Once every eighteen months we spend a week drilling into the National Electrical Code by submitting new proposals or comments on proposed revisions. Today we review the actions taken by the technical committees last month ahead of the ballot deadline for the First Revision Report — now set for April 16th.
“G.K. Chesterton’s Fence” is a concept often cited in discussions about change, reform, and tradition — in software as well as in “campus traditions”.
It’s derived from a quote by the English writer, G.K. Chesterton, which goes: “In the matter of reforming things, as distinct from deforming them, there is one plain and simple principle; a principle which will probably be called a paradox. There exists in such a case a certain institution or law; let us say, for the sake of simplicity, a fence or gate erected across a road. The more modern type of reformer goes gaily up to it and says, ‘I don’t see the use of this; let us clear it away.’ To which the more intelligent type of reformer will do well to answer: ‘If you don’t see the use of it, I certainly won’t let you clear it away. Go away and think. Then, when you can come back and tell me that you do see the use of it, I may allow you to destroy it.'”
In essence, Chesterton is cautioning against the impulse to dismantle or alter established systems, institutions, or traditions without fully understanding why they were put in place in the first instance. The “fence” represents any existing structure, rule, or tradition, while the act of removing it symbolizes reform or change. Chesterton suggests that before advocating for the removal or alteration of something, one should first understand its purpose and history. This is because such structures often have reasons for their existence, which might not be immediately apparent to those seeking change.
The principle emphasizes the importance of respecting tradition and the wisdom of those who came before, as well as the necessity of informed decision-making when it comes to implementing reforms. It urges individuals to exercise caution and humility, recognizing that existing systems may have evolved to address specific needs or challenges, and that blindly discarding them could lead to unforeseen consequences.
“View of the Colosseum” 1747 Giovanni Paolo Panini
Play is the making of civilization—how one plays the game
more to the point than whether the game is won or lost.
The purpose of this standard is to establish the minimum requirements to safeguard health, safety and general welfare through structural strength, means of egress facilities, stability and safety to life and property relative to the construction, alteration, repair, operation and maintenance of new and existing temporary and permanent bench bleacher, folding and telescopic seating and grandstands. This standard is intended for adoption by government agencies and organizations setting model codes to achieve uniformity in technical design criteria in building codes and other regulations.
This title is on the standing agenda of our Sport, Olahraga (Indonesian), رياضة (Arabic), colloquia. You are welcomed to join us any day at with the login credentials at the upper right of our home page.
At the April International Code Council Group A Hearings there were three candidate code changes related to the safety standard of care for athletic venues:
These concepts will likely be coordinated with another ICC regulatory product —ICC 300 – Standard on Bleachers, Folding and Telescopic Seating, and Grandstands — covered here previously. ICC 300 is a separate document but some of the safety concepts track through both.
The ICC Public Comment Hearings on Group A comments in Richmond Virginia ended a few days ago (CLICK HERE). The balloting is being processed by the appropriate committee and will be released soon. For the moment, we are happy to walk through the proposed changes – that will become part of the 2021 International Building Code — any day at 11 AM Eastern time. We will walk through all athletic and recreation enterprise codes and standards on Friday, November 2nd, 11 AM Eastern time. For access to either teleconference, click on the LIVE Link at the upper right corner of our home page.
Issue: [15-283]
Category: Athletics & Recreation, Architectural, Public Safety
Contact: Mike Anthony, Richard Robben, Jack Janveja
The International Code Council has launched a new revision cycle for its consensus document — ICC 300 – Standard on Bleachers, Folding and Telescopic Seating, and Grandstands. The purpose of the effort is the development of appropriate, reasonable, and enforceable model health and safety provisions for new and existing installations of all types of bleachers and bleacher-type seating, including fixed and folding bleachers for indoor, outdoor, temporary, and permanent installations. Such provisions would serve as a model for adoption and use by enforcement agencies at all levels of government in the interest of national uniformity.
Comments are due December 4th. The document is free. You may obtain an electronic copy from: https://www.iccsafe.org/codes-techsupport/standards/is-ble/. Comments may be sent to Edward Wirtschoreck, (888) 422-7233, ewirtschoreck@iccsafe with copy to psa@ansi.org)
* With some authority, we can claim that without Standards Michigan, many education industry trade associations would not be as involved in asserting the interest of facility managers in global consensus standards development processes. See ABOUT.
The 2024 Kentucky Derby will be run on Saturday, May 4, 2024. Live TV coverage begins at 2:30 p.m. ET (11:30 a.m. PT). Post time for the 150th running of the Kentucky Derby is 6:57 p.m. ET (3:45 p.m. PT)
During today’s session we approach disaster avoidance, management and recovery literature from a different point of view than our customary approach — i.e. what happens when, a) there is failure to conform to the standard, b) there is no applicable standard at all. This approach necessarily requires venturing into the regulatory and legal domains. We will confine our approach to the following standards development regimes:
De facto standards: These are standards that are not officially recognized or endorsed by any formal organization or government entity, but have become widely adopted by industry or through market forces. Examples include the QWERTY keyboard layout and the MP3 audio format.
De jure standards: These are standards that are formally recognized and endorsed by a government or standard-setting organization. Examples include the ISO 9000 quality management standard and the IEEE 802.11 wireless networking standard.
Consortium standards: These are standards that are developed and maintained by a group of industry stakeholders or organizations, often with the goal of advancing a particular technology or product. Examples include the USB and Bluetooth standards, which are maintained by the USB Implementers Forum and the Bluetooth Special Interest Group, respectively.
Open standards: These are standards that are freely available and can be used, implemented, and modified by anyone without restriction. Examples include the HTML web markup language and the Linux operating system.
Proprietary standards: These are standards that are owned and controlled by a single organization, and may require payment of licensing fees or other restrictions for use or implementation. Examples include the Microsoft Office document format and the Adobe PDF document format.
ANSI accredited standards developers with disaster management catalogs
We may have time to review State of Emergency laws on the books of most government agencies; with special attention to power blackout disasters.
Cases involving the Takings Clause of the Fifth Amendment might be relevant when government actions related to natural disasters affect private property rights.
Committee Action Hearings on the Group A tranche of titles, some of which interact structural elements at risk in natural disasters will be heard in Orlando, April 7-16.
“Landscape between Storms” 1841 Auguste Renoir
When is it ever NOT storm season somewhere in the United States; with several hundred schools, colleges and universities in the path of them? Hurricanes also spawn tornadoes. This title sets the standard of care for safety, resilience and recovery when education community structures are used for shelter and recovery. The most recently published edition of the joint work results of the International Code Council and the ASCE Structural Engineering Institute SEI-7 is linked below:
Given the historic tornados in the American Midwest this weekend, its relevance is plain. From the project prospectus:
The objective of this Standard is to provide technical design and performance criteria that will facilitate and promote the design, construction, and installation of safe, reliable, and economical storm shelters to protect the public. It is intended that this Standard be used by design professionals; storm shelter designers, manufacturers, and constructors; building officials; and emergency management personnel and government officials to ensure that storm shelters provide a consistently high level of protection to the sheltered public.
This project runs roughly in tandem with the ASCE Structural Engineering Institute SEI-17 which has recently updated its content management system and presented challenges to anyone who attempts to find the content where it used to be before the website overhaul. In the intervening time, we direct stakeholders to the link to actual text (above) and remind education facility managers and their architectural/engineering consultants that the ICC Code Development process is open to everyone.
The ICC receives public response to proposed changes to titles in its catalog at the link below:
You are encouraged to communicate with Kimberly Paarlberg (kpaarlberg@iccsafe.org) for detailed, up to the moment information. When the content is curated by ICC staff it is made available at the link below:
We maintain this title on the agenda of our periodic Disaster colloquia which approach this title from the point of view of education community facility managers who collaborate with structual engineers, architects and emergency management functionaries.. See our CALENDAR for the next online meeting, open to everyone.
The original University of Michigan codes and standards enterprise advocated actively in Article 708 Critical Operations Power Systems (COPS) of the National Electrical Code (NEC) because of the elevated likelihood that the education facility industry managed assets that were likely candidates for designation critical operations areas by emergency management authorities.
Because the NEC is incorporated by reference into most state and local electrical safety laws, it saw the possibility that some colleges and universities — particularly large research universities with independent power plants, telecommunications systems and large hospitals — would be on the receiving end of an unfunded mandate. Many education facilities are identified by the Federal Emergency Management Association as community storm shelters, for example.
As managers of publicly owned assets, University of Michigan Plant Operations had no objection to rising to the challenge of using publicly owned education facilities for emergency preparedness and disaster recovery operations; only that meeting the power system reliability requirements to the emergency management command centers would likely cost more than anyone imagined — especially at the University Hospital and the Public Safety Department facilities. Budgets would have to be prepared to make critical operations power systems (COPS) resistant to fire and flood damages; for example.
Collaboration with the Institute of Electrical and Electronic Engineers Industrial Applications Society began shortly after the release of the 2007 NEC. Engineering studies were undertaken, papers were published (see links below) and the inspiration for the IEEE Education & Healthcare Facilities Committee developed to provide a gathering place for power, telecommunication and energy professionals to discover and promulgate leading practice. That committee is now formally a part of IEEE and collaborates with IAS/PES JTCC assigned the task of harmonizing NFPA and IEEE electrical safety and sustainability consensus documents (codes, standards, guidelines and recommended practices.
The transcript of NEC Code Making Panel 13 — the committee that revises COPS Article 708 every three years — is linked below:
The 2023 Edition of the National Electrical Code does not contain revisions that affect #TotalCostofOwnership — only refinement of wiring installation practices when COPS are built integral to an existing building that will likely raise cost. There are several dissenting comments to this effect and they all dissent because of cost. Familiar battles over overcurrent coordination persist.
Our papers and proposals regarding Article 708 track a concern for power system reliability — and the lack of power — as an inherent safety hazard. These proposals are routinely rejected by incumbent stakeholders on NEC technical panels who do not agree that lack of power is a safety hazard. Even if lack of power is not a safety hazard, reliability requirements do not belong in an electrical wiring installation code developed largely by electricians and fire safety inspectors. The IEEE Education & Healthcare Facilities Committee (IEEE E&H) maintains a database on campus power outages; similar to the database used by the IEEE 1366 committees that develop reliability indices to enlighten public utility reliability regulations.
Public input on the 2026 revision to the NEC will be received until September 7th. We have reserved a workspace for our priorities in the link below:
The first elevator in the United States was installed at Harvard University in 1874. It was not a passenger elevator as we typically think of today, but rather a freight elevator used to move heavy items within a building. The installation of this elevator marked an important development in building technology and transportation within multi-story structures. It was based on the design of Elisha Otis, who is famous for inventing the safety elevator with a safety brake system that prevents the elevator from falling if the hoisting cable fails. Otis’ innovation played a pivotal role in making elevators safe and practical for everyday use, leading to their widespread adoption in buildings around the world.
Elevator design by the German engineer Konrad Kyeser (1405)
Education communities are stewards of 100’s of lifts, elevators and moving walks. At the University of Michigan, there are the better part of 1000 of them; with 19 of them in Michigan Stadium alone. The cost of building them — on the order of $50,000 to $150,000 per floor depending upon architectural styling — and the highly trained staff needed to operate, maintain and program interoperability software is another cost that requires attention. All building design and construction disciplines — architectural, mechanical and electrical have a hand in making this technology safe and sustainabile.
We start with international and nationally developed best practice literature and work our way to state level adaptations. Labor for this technology is heavily regulated.
Its a rarefied and crazy domain for the user-interest. Expertise is passionate about safety and idiosyncratic but needs to be given the life safety hazard. Today we review o pull together public consultation notices on relevant codes, standards and regulations today 11 AM/EDT.
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/njrDAbSpwBpic.twitter.com/GkAXrHoQ9T