ASCE Standards Catalog | Standards Open for Public Comment
The #InfrastructureReportCard doesn’t just tell us where we stand – it helps us get to where we need to be.
Read 5 key takeaways you should know about ASCE’s 2025 Report Card for America’s Infrastructure: https://t.co/LrnxBB5Jto. pic.twitter.com/rwrESHDLow
— ASCE Headquarters (@ASCETweets) March 27, 2025
Electrical storage system resides at the Massachusetts Institute of Technology’s Vail Access Project
Today at 15:00 UTC we refresh our understanding of stabilized technical standards for electrical energy storage systems (ESS) for industrial and commercial applications. Adhering to these standards ensures ESS reliability, protects personnel, and supports the growing adoption of energy storage in industrial and commercial settings.
Ω NFPA 855 – Standard for the Installation of Stationary Energy Storage Systems: This U.S.-based standard provides comprehensive guidelines for ESS installations, focusing on safety for lithium-ion, flow, and other battery technologies. It covers system siting, fire protection, ventilation, and thermal management. NFPA 855 mandates minimum clearances from buildings and exposures, requires fire detection and suppression systems (e.g., sprinklers or gas-based systems), and specifies exhaust systems to manage off-gassing risks. It also addresses commissioning, maintenance, and decommissioning to prevent hazards like thermal runaway.
Ω NEC (NFPA 70) – National Electrical Code, Article 706: Article 706 of the NEC governs ESS electrical design, emphasizing safe integration with power systems. It requires proper grounding, overcurrent protection, and disconnecting means for battery systems. The standard specifies wiring methods, labeling for hazard awareness, and compatibility with grid interconnection. For commercial and industrial ESS, it mandates compliance with voltage and capacity limits, ensuring systems are designed to handle high-power demands safely. 2026 CMP-16 Public Input Report | 2026 CMP-16 Second Draft Report
Ω UL 9540 – Standard for Energy Storage Systems and Equipment: UL 9540 certifies the safety of ESS, including battery packs, inverters, and control systems. It requires systems to undergo rigorous testing for electrical safety, fire resistance, and thermal runaway prevention. For large-scale commercial installations, UL 9540A, a test method for evaluating thermal runaway fire propagation, is critical to ensure systems can contain or mitigate fire risks. Compliance is often required for local code approvals.
Ω IEEE 1547 – Standard for Interconnecting Distributed Resources with Electric Power Systems: For ESS connected to utility grids, IEEE 1547 specifies requirements for interconnection, including power quality, voltage regulation, and anti-islanding protection. It ensures ESS can safely operate in parallel with the grid, providing ancillary services like frequency regulation or peak shaving without compromising grid stability.
Ω Local Building and Fire Codes: Beyond national and international standards, local jurisdictions — such as college town sustainability initiatives — often enforce additional requirements. Apart from the primary goal of saving energy specific design and construction requirements may apply. These may include specific setback distances, fire-rated enclosures, or emergency response plans tailored to the facility’s size and location. City of Ann Arbor Construction & Building
Compliance with these standards involves collaboration among engineers, installers, and inspectors. Systems must be designed with robust BMS, cooling, and fire mitigation, constructed with high-quality materials, and regularly maintained to meet safety and performance expectations.
Use the login credentials at the upper right of our home page.
Related, but not covered today:
Utility scale (high voltage) owned and operated by merchant utilities.
Ω IEC 62619 – Secondary Cells and Batteries Containing Alkaline or Other Non-Acid Electrolytes: This international standard focuses on the safety of lithium-ion batteries used in industrial ESS. It outlines requirements for cell and module testing, including electrical, mechanical, and environmental stress tests to prevent failures like short circuits or fires. IEC 62619 also specifies battery management system (BMS) requirements to monitor voltage, temperature, and state-of-charge, ensuring operational stability.
Ω IEC 62485-2 – Safety Requirements for Secondary Batteries and Battery Installations: This standard applies to stationary battery systems, addressing electrical safety, installation practices, and maintenance. It emphasizes protection against electric shock, overcurrent, and short-circuit risks, requiring robust insulation and fault detection systems.
“Mount Fuji from Lake Yamanaka” Takahashi Shōtei (1871-1945) | Los Angeles County Museum of Art
The Japanese Standards Association is the Global Secretariat for a standardization project devoted to the discovery and promulgation of common methods and guidelines for coordinated lifetime management of network assets in power systems to support good asset management. In addition, this may include the development of new methods and guidelines required to keep pace with development of electrotechnologies excluding generation assets; covered by other IEC standards.
There has, and will continue to be significant investment in electricity assets which will require ongoing management to realise value for the organizations. In the last 5 years, there has been USD 718 billion investment for electricity, spending on electricity networks and storage continued, reaching an all-time high of USD 277 billion in 2016. In the United States (17% of the total) and Europe (13%), a growing share is going to the replacement of ageing transmission and distribution assets. A more fully dimensioned backgrounder on the business environment that drives the market for this title is available in the link below:
IEC/TC 123 Strategic Business Plan
Begun in 2018, this is a relatively new project with three stabilized titles:
IEC 60050-693 ED1: Management of network assets in power systems – Terminology
IEC 63223-2 ED1: Management of network assets in power systems – Requirements
IEC TS 63224 ED1: Management of network assets in power systems – Practices and case studies
Electropedia: The World’s Online Electrotechnical Vocabulary
It is early in this project’s lifecycle; far too early to find it referenced in public safety and energy laws in the United States where it would affect #TotalCostofOwnership. Where we should, we follow the lead of the USNC/IEC for the United States, while still mindful that many of our IEEE colleagues follow the lead of their own national standards body.
Because this project fills an obvious gap in good practice literature we maintain this project on our 4 times monthly electrotechnology colloquium that we co-host with the IEEE Education & Healthcare Facilities Committee. See our CALENDAR for the next online meeting; open to everyone.
World Standards Day 2023 webinars on latest information technologies
The importance of functional safety | 2023-10-11 IEC Editorial Team
Should every campus building generate its own power? Sustainability workgroups are vulnerable to speculative hype about net-zero buildings and microgrids. We remind sustainability trendsniffers that the central feature of a distributed energy resource–the eyesore known as the university steam plant–delivers most of the economic benefit of a microgrid. [Comments on Second Draft due April 29th] #StandardsMassachusetts
“M. van Marum. Tweede vervolg der proefneemingen gedaan met Teyler’s electrizeer-machine, 1795” | An early energy storage device | Massachusetts Institute of Technology Libraries
We have been following the developmental trajectory of a new NFPA regulatory product — NFPA 855 Standard for the Installation of Stationary Energy Storage Systems — a document with ambitions to formalize the fire safety landscape of the central feature of campus microgrids by setting criteria for minimizing the hazards associated with energy storage systems.
The fire safety of electric vehicles and the companion storage units for solar and wind power systems has been elevated in recent years with incidents with high public visibility. The education industry needs to contribute ideas and data to what we call the emergent #SmartCampus;an electrotechnical transformation — both as a provider of new knowledge and as a user of the new knowledge.
Transcripts of technical deliberation are linked below:
2026 Public Input Report (705 pages) § 2026 Second Draft Meeting Agenda (912 pages)
Comment on the 2026 revision received by March 27, 2025 will be heard at the NFPA June 2025 Expo through NFPA’s NITMAM process.
University of Michigan | Average daily electrical load across all Ann Arbor campuses is on the order of 100 megawatts
A fair question to ask: “How is NFPA 855 going to establish the standard of care any better than the standard of care discovered and promulgated in the NFPA 70-series and the often-paired documents NFPA 110 and NFPA 111?” (As you read the transcript of the proceedings you can see the committee tip-toeing around prospective overlaps and conflicts; never a first choice).
Suffice to say, the NFPA Standards Council has due process requirements for new committee projects and, obviously, that criteria has been met. Market demand presents an opportunity to assemble a new committee with fresh, with new voices funded by a fresh set of stakeholders who, because they are more accustomed to advocacy in open-source and consortia standards development platforms, might have not been involved in the more rigorous standards development processes of ANSI accredited standards developing organizations — specifically the NFPA, whose members are usually found at the top of organization charts in state and local jurisdictions. For example we find UBER — the ride sharing company — on the technical committee. We find another voice from Tesla Motors. These companies are centered in an industry that does not have the tradition of leading practice discovery and promulgation that the building industry has had for the better part of two hundred years.
Our interest in this standard lies on both sides of the education industry — i.e. the academic research side and the business side. For all practical purposes, the most credible, multi-dimensional and effective voice for lowering #TotalCostofOwnership for the emergent smart campus is found in the tenure of Standards Michigan and its collaboration with IEEE Education & Healthcare Facilities Committee (E&H). You may join us sorting through the technical, economic and legal particulars and day at 11 AM Eastern time. The IEEE E&H Committee meets online every other Tuesday in European and American time zones; the next meeting on March 26th. All meetings are open to the public.
University of California San Diego Microgrid
You are encouraged to communicate directly with Brian O’Connor, the NFPA Staff Liaison for specific questions. We have some of the answers but Brian is likely to have all of them. CLICK HERE for the NFPA Directory. Additionally, NFPA will be hosting its Annual Conference & Expo, June 17-20 in San Antonio, Texas; usually an auspicious time for meeting NFPA staff working on this, and other projects.
The prospect of installing of energy storage technologies at every campus building — or groups of buildings, or in regions — is clearly transformational if the education facilities industry somehow manages to find a way to drive the cost of operating and maintaining many energy storage technologies lower than the cost of operating and maintaining a single campus distributed energy resource. The education facility industry will have to train a new cadre of microgrid technology specialists who must be comfortable working at ampere and voltage ranges on both sides of the decimal point that separates power engineers from control engineers. And, of course, dynamic utility pricing (set by state regulatory agencies) will continue to be the most significant independent control variable.
Finding a way to make all this hang together is the legitimate work of the academic research side of the university. We find that sustainability workgroups (and elected governing bodies) in the education industry are vulnerable to out-sized claims about microgrids and distributed energy resources; both trendy terms of art for the electrotechnical transformation we call the emergent #SmartCampus.
We remind sustainability trendsniffers that the central feature of a distributed energy resource — the eyesore known as the university steam plant — bears most of the characteristics of a microgrid. In the videoclip linked below a respected voice from Ohio State University provides enlightenment on this point; even as he contributes to the discovery stream with a study unit.
Ohio State University McCracken Power Plant
Issue: [16-131]
Category: District Energy, Electrical, Energy, Facility Asset Management, Fire Safety, Risk Management, #SmartCampus, US Department of Energy
Colleagues: Mike Anthony, Bill Cantor (wcantor@ieee.org). Mahesh Illindala
Standards Massachusetts, Standards Texas, Standards Ohio
*It is noteworthy that (NFPA 70) National Electrical Code-Making Panel 1 has appropriated vehicle-to-grid installations into its scope.
Princeton University Power Plant | Click on image
LEARN MORE:
Related Post: Electrical Safety Research Advisory Committee
Bibiography: Campus Microgrids
Higher Education Facilities Conference: The Rise of University Microgrids
Here's an interesting shift – #utilities are starting to invest in big #batteries rather than building new #power plants. Find out why over at @GreenBiz: https://t.co/m0DYK9qAae #energy #EnergyStorage
— IEEE Power & Energy Society (@ieee_pes) February 28, 2019
Mahesh Illindala enlightens understanding of what microgrid is, and is not:
Check out our top story from February 2018 – Making the right battery storage choice for solar panel installations https://t.co/1xyTnd17TF pic.twitter.com/sXJNX0kSfr
— IEC (@IECStandards) January 2, 2019
Spoon University was founded in 2013 by Sarah Adler and Mackenzie Barth, two Northwestern University students. Living off-campus, they struggled to cook and navigate local dining options, noticing a lack of food media tailored to college students. They launched a food-focused magazine and website at Northwestern, which quickly grew to over 100 student contributors.
The platform expanded to other campuses, driven by student interest, becoming a crowd-sourced food network for millennials. By 2015, it raised $2 million in funding and now operates chapters at over 200 campuses worldwide, offering recipes, reviews, and food-related content
National Geographic: The story of how the lobster roll became New England’s most iconic food
This content is accessible to paid subscribers. To view it please enter your password below or send mike@standardsmichigan.com a request for subscription details.
This content is accessible to paid subscribers. To view it please enter your password below or send mike@standardsmichigan.com a request for subscription details.
Ernest Renan (1823-1892) was a French philosopher, historian, and scholar of religion. He is best known for his work on nationalism and the relationship between language, culture, and identity. The language of technology– and the catalog of codes, standards, guidelines, recommended practices and government regulations rest upon a common understanding of how things can and should work separately. The essay is widely cited:
In our domain we routinely see technical agreement and disagreement among stakeholders resolved, or left unresolved because of definitions — even when discussion is conducted in English. We keep the topic of language (Tamil (மொழி) — since it is one of the most widely spoken languages on earth) on our aperiodic Language colloquia. See our CALENDAR for the next online meeting; open to everyone.
Université Paris 1 Panthéon-Sorbonne
English and French are the two most prominent diplomatic languages, especially in historical and international contexts. They have long been the primary languages of diplomacy due to their widespread use in international organizations and historical influence.
English: Dominates in modern diplomacy, international law, and global organizations. It is the working language in many international forums, including the United Nations, NATO, and the Commonwealth of Nations.
French: Traditionally known as the “language of diplomacy,” French was the dominant diplomatic language until the 20th century. It remains a significant language in international relations, particularly within the United Nations, the European Union, and many African nations.
While other languages like Spanish, Arabic, Russian, and Chinese are also used in diplomatic contexts and are official languages of the United Nations, English and French are the most universally recognized and utilized in diplomatic settings.
“The Tower of Babel” 1563 | Pieter Bruegel the Elder
2021 IBC Chapter 2: Definitions
2024/2025/2026 ICC CODE DEVELOPMENT SCHEDULE
Complete Monograph (2650 pages) | Note our proposal on Page 754
“All language is but a poor translation.”
― Franz Kafka
The Impossibility of Translating Franz Kafkahttps://t.co/OotULfVwA5@ASTMIntl
Standard Practice for Assessing Language Proficiencyhttps://t.co/RQVv3TJs2k pic.twitter.com/EZax9evtNL— Standards Michigan (@StandardsMich) April 25, 2021
“Ever wondered what would happen if elevator’s didn’t have buttons and relied on vocal recognition instead?”
The Scottish Comedy Channel | @ComedyUnit
Language is the only homelandhttps://t.co/fulQaBUBDChttps://t.co/mrQCfy4niM pic.twitter.com/8ipdyFLPuW— Standards Michigan (@StandardsMich) July 11, 2024
‘Girls tell about their time at Canadian College of English Language’https://t.co/SKYf5gNZLXhttps://t.co/fsQaxC1L69 pic.twitter.com/FBywkbB1BY
— Standards Michigan (@StandardsMich) July 1, 2024
Goat farming is an important source of livelihood for many small-scale farmers in developing countries, particularly in regions such as sub-Saharan Africa and South Asia. The FAO estimates that more than 90% of the world’s goats are raised in developing countries, where they provide a critical source of food and income for rural communities.
Overall, the global goat farming industry continues to grow, driven by increasing demand for goat meat and milk products, as well as the potential for sustainable agriculture practices.
Advantages:
Low start-up costs: Goat farming requires relatively low start-up costs compared to other types of agriculture. Goats are small animals that do not require much space, and they can be raised in a variety of environments, from small backyard farms to large commercial operations.
High productivity: Goats are known for their high reproductive rate, which allows farmers to increase their herd size quickly. They are also efficient at converting food into milk and meat, making them a profitable investment for farmers.
Multiple uses: Goats can be raised for meat, milk, and fiber, making them a versatile livestock option. Additionally, their manure can be used as fertilizer, and they can be used for weed control on farms and other properties.
Sustainable farming: Goat farming can be a sustainable agricultural practice, as goats do not require large amounts of feed or water, and they can be raised on marginal lands that are unsuitable for other types of agriculture.
Disadvantages:
Predation: Goats are vulnerable to predation by coyotes, dogs, and other predators, which can be a significant problem for farmers, especially in rural areas.
Disease susceptibility: Goats are susceptible to a variety of diseases, some of which can be difficult to diagnose and treat. Additionally, some diseases can be transmitted to humans, making it important for farmers to take precautions when handling their animals.
Market volatility: The demand for goat products can be volatile, and prices can fluctuate significantly based on supply and demand. This can make it challenging for farmers to predict their income and manage their finances.
Labor intensive: Goat farming can be labor-intensive, especially during kidding and milking seasons. This can make it difficult for farmers to manage their workload, especially if they have a large herd.
Girl with a Goat | Benton County Arkansas
When you don’t have children or a significant other so get graduation photos done with your study subjects & absolute best pals ❤️
I despise having my photo taken & almost cancelled but decided I should suck it… although ended up in my dungarees for my favourite ones 😂 pic.twitter.com/0c6ZOBDEHI
— Dr Holly Vickery (@SkylarkHolly) July 25, 2024
Hi followers! It’s time to update my pinned tweet as I’ve finished my PhD at Reading in goat kid behaviour and welfare and…
I’m now a *permanent* lecturer at Harper Adams university!
Here I love to love to talk all things science, animals, crafts and smallholding life ☺️ pic.twitter.com/J9xQlLVgTi— Holly Vickery PhD (@SkylarkHolly) April 28, 2024
New update alert! The 2022 update to the Trademark Assignment Dataset is now available online. Find 1.29 million trademark assignments, involving 2.28 million unique trademark properties issued by the USPTO between March 1952 and January 2023: https://t.co/njrDAbSpwB pic.twitter.com/GkAXrHoQ9T
— USPTO (@uspto) July 13, 2023
Standards Michigan Group, LLC
2723 South State Street | Suite 150
Ann Arbor, MI 48104 USA
888-746-3670
 |
 |
|
 |
 |
|
 |
 |
