The earliest installation of a passenger elevator in a university building in the United States was at the Massachusetts Institute of Technology in Cambridge. In 1861, Otis Brothers & Co., the company founded by Elisha Graves Otis, installed the first passenger elevator in this three-story structure that housed laboratories, classrooms, and offices for faculty and students.
This early installation of a passenger elevator marked an important milestone in the history of vertical transportation on college and university campuses, and it paved the way for the adoption of elevators in other educational institutions as they expanded in size and height over time.
Bringing technology and industrial innovation to market more quickly
Encouraging cooperative research and development between business and the federal government by providing access to federal laboratories
Making it easier for businesses to obtain exclusive licenses to technology and inventions that result from cooperative research with the federal government
The NTTAA — along with administrative circular A-119 from the White House Office of Management and Budget — made a direct impact on the development of new industrial and technology standards by requiring that all Federal agencies use privately developed standards, particularly those developed by standards developing organizations accredited by the American National Standards Institute (ANSI). In circular A-119 federal agencies were also encouraged to participate in the development of those standards. While discussion continues about how well the US non-government sector is doing to advance national technology strategy continues (see January 17, 2012 White House Memo M-12-08) the US standards system remains the most effective process for advancing national technology and economic priorities for the education university and others.
Comments are due by March 26th. You may comment directly to ANSI at this email address: psa@ansi.org. With respect to our higher priorities, we will not be commenting on this redline, though intellectual property and patent policies are high on the agenda of many research universities. We have advocated in other parts of the ANSI Essential Requirements document in the past, however — a history we are happy to explain at any of our weekly Open Door teleconferences every Wednesday, 11 AM Eastern time. Anyone is welcomed to join these discussions with the login information in the link below:
At some point transformation of electric energy from distribution voltage to utilization voltage must occur — either proximate to structures on the exterior (where they can present an eyesore to ambience and ‘campus feeling’) or within a building if the architect will design an interior space where switchgear can be operated safely.
Since 1993 we have advocated safety and sustainability of either type of installation in the National Electrical Code. Today we review relevant code requirements respecting relatively new requirements for the education industry’s green agenda.
Graph Neural Networks 2023: (“Boosting short-term electric load forecasting”) introduced visibility graph neural networks for forecasting in high-voltage/medium-voltage substations. This approach uses graph theory to model complex grid interactions, improving accuracy over traditional methods.
Ahead of the April close date for comments on the Second Draft of the 2026 revision of the NEC we examine thought trends on the following:
How does “high voltage” differ among electrotechnology professionals? Signaling and control systems workers have a much lower criteria than a merchant utility lineman than a campus bulk distribution engineer. In other words, “high voltage” is generally understood in practice and essential for worker safety. Labeling counts.
What is the origin of the apparent “confusion’ about high voltage in the IEEE, IEC, NFPA and TIA electrical safety catalogs? Is the distinction functionally acceptable — i.e. a term of art understood well enough in practice?
How can the 2026 NEC be improved for engineers, electricians and inspectors? There has been some considerable re-organization of low, medium and high voltage concepts in the 2023. It usually takes at least two NEC revision cycles for workable code to stabilize. Since education communities purchase and distribute higher voltage power on large campuses; how can power purchasing and customer distribution system best practice be improved?
Standards Michigan, spun-off in 2016 from the original University of Michigan Business & Finance Operation, has peppered NFPA 70 technical committees writing the 2016-2026 National Electric Code with proposals to reduce the size of building premise feeder infrastructure; accommodating the improvements made in illumination and rotating machinery energy conservation since the 1980’s (variable frequency drives, LED lighting, controls, etc.)
These proposals are routinely voted down in 12-20 member committees representing manufacturers (primarily) though local inspection authorities are complicit in overbuilding electric services because they “bill by the service panel ampere rating”. In other words, when a municipality can charge a higher inspection fee for a 1200 ampere panel, what incentive is there to support changes to the NEC that takes that inspection fee down to 400 amperes?
The energy conservation that would result from the acceptance of our proposals into the NEC are related to the following: reduced step down transformer sizes, reduced wire and conduit sizes, reduced panelboard sizes, reduced electric room cooling systems — including the HVAC cooling systems and the ceiling plenum sheet metal carrying the waste heat away. Up to 20 percent energy savings is in play here and all the experts around the table know it. So much for the economic footprint of the largest non-residential building construction market in the United States — about $120 billion annually.
The market incumbents are complicit in ignoring energy conservation opportunity. To paraphrase one of Mike Anthony’s colleagues representing electrical equipment manufacturers:
“You’re right Mike, but I am getting paid to vote against you.”
For decades, application of National Electrical Code (NEC) rules for sizing services, feeders and branch circuits has resulted in unused capacity in almost all occupancy classes. US Department of Energy data compiled in 1999 indicates average load on building transformers between 10 and 25 percent. More recent data gathered by the educational facilities industry has verified this claim. Recognizing that aggressive energy codes are driving energy consumption lower, and that larger than necessary transformers create larger than necessary flash hazard, the 2014 NEC will provide an exception in Section 220.12 that will permit designers to reduce transformer kVA ratings and all related components of the power delivery system. This is a conservative, incremental step in the direction of reduced load density that is limited to lighting systems. More study of feeder and branch circuit loading is necessary to inform discussion about circuit design methods in future revisions of the NEC.
“What art is, in reality, is this missing link, not the links which exist.
It’s not what you see that is art; art is the gap”
— Marcel Duchamp
Today we refresh our understanding of the literature that guides the safety and sustainability goals of lively art and special event setting on the #WiseCampus. Consortia have evolved quickly in recent years, leading and lagging changes in the content creation and delivery domain. With this evolution a professional discipline has emerged that requires training and certification in the electrotechnologies that contribute to “event safety”; among them:
ASHRAE International
Standard 62.1: This standard establishes minimum ventilation rates and indoor air quality requirements for commercial buildings, including theaters and auditoriums.
Standard 55: This standard specifies thermal comfort conditions for occupants in indoor environments, which can have an impact on air quality.
RP-16-17 Lighting for Theatrical Productions: This standard provides guidance on the design and implementation of lighting systems for theatrical productions. It includes information on the use of color, light direction, and light intensity to create different moods and effects.
RP-30-15 Recommended Practice for the Design of Theatres and Auditoriums: This standard provides guidance on the design of theaters and auditoriums, including lighting systems. It covers topics such as seating layout, stage design, and acoustics, as well as lighting design considerations.
DG-24-19 Design Guide for Color and Illumination: This guide provides information on the use of color in lighting design, including color temperature, color rendering, and color mixing. It is relevant to theater lighting design as well as other applications.
Dance and Athletic Floor Product Standards: ASTM F2118, EN 14904, DIN 18032-2
Incumbent standards-setting organizations such as ASHRAE, ASTM, ICC, IEEE, NFPA have also discovered, integrated and promulgated event safety and sustainability concepts into their catalog of best practice titles; many already incorporated by reference into public safety law. We explore relevant research on crowd management and spectator safety.
The circumstances of the pandemic has made “re-rationalization” of education community spaces an urgent priority. Today at 15:00 UTC we pick through the concepts in play. Use the login credentials at the upper right of our home page.
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
