public Comment Report Panel 12

Panel 12 Final Ballot

We find a fair amount of administrative and harmonization action; fairly common in any revision cycle. We have taken an interest in a few specific concepts that track in academic research construction industry literature:

Correlation with Underwriters Laboratory product standards
Bi-Directional Charging & Demand Response
Connection to interactive power sources

As a wiring safety installation code — with a large installer and inspection constituency — the NEC is usually the starting point for designing the power chain to electric vehicles. There is close coupling between the NEC and product conformance organizations identified by NIST as Nationally Recognized Testing Laboratories; the subject of a separate post.

Edison electric vehicle | National Park Service, US Department of the Interior

~~After the First Draft is released June 28th public comment is receivable until August 19th.~~

We typically do not duplicate the work of the 10’s of thousands of National Electrical Code instructors who will be fanning out across the nation to host training sessions for electrical professionals whose license requires mandatory continuing education. That space has been a crowded space for decades. Instead we co-host “transcript reading” sessions with the IEEE Education & Healthcare Facilities Committee to sort through specifics of the 2020 NEC and to develop some of the ideas that ran through 2020 proposals but did not make it to final ballot and which we are likely to see on the docket of the 2023 NEC revision. That committee meets online 4 times monthly. We also include Article 625 on the standing agenda of our Mobility colloquium; open to everyone. See our CALENDAR for the next online meeting

Issue: [16-102]

Category: Electrical, Transportation & Parking, Energy

Colleagues: Mike Anthony, Jim Harvey

Workspace / NFPA

More

U.S. NATIONAL ELECTRIC VEHICLE SAFETY STANDARDS SUMMIT | DETROIT, MICHIGAN 2010

Gallery: Electric Vehicle Fire Risk

Electric Vehicle Charging

August 22, 2024

mike@standardsmichigan.com

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GROUP A MODEL BUILDING CODES: Comments on Committee Actions will be received until July 8th

Edison electric vehicle | National Park Service, US Department of the Interior

Free public access to the 2021 edition of the International Energy Conservation Code (IECC) is linked below:

2021 International Energy Conservation Code

This title will be updated within a reconfigured code development cycle linked below:

2024/2025/2026 ICC CODE DEVELOPMENT SCHEDULE

Keep in mind that many electric vehicle safety and sustainability concepts will track in other titles in the ICC catalog. It is enlightening to see other energy related proposals tracking in the most recent Group A code revision cycle

The following proposals discussed during the Group A Hearings ended earlier this month are noteworthy:

IBC § 202 (NEW) | G66-21 | Electrical mobility definitions

IBC § 1107.2, et al | E124-21 & E125-21 & E126-21 | Electrical vehicle charging stations for R-2 occupancies.

From the Group B revision cycle — COMPLETE MONOGRAPH:

R309.6 Electric vehicle charging stations and systems. Where provided, electric vehicle charging systems shall be installed in accordance with NFPA 70. Electric vehicle charging system equipment shall be listed and labeled in accordance with UL 2202. Electric vehicle supply equipment shall be listed and labeled in accordance with UL 2594.

IBC 406.2.7 Electric vehicle charging stations and systems. Where provided, electric vehicle charging systems shall be installed in accordance with NFPA 70. Electric vehicle charging system equipment shall be listed and labeled in accordance with UL 2202. Electric vehicle supply equipment shall be listed and labeled in accordance with UL 2594. Accessibility to electric vehicle charging stations shall be provided in accordance with Section 1108.

TABLE R328.5 MAXIMUM AGGREGATE RATINGS OF ESS (Energy Storage Systems) – PDF Page 1476

Incumbents are socking in EV concepts all across the ICC catalog. We refer them to experts in the Industrial Applications Society IEEE E&H Committee.

One of the more spirited debates in recent revision cycles is the following:

Who shall pay for electrical vehicle charging infrastructure?

The underlying assumption is that the electrification of the global transportation grid has a net benefit. We remain mute on that question; the question of net gain.

Of course, many proposals pointed the finger at the stakeholder with the deepest pockets. Accordingly, new commercial building owners will be required to install charging stations for new buildings. During 2018 and 2019 we tracked the action in the workspace below so that we could collaborate with the IEEE Education & Healthcare Facilities Committee:

2021 Electric Vehicle Infrastructure

Given that most higher education facilities are classified as commercial, the cost of charging stations will be conveyed into the new building construction budget unless the unit takes an exception. Generally speaking, most colleges and universities like to display their electric vehicle credentials, even if the use of such charging stations remains sparse.

Cornell University

Issue: [11-40]

Category: Electrical, #SmartCampus

Colleagues: Mike Anthony, Jim Harvey

* The education industry has significant square footage this is classified as residential; particularly on the periphery of large research campuses.

LEARN MORE:

ICC 2021/2022 Code Development Cycle

The Top 5 Energy Efficiency Proposals for the 2021 IECC

Archive / IECC Electric Vehicle Charging

What Is A Standard Drink?

August 21, 2024

mike@standardsmichigan.com

D6, D6/2, Friday, Holiday, Holiday Week, Saturday

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“Rather a bottle in front of me than a frontal lobotomy”

— Some guy

Many people are surprised to learn what counts as a “drink”. The amount of liquid in your glass, can, or bottle does not necessarily match up to how much alcohol is actually in your drink. Even before the United States federal government withdrew from regulating alcohol, the conversation, and degree of agreement and attitude, remains remarkably regionally specific:

Missouri University of Science & Technology: What is a Standard Drink?

University of South Alabama: What is a Standard Drink?

Stanford University Office of Alcohol Policy and Education

Other nations serve alcohol to students on campus in university owned facilities.

Maynooth University Student Union County Kildare

I didn’t know that🤔 pic.twitter.com/rMT3X2fCN0

— Alix (@AlixG_2) August 17, 2024

College students create the ultimate hangover cure

❤️ pic.twitter.com/pmQp9jUuCF

— Dr. Maya C. Popa (@MayaCPopa) May 26, 2023

Infotech 100

August 21, 2024

mike@standardsmichigan.com

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Touring the Coffee Shops of Nottingham

August 21, 2024

mike@standardsmichigan.com

England

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The “Golden Cup” Standard

England | East Midlands

“O brave new world, that has such people in’t!” | The Tempest, William Shakespeare, Act 5, Scene 1

LIVE: Radio Machias 91.1

August 21, 2024

mike@standardsmichigan.com

D5, D6/3, Maine

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CLICK IMAGE TO START LIVESTREAM

LIVESTREAM

WUMM Radio

Energy 400

August 21, 2024

mike@standardsmichigan.com

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Climate Psychosis | Other Ways of Knowing Climate Change

“The Conquest of Energy” / José Chávez Morado / Universidad Nacional Autónoma de México

We began last year breaking down our coverage of education settlement energy codes and standards into the tranches listed below:

Energy 200: Codes and standards for building premise energy systems. (Electrical, heating and cooling of the building envelope)

Energy 300: Codes and standards that support the energy systems required for information and communication technology

21 March 2024

Energy 400: Codes and standards for energy systems between campus buildings. (District energy systems including interdependence with electrical and water supply)

ASHRAE Proposal for a District Cooling Standard

A different “flavor of money” runs through each of these domains and this condition is reflected in best practice discovery and promulgation. Energy 200 is less informed by tax-free (bonded) money than Energy 400 titles.

Some titles cover safety and sustainability in both interior and exterior energy domains so we simply list them below:

~~ASME A13.1 – 20XX, Scheme for the Identification of Piping Systems | Consultation closes 6/20/2023~~

ASME Boiler Pressure Vessel Code

ASME BPVC Codes & Standards Errata and Notices

ASHRAE International 90.1 — Energy Standard for Buildings Except Low-Rise Residential Buildings

Data Center Operations & Maintenance

2018 International Green Construction Code^®Powered by Standard 189.1-2017

NFPA 90 Building Energy Code

NFPA 855 Standard for the Installation of Stationary Energy Storage Systems

IEEE Electrical energy technical literature

ASTM Energy & Utilities Overview

Underwriters Laboratories Energy and Utilities

There are other ad hoc and open-source consortia that occupy at least a niche in this domain. All of the fifty United States and the Washington DC-based US Federal Government throw off public consultations routinely and, of course, a great deal of faculty interest lies in research funding.

Please join our daily colloquia using the login credentials at the upper right of our home page.

References: Energy 400

ICYMI – here is our 50th anniversary lecture from Professor Helen Thompson on the 1970s energy crises and what we can learn from it, with some great questions from our audience! https://t.co/9XUqc3fx5f pic.twitter.com/zHvqY8HYL1

— Clare College (@ClareCollege) March 9, 2023

More

United States Department of Energy

International Energy Agency World Energy Outlook 2022

International Standardization Organization

ISO/TC 192 Gas Turbines

Energy and heat transfer engineering in general

Economics of Energy, Volume: 4.9 Article: 48 , James L. Sweeney, Stanford University

Global Warming: Scam, Fraud, or Hoax?, Douglas Allchin, The American Biology Teacher (2015) 77 (4): 309–313.

Helmholtz and the Conservation of Energy, By Kenneth L. Caneva, MIT Press

International District Energy Association Campus Energy 2023 Conference: February 29-March 2 (Grapevine Texas)

NRG Provides Strategic Update and Announces New Capital Allocation Framework at 2023 Investor Day

Evaluation of European District Heating Systems for Application to Army Installations in the United States

Gallery: Other Ways of Knowing Climate Change

Allston District Energy

Campus Bulk Electrical Distribution

Interdependent Water & Electricity Networks

Interoperability of Inverter-Based Resources

Gallery: Campus Steam Tunnels

Electrical Resource Adequacy

From our video archive:

Ask me why pic.twitter.com/zQIpuI7vCh

— Grace Stanke (@Grace_Stanke) August 23, 2023

Boiler & Pressure Vessel Code

August 21, 2024

mike@standardsmichigan.com

D4

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“Mechanic and Steam Pump” | Lewis W. Hine (1921)

The heating and cooling requirements of K-12 schools, college and university educational, medical research and healthcare delivery campuses are a large market for boiler pressure vessel manufacturers, installers, maintenance personnel and inspectors. The demand for building new, and upgrading existing boilers — either single building boilers, regional boilers or central district energy boilers — presents a large market for professional engineering firms also. A large research university, for example, will have dozens, if not well over 100 boilers that heat and cool square footage in all climates throughout the year. The same boilers provide heating and cooling for data centers, laundry operations, kitchen steam tables in hospitals and dormitories.

The safety rules for these large, complex and frankly, fearsome systems, have been developed by many generations of mechanical engineering professionals in the American Society of Mechanical Engineers (ASME) Boiler and Pressure Vessel Code (BPVC). From the BPVC scope statement:

“…The International Boiler and Pressure Vessel Code establishes rules of safety — relating only to pressure integrity — governing the design, fabrication, and inspection of boilers and pressure vessels, and nuclear power plant components during construction. The objective of the rules is to provide a margin for deterioration in service. Advancements in design and material and the evidence of experience are constantly being added…”

Many state and local governments incorporate the BPVC by reference into public safety regulations and have established boiler safety agencies. Boiler explosions are fairly common, as a simple internet search on the term “school boiler explosion” will reveal. We linked one such incident at the bottom of this page.

University of Michigan Central Heating Plant

The 2023 Edition of the BPVC is the current edition; though the document is divided into many sections that change quickly.

ASME Codes & Standards Electronic Tools

ASME Proposals Available For Public Review

ASME Section IV: Rules for the Construction of Heating Boilers (2019)

Public consultation on changes to the standard for controls and safety devices for automatically fired boilers closes September 25th.

This is a fairly stable domain at the moment. We direct you elsewhere to emergent topics:

Ghost kitchens gaining steam on college campuses

College: the Next Big Frontier for Ghost Kitchens

Illinois Admin. Code tit. 77, § 890.1220 – Hot Water Supply and Distribution

Design Considerations for Hot Water Plumbing

FREE ACCESS: 2019 ASME Boiler and Pressure Code (Section VI)

Plumbing

Two characteristics of the ASME standards development process are noteworthy:

Only the proposed changes to the BPVC are published. The context surrounding a given change may be lost or not seen unless access to previous version is available. Knowledgeable experts who contribute to the development of the BPVC usually have a previous version, however. Newcomers to the process may not.
The BPVC has several breakout committees; owing to its longer history in the US standards system and the gathering pace of complexity in this technology.

We unpack the ASME bibliography primarily during our Mechanical, Plumbing and Energy colloquia; and also during our coverage of large central laundry and food preparation (Kitchens 100) colloquia. See our CALENDAR for the next online meeting, open to everyone.

Issue: [12-33] [15-4] [15-161] [16-77] [18-4] [19-157]

Category: District Energy, Energy, Mechanical, Kitchens, Hot Water

Contact: Eric Albert, Richard Robben, Larry Spielvogel

More:

Standards Michigan BPVC Archive

ASME BPVC Resources

Big Ten & Friends Energy Conference 2023

Standards Michigan Workspace (Requires access credentials from bella@standardsmichigan.com).

School Boiler Maintenance Programs: How Safe Are The Children?

Boiler Explodes at Indiana High School

Engineers at @virginia_tech are boosting heat transfer by prompting bubbles to jump from a heated plate during boiling, potentially increasing power plant efficiency with microstructures: https://t.co/W1gLvhn15q pic.twitter.com/45PNRAEmpB

— ASME.org (@ASMEdotorg) January 30, 2024

Hayward Street Geothermal Cooling $20M

August 21, 2024

mike@standardsmichigan.com

michc, Michigan

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ACTION REQUEST: $20M

Leinweber Computer and Information Science

Leinweber Foundation Gift

Business & Finance: We Make Blue Go

Geothermal cooling plants have far fewer moving parts and thus pay for themselves by combining immediate energy savings, revenue from excess energy or services, government incentives, and long-term operational efficiency. “Classical” payback period depends on factors like the plant’s scale and available incentives through DTE Energy.

1. Energy Cost Savings

Reduced Operating Costs: Geothermal systems use the relatively constant temperature of the earth to provide heating and cooling, which can be much more energy-efficient than traditional HVAC systems. This efficiency leads to lower utility bills for the facility, resulting in significant cost savings over time.
Lower Maintenance Costs: Geothermal systems generally have fewer moving parts than conventional systems, leading to lower maintenance and repair costs.

2. Revenue Generation

Selling Excess Energy: In some cases, geothermal plants can produce more energy than needed for cooling. This excess energy can be sold back to the grid or used for other purposes, providing an additional revenue stream.
Leasing and Service Agreements: Some facilities enter into agreements with nearby buildings or industries to provide geothermal cooling services, generating income.

3. Government Incentives and Subsidies

Tax Credits and Rebates: Many governments offer financial incentives, such as tax credits, grants, and rebates, for the installation and operation of geothermal systems. These incentives can significantly reduce the upfront costs and improve the payback period.
Renewable Energy Certificates(RECs): In some regions, geothermal plants can earn RECs for generating renewable energy. These certificates can be sold to other companies to offset their carbon emissions, generating additional income.

4. Environmental and Social Benefits

Carbon Credits: By reducing greenhouse gas emissions compared to traditional systems, geothermal plants can earn carbon credits, which can be sold or traded in carbon markets.
Sustainability Branding: Businesses that use geothermal cooling can market themselves as environmentally friendly, potentially attracting more customers or tenants, which indirectly supports the plant’s financial viability.

5. Long-Term Investment

Long Lifespan: Geothermal systems typically have a long lifespan (20-50 years), allowing for a long-term return on investment. While the initial capital costs are high, the system’s durability and low operating costs contribute to a favorable payback over time.
Resilience Against Energy Price Volatility: Geothermal systems provide protection against fluctuating energy prices, offering stable and predictable costs, which is financially beneficial over the long term.

6. Financing Models

Power Purchase Agreements (PPAs): Some geothermal plants are financed through PPAs, where a third party finances the installation and the facility pays for the energy produced, typically at a lower rate than conventional energy sources.
Energy Service Companies (ESCOs): These companies can finance, install, and maintain geothermal systems, with the facility paying for the service over time, usually based on the energy savings achieved.

7. Scalability and Integration

Integration with Other Renewable Systems: Geothermal cooling can be part of a broader renewable energy strategy, integrating with solar or wind power to further enhance efficiency and reduce costs, improving the overall financial outlook.

Earth Energy Systems

Earth Energy Systems

August 21, 2024

mike@standardsmichigan.com

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Geothermal systems cool buildings by leveraging the stable temperatures found beneath the Earth’s surface. A geothermal heat pump system consists of a ground loop, heat exchanger, and distribution system.

In cooling mode, the system extracts heat from the building and transfers it to the ground. The ground loop, typically composed of pipes buried horizontally or vertically, circulates a fluid that absorbs heat from the building’s interior. The fluid, warmed by this process, is then pumped through the ground loop where the Earth’s cooler temperatures absorb the heat, effectively dissipating it into the ground.

The cooled fluid returns to the heat pump, which distributes the now-cooler air throughout the building via the distribution system, such as ductwork. This process is highly efficient because the ground maintains a relatively constant temperature year-round, allowing the geothermal system to operate with less energy compared to traditional air-source cooling methods.

At the moment, though the technology has been made practical since Prince Piero Ginori Conti’s discovery in 1904, and has since tracked well in local building codes and environmental regulations, the bibliography for earth energy systems is nascent and relatively thin. One trade association is emerging from the gathering pace of applications and case studies: Closed-Loop/Geothermal Heat Pump Systems Design and Installation Standards

We maintain the IGSHPA catalog on the standing agenda of our Energy, Mechanical and Air Conditioning colloquia. See our CALENDAR for the next online meeting; open to everyone.

Partial Bibliography:

Handbook of Best Practices for Geothermal Drilling

Best Practices for Designing Geothermal Systems

Geothermal Direct Use Engineering and Design Guidebook

International Standards

ISO 13612-1:2014 – Heating and cooling systems in buildings — Method for calculation of the system performance and system design for heat pump systems — Part 1: Design and dimensioning.

- This standard covers the design and performance calculation of geothermal heat pump systems.

ISO 14823:2017 – Intelligent transport systems — Graphic data dictionary.

- While not specific to geothermal, this standard includes data relevant to various systems, including geothermal energy systems.

ISO 52000-1:2017 – Energy performance of buildings — Overarching EPB assessment — Part 1: General framework and procedures.

- This standard provides a general framework for assessing the energy performance of buildings, which includes geothermal systems.

IEC 61753-111-7:2014 – Fibre optic interconnecting devices and passive components – Performance standard – Part 111-7: Sealed closures for category S – Subterranean environments.

- Relevant for the installation of geothermal systems that include fiber optic components in subterranean environments.

North American Standards

CSA C448: Design and installation of earth energy systems.

ANSI/CSA C448 Series-16 – Design and Installation of Earth Energy Systems.

- This standard covers the design and installation of geothermal heat pump systems in the United States, providing guidelines on installation practices, materials, and system performance.

ASHRAE Standard 90.1 – Energy Standard for Buildings Except Low-Rise Residential Buildings.

- This standard sets the minimum energy efficiency requirements for the design and construction of buildings, including the installation of geothermal systems.

IGSHPA Standards – International Ground Source Heat Pump Association (IGSHPA) Standards.

- The IGSHPA develops standards for the design and installation of geothermal heat pump systems, with a focus on closed-loop systems.

NFPA 54 – National Fuel Gas Code.

- Although primarily focused on fuel gas systems, this standard may intersect with geothermal systems when they involve hybrid solutions that include gas heating.

EPA Standards for Geothermal Energy (40 CFR Part 144) – Underground Injection Control (UIC) Program.

- This standard regulates the injection of fluids into underground wells, relevant for geothermal systems that involve deep wells for heat exchange.

UL 1995 – Heating and Cooling Equipment.

- This standard applies to the safety of heating and cooling equipment, including geothermal heat pumps.

“Neptune’s Horses” 1919 | Walter Crane

Electric Vehicle Power Transfer

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