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Citicorp Center engineering crisis

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Citigroup building with a sketch of internal framework superimposed on one side. The same design is used on all four sides and transmits wind and gravity loads to the four support stilts. There is also a fifth support column in the center.

In July 1978, a possible structural flaw was discovered in Citicorp Center, a skyscraper that had recently been completed in New York City. Workers surreptitiously made repairs over the next few months. The building, now known as Citigroup Center, occupied an entire block and was to be the headquarters of Citibank. Its structure, designed by William LeMessurier, had several unusual design features, including a raised base supported by four offset stilts and a column in the center, diagonal bracing which absorbed wind loads from upper stories, and a tuned mass damper with a 400-ton concrete weight floating on oil[1] to counteract oscillation movements. It was the first building that used active mechanical elements (the tuned mass damper) for stabilization.[1][2] Concerned about "quartering winds" directed diagonally toward the corners of the building, Princeton University undergraduate student Diane Hartley investigated the structural integrity of the building and found it wanting. However, it is not clear whether her study ever came to the attention of LeMessurier, the chief structural engineer of the building.

At around the same time as Hartley was studying the question, an architecture student at New Jersey Institute of Technology (NJIT) named Lee DeCarolis chose the building as the topic for a report assignment in his freshman class on the basic concepts of structural engineering.[3] A Professor Zoldos of NJIT expressed reservations to DeCarolis about the building's structure, and DeCarolis contacted LeMessurier, relaying what his professor had said. LeMessurier had also become aware that during the construction of the building, changes had been made to his design without his approval, and he reviewed the calculations of the building's stress parameters and the results of wind tunnel experiments.[2] He concluded there was a problem. Worried that a high wind could cause the building to collapse, LeMessurier directed that the building be reinforced.

The reinforcements were made stealthily at night while the offices in the building were open for regular operation during the day. The concern was for the integrity of the building structure in high wind conditions. Estimates at the time suggested that if the mass damper was disabled by a power failure, the building could be toppled by a 70-mile-per-hour (110 km/h) quartering wind, with possibly many people killed as a result. The reinforcement effort was kept secret until 1995. The tuned mass damper has a major effect on the stability of the structure, so an emergency backup generator was installed and extra staff was assigned to ensure that it would keep working reliably during the structural reinforcement.

The city had plans to evacuate the Citicorp Center and other surrounding buildings if high winds did occur.[2] Hurricane Ella did threaten New York during the retrofitting, but it changed course before arriving. Ultimately, the retrofitting may not have been necessary. A NIST reassessment using modern technology later determined that the quartering wind loads were not the threat that LeMessurier and Hartley had thought. They recommended a reevaluation of the original building design to determine if the retrofitting had really been warranted.[4] It is not clear whether the NIST-recommended reevaluation was ever conducted, although the question is only an academic one, since the reinforcement had been done.

Background

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St. Peter's Evangelical Lutheran Church is visible on the left-hand side, below the skyscraper. The church's location necessitated the unusual placement of columns in the center of each face instead of at the corners.

The Citigroup Center, originally known as Citicorp Center, is a 59-story skyscraper at 601 Lexington Avenue in the Midtown Manhattan neighborhood of New York City.[5][6][7] It was designed by architect Hugh Stubbins as the headquarters for First National City Bank (later Citibank), along with associate architect Emery Roth & Sons.[8][9][10] LeMessurier Associates and James Ruderman were the structural engineers, and Bethlehem Steel was the steel subcontractor.[9][11] The building was dedicated on October 12, 1977.[12][13]

As part of Citicorp Center's construction, a new building for the site's previous occupant, St. Peter's Lutheran Church, was erected at the site's northwest corner; by agreement, it was supposed to be separate from the main tower.[14][15] To avoid the church, the tower is supported by four stilts[9][16] positioned underneath the centers of each of the tower's edges.[17] (Early plans called for the supports to be placed under the tower's corners, but the agreement with the church prevented that.[18]) To allow this design to work, Bill LeMessurier specified that load-bearing braces in the form of inverted chevrons be stacked above the stilts inside each face of the building. These braces are designed to distribute tension loads created by the wind from the upper stories down to the stilts.[19][20]

The long, multi-story diagonal braces had to be fabricated in sections and assembled on-site, requiring five joints in each brace. LeMessurier's original design for the chevron load braces used welded joints. To save money, Bethlehem Steel proposed changing the construction plans to use bolted joints, a design modification accepted by LeMessurier's office but unknown to the engineer himself until later.[17]

For his original design, LeMessurier focused primarily on the wind load on the building when the wind blew perpendicularly against the side of the building. Although he had initially studied winds from various directions, he had concluded that quartering winds were not the critical case, and came to rely primarily on the calculations for perpendicular winds.[21] Perpendicular winds were the only calculations required by New York City building code. Such winds are normally the worst case, and typically a structural system capable of handling them can easily cope with wind from any other angle.[17][22]

Discovery

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In May 1978, after the building structure was completed, LeMessurier was designing a similar building with wind braces in Pittsburgh, and a potential contractor questioned the expense of using welded rather than bolted joints. LeMessurier asked his office how the welds went at the Citicorp construction and was then told that bolts had been substituted for the welded joints he had prescribed.[21] LeMessurier had not seen the analysis that had been performed when this substitution was done.

In June 1978, Princeton University engineering student Diane Hartley was writing her senior thesis about Citicorp Center's design at the suggestion of her professor, David Billington.[21][23] As part of that work she analyzed the structural design and calculated stresses from quartering winds, finding them higher than the maximum expected stress values provided to her by LeMessurier's firm. Hartley asked her contact at the building design company, Joel S. Weinstein, a junior member of its staff, about the issue, and he provided her with a copy of the firm's calculations for perpendicular winds (but not for quartering winds). Only Weinstein was indicated as signing off on the copies of the calculations he provided to her, although she expected to see them initialed by a second person to confirm them, as was the usual practice in the industry. According to Hartley, she asked for calculations about quartering winds, and Weinstein said he would provide them but then didn't. Calculations for quartering winds were not required by the building code at the time, and were not common practice in the industry (although the design of the building was obviously unusual and would have justified special analysis). Weinstein assured her that the building could handle the necessary forces, and she did not further pursue the issue beyond writing about it in her thesis, which recorded her concerns and the response she received. In his feedback on Hartley's thesis, Billington questioned why her calculations weren't checked against figures from the firm.[21]

In June 1978, LeMessurier was answering questions via phone with a young architectural student,[1] self-identified more than 40 years later as Lee DeCarolis.[24] Those phone calls and the bolt substitutions convinced him to recalculate the wind loads, including the diagonal wind loads.

On July 24, 1978, LeMessurier went to his office and conducted calculations on Citicorp Center's design.[21][22] He had thought that perpendicular winds were the critical case for the building rather than quartering winds. He found that, for four of the eight tiers of chevrons, quartering winds would create a 40 percent increase in wind loads and a 160 percent increase in the load at the bolted joints.[17] Citicorp Center's use of bolted joints and the loads from quartering winds would not have caused concern if these issues had been isolated. However, the combination of the two findings prompted LeMessurier to run tests on structural safety.[25] He concluded that the original welded-joint design could withstand the load from both straight-on and quartering winds, but the modified bolted-joint design could be vulnerable to a 70-mile-per-hour (110 km/h) near-hurricane force quartering wind.[20][21] LeMessurier also discovered that his firm had used New York City's truss safety factor of 1:1 instead of the column safety factor of 1:2.[20]

On July 26, LeMessurier visited wind-tunnel expert Alan Garnett Davenport at the University of Western Ontario. Davenport's team conducted calculations on the building and concluded not only that LeMessurier's modeling was correct but also that, in a real-world situation, member stresses could increase by more than the 40 percent LeMessurier had calculated.[21][26] LeMessurier then went to his Maine summer home on July 28 to analyze the issue.[21][26] With the tuned mass damper active, LeMessurier estimated that a wind capable of toppling the building had a one in fifty-five chance of happening any year.[27][21] But if the tuned mass damper could not function due to a power outage, a wind strong enough to cause the building's collapse had one chance in sixteen of happening any year.[2][27]

Repairs

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LeMessurier agonized over how to deal with the problem. If the issues were made known to the public, he risked ruining his professional reputation and causing panic in the immediate area surrounding the building and the occupants.[28] LeMessurier considered never bringing the issue up, and he also briefly contemplated committing suicide before anyone else found out about the defect.[2][29][30] LeMessurier ultimately contacted Stubbins's lawyer and insurance carrier. LeMessurier then contacted Citicorp's lawyers, the latter of which hired Leslie E. Robertson as an expert adviser.[28] Citicorp accepted LeMessurier's proposal to weld steel plates over the bolted joints, and Karl Koch Erecting was hired for the welding process.[31] Very few people were made aware of the issue, besides Citicorp leadership, mayor Ed Koch, acting buildings commissioner Irving E. Minkin, and the head of the welder's union.[20][31]

Construction crews started installing the welded panels at night in August 1978. Officials made no public mention of any possible structural issues, and the city's three major newspapers had gone on strike.[32][31] Officials barely acknowledged the issue, instead describing the work as a routine procedure. Henry DeFord III of Citicorp claimed the Citicorp Center could withstand a 100-year wind[33] and that there were no "noticeable problems in the building at all".[34] As precautions, emergency generators were installed for the mass damper, strain gauges were placed on critical beams and weather forecasters were engaged.[21] Citicorp and local officials created emergency evacuation plans for the immediate neighborhood.[20][35] However, these evacuation plans were not publicized at the time, although thousands of people could have been killed in a potential collapse.[29] Six weeks into the work, a major storm (Hurricane Ella) was off Cape Hatteras and heading for New York. The reinforcement was only half-finished, with New York City hours away from emergency evacuation, but at that point the backup generators were in place and the mass damper was being continually monitored by special staff, and enough of the bracing had been completed that the tower was estimated to be able to survive a 200-year storm.[35] Ella eventually turned eastward and veered out to sea.[20][35] The weather watch ended on September 13.[35]

Repairs were completed in October 1978, and most of the newspapers remained out of production for weeks after it was completed. LeMessurier claimed a wind strong enough to topple the repaired building would occur only once every 700 years.[32][36] Stubbins and LeMessurier's insurance carrier covered all of the repair costs, estimated to be several million dollars.[2][36]

Publication

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Since no structural failure occurred, the work was not publicized until 1995, when a lengthy article appeared in The New Yorker.[32][37] The 1995 story in The New Yorker described the student as a "young man, whose name has been lost in the swirl of subsequent events" who called LeMessurier saying "that his professor had assigned him to write a paper on the Citicorp tower".[37][22] However, it was clear that Diane Hartley had never contacted LeMessurier directly – she had spoken only to Joel S. Weinstein.[22][1] According to one second-hand report, when one of LeMessurier's colleagues asked whether the student was female, "LeMessurier responded that he didn't know because he had not actually spoken with the student."[1] However, in a lecture on the subject, LeMessurier himself said he had spoken directly and repeatedly with the student and referred to the student as male.[2] LeMessurier died in 2007 without describing any communication with him about the interaction between Hartley and Weinstein.[21]

Hartley identified herself as the probable engineering student in 2011, more than fifteen years after the New Yorker article was published.[22]

However, another student at a different institution later identified himself as the student that LeMessurier spoke to by phone[2] identified himself as Lee DeCarolis in an article published on the Online Ethics Center website.[24] He said he learned in 2011 how he played a part in the Citicorp Building history from reading Einstein's Refrigerator, a 2001 book by the high school teacher and podcaster Steve Silverman. By that time, LeMessurier had died. While he had mentioned his role to acquaintances and even written a play about it, DeCarolis revealed himself to the public at large only after a reassessment by NIST had determined that the effect of the wind loads had not been as severe as Hartley and LeMessurier had determined.[4]

Ethical questions

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According to a case study by the American Institute of Architects (AIA) Trust,[21] "many have viewed the actions of LeMessurier as nearly heroic, and many engineering schools and ethics educators now use LeMessurier's story as an example of how to act ethically." However, others have criticized LeMessurier for his lack of oversight that led to the issues and his lack of honesty toward neighborhood residents, architects, engineers, and other members of the public when the problems were discovered. Architect Eugene Kremer discussed the ethical questions raised in this case in 2002.[29] Kremer listed six key points that he perceived as ethically problematic:[38]

  1. Analysis of wind loads: Although quartering wind loads were considered early in the design process, LeMessurier initially reached the conclusion that they were not the critical case for the building's structural analysis, and came to rely primarily on the calculations for perpendicular winds, as required by building codes, rather than checking all calculations and scenarios thoroughly.[17][29]
  2. Design changes: The steel framework subcontractor (Bethlehem Steel) proposed to use bolted joints instead of full-penetration welding, and the proposal was approved by LeMessurier's firm without LeMessurier personally reviewing the details.[17] Kremer reported that Robert McNamara, "the managing principal for Citicorp in LeMessurier Associates' Cambridge office", stated that after he reviewed the proposal, he "presented the suggested change to Bill LeMessurier", who "discussed [with him] the technical implications and did calculations as to what effect the bolt extension in the connection would have on the movement of the tower ...", and that LeMessurier's firm then approved the details of the change without LeMessurier personally reviewing those details.[29] This somewhat contradicts LeMessurier, who said he wasn't aware of the substitution until after the work had been completed.[2]
  3. Professional responsibility: Before LeMessurier decided to make Citicorp aware of the design defects, he briefly considered concealing the issues instead, or even committing suicide. Kremer said he should not have entertained such thoughts, even briefly.[29][30] In contrast, the AIA study reports that it is clear LeMessurier never really considered the other options seriously.[21]
  4. Public statements: In press interviews and releases of information at the time, officials either omitted or lied about details of the defects. Kremer cites the National Society of Professional Engineers (NSPE) Code of Ethics, which says engineers shall "Issue public statements only in an objective and truthful manner."[29][39]
  5. Public safety: When Hurricane Ella threatened the city in August and September 1978, evacuation plans for the surrounding area were made in secret. Kremer cites the NSPE Board of Ethical Review (BER), which, although it was not commenting about the Citicorp Center specifically, said "withholding critical information from thousands of individuals whose safety is compromised over a significant period of time" is improper (although it could be argued that the Citicorp Center situation did not rise to meet that standard, when considering that no storms with high winds actually occurred in New York City during the period in question, and other steps had been taken to reduce the risk, and evacuation plans were ready if a high-wind storm were to occur).[35]
  6. Advancing professional knowledge: Kremer argues that concealing the crisis for almost 20 years prevented some of the ethical and engineering analysis and learning that could have taken place if information had been released about the Citicorp Center case.[29]

References

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  1. ^ a b c d e Whitbeck, Caroline; Plosky, Eric (May 29, 1995). "William LeMessurier – The Fifty-Nine-Story Crisis: A Lesson in Professional Behavior". Online Ethics Center. Archived from the original on July 9, 2021. Retrieved July 8, 2021.
  2. ^ a b c d e f g h i LeMessurier, William (November 17, 1995). "William LeMessurier-The Fifty-Nine-Story Crisis: A Lesson in Professional Behavior". MIT Mechanical Engineering Colloquium. National Academy of Engineering. Archived from the original on August 7, 2022. Retrieved August 7, 2022 – via YouTube. (tuned mass damper discussion starting at 14:08, reference to the building as the first and to LeMessurier as the "father of the tuned mass damper" at 25:50, phone call with student described at 28:34, finding out about bolt substitution 27:30 (when he learned of it 31:25), wind tunnel experiments 34:10, 16-year failure period if damper was not functioning 35:10, brief thought of suicide 38:15, insurance company interaction and conventionality of diagonal wind analysis 40:40 and 55:40, evacuation plan at 49:30)
  3. ^ DeCarolis, Lee. "Citicorp Building: Who Was the Mystery Student?". Online Ethics Center for Engineering and Science. Retrieved September 12, 2024.
  4. ^ a b Park, Sejun; Duthinh, Dat; Simiu, Emil; Yeo, DongHun (March 6, 2019). "Wind Effects on a Tall Building with Cross Section and Mid-size Base Columns: A Database-assisted Design Approach". Journal of Structural Engineering. 145 (5). New York. doi:10.1061/(asce)st.1943-541x.0002328. PMC 7909585. PMID 33642672. Archived from the original on August 7, 2022. Retrieved August 7, 2022.
  5. ^ "Citigroup Center – The Skyscraper Center". Council on Tall Buildings and Urban Habitat. Archived from the original on June 15, 2012.
  6. ^ "601 Lexington Avenue". Emporis. Archived from the original on May 12, 2018. Retrieved January 1, 2021.{{cite web}}: CS1 maint: unfit URL (link)
  7. ^ Landmarks Preservation Commission 2016, p. 1.
  8. ^ White, Norval; Willensky, Elliot; Leadon, Fran (2010). AIA Guide to New York City (5th ed.). New York: Oxford University Press. p. 320. ISBN 978-0-19538-386-7.
  9. ^ a b c "Manhattan's Fifth Tallest Building Is Designed for Energy Conservation" (PDF). AIA Journal. 60 (4): 11, 61. October 1973. Archived (PDF) from the original on July 21, 2021. Retrieved July 21, 2021.
  10. ^ "Plan for Skyscraper On Lexington Ave. Detailed by Citibank". The New York Times. July 25, 1973. ISSN 0362-4331. Archived from the original on July 21, 2021. Retrieved April 3, 2021.
  11. ^ "Architectural Awards of Excellence" (PDF). American Institute of Steel Construction. 1978. p. 17. Archived (PDF) from the original on July 21, 2021. Retrieved April 6, 2021.
  12. ^ Landmarks Preservation Commission 2016, p. 7.
  13. ^ Goldberger, Paul (October 12, 1977). "Citicorp's Center Reflects Synthesis of Architecture". The New York Times. ISSN 0362-4331. Archived from the original on July 21, 2021. Retrieved April 5, 2021.
  14. ^ Stern, Mellins & Fishman 1995, p. 490.
  15. ^ Alpern, Andrew; Durst, Seymour (2011). Holdouts!: the buildings that got in the way. Old York Foundation Distributed by David R. Godine, Publisher. p. 116. ISBN 978-1-56792-443-5. OCLC 722452921.
  16. ^ Stern, Mellins & Fishman 1995, p. 492.
  17. ^ a b c d e f Morgenstern 1995, p. 46.
  18. ^ "At New York's Citicorp Center, a structure of masterly invention underlies the urbane face of a skyscraper in the grand manner" (PDF). Architectural Record. 159 (E3): 69. August 1978. Archived (PDF) from the original on July 24, 2021. Retrieved July 24, 2021.
  19. ^ Stern, Mellins & Fishman 1995, p. 493.
  20. ^ a b c d e f Werner, Joel (April 17, 2014). "The Design Flaw That Almost Wiped Out an NYC Skyscraper". Slate. Archived from the original on April 17, 2014. Retrieved April 17, 2014.
  21. ^ a b c d e f g h i j k l m Vardaro, Michael. "Case Study: The Citicorp Center Design". AIA Trust. Archived from the original on November 12, 2020. Retrieved November 29, 2020.
  22. ^ a b c d e McGinn, Robert (2018). The Ethical Engineer: Contemporary Concepts and Cases. Princeton University Press. p. 82. ISBN 978-1-4008-8910-5. Archived from the original on July 14, 2023. Retrieved July 21, 2021.
  23. ^ Hartley, Diane Lee (1978). Implications of a Major Urban Office Complex: The Scientific, Social and Symbolic Meanings of Citicorp Center, New York City – V. 1 and 2 (BSE thesis). Princeton University. Archived from the original on July 14, 2023. Retrieved July 21, 2021. Access Restrictions: Walk-in Access. This thesis can only be viewed on computer terminals at the Mudd Manuscript Library.
  24. ^ a b DeCarolis, Lee (August 7, 2022). "Citicorp Building: Who Was the Mystery Student?". Online Ethics Center. Archived from the original on September 28, 2022. Retrieved August 7, 2022.
  25. ^ Morgenstern 1995, pp. 46–47.
  26. ^ a b Morgenstern 1995, p. 47.
  27. ^ a b Morgenstern 1995, pp. 47–48.
  28. ^ a b Morgenstern 1995, pp. 48–49.
  29. ^ a b c d e f g h Kremer, Eugene (Fall 2002). "(Re)Examining the Citicorp Case: Ethical Paragon or Chimera". Cross Currents. 52 (3). Archived from the original on May 23, 2007. Retrieved July 21, 2021.
  30. ^ a b Morgenstern 1995, p. 48.
  31. ^ a b c Morgenstern 1995, p. 50.
  32. ^ a b c Landmarks Preservation Commission 2016, p. 9.
  33. ^ "Citicorp Bldg. To Get $1M in Wind Bracing". New York Daily News. August 9, 1978. p. 271. Archived from the original on July 21, 2021. Retrieved April 6, 2021 – via newspapers.com.
  34. ^ "Citicorp Tower Gets More Steel Bracing As Added Precaution". The Wall Street Journal. August 9, 1978. p. 15. ISSN 0099-9660. ProQuest 134301488.
  35. ^ a b c d e Morgenstern 1995, pp. 52–53.
  36. ^ a b Morgenstern 1995, p. 53.
  37. ^ a b Morgenstern 1995, p. 45.
  38. ^ Delatte, Norbert J. (January 1, 2009). Beyond Failure: Forensic Case Studies for Civil Engineers. ACSE Press. p. 340. ISBN 978-0-7844-7228-6. Archived from the original on July 14, 2023. Retrieved March 13, 2019.
  39. ^ Morgenstern 1995, p. 51.

Sources

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