Hugh DeHaven
Hugh DeHaven (3 March 1895-13 February 1980) was an American pilot, engineer and passive safety pioneer.[1] DeHaven survived a plane crash while training as a Royal Canadian Flying Corps pilot during the First World War,[2] and became interested in improving human survivability in vehicle crashes. He has been called "Father of Crash Survivability".[3]
Early life
DeHaven was born in 1895 in Brooklyn, New York. His father was a steel worker and inventor. He attended Fessenden School in West Newton, Massachusetts from 1906 to 1909 before attending The Hill School in Pottstown, Pennsylvania from 1909 to 1914. Following graduation DeHaven attended Cornell University from 1914 to 1915, and Columbia University from 1915 to 1916. He tried to join the US Army Air Corps in 1916, but was rejected. He joined the Royal Flying Corps Canada in Toronto, Canada.[4]
While training as a pilot during the First World War, DeHaven survived a plane crash.[2] While recuperating from a ruptured pancreas, he tried to understand why he, and only he, survived that crash,[5] noting that his cockpit was the only one that remained intact.
Early work
DeHaven was issued US 2710649 "Combination shoulder and lap safety belt"[6] in 1955 for the first three point seat belt.
Early in the 20th century, DeHaven established the Aviation Safety and Research Facility at Cornell University.[7]
In 1939, DeHaven recommended the use of helmets and seat belts at a 45° angle in airplanes. He created the inertial reel and the concept of the "delethalized" instrument panel.
Crash Injury Research (CIR)
In 1942, DeHaven started the Crash Injury Research project at Cornell, and published the classic Mechanical analysis of survival in falls from heights of fifty to one hundred and fifty feet. He concluded:
- The human body can tolerate and expend a force of two hundred times the force of gravity for brief intervals during which the force acts in transverse relation to the long axis of the body. It is reasonable to assume that structural provisions to reduce impact and distribute pressure can enhance survival and modify injury within wide limits in aircraft and automobile accidents. [8][9]
In 1950, DeHaven published a report pointing to the second collision and the risk involved in vehicle ejection. He created the concept of "packaging" car occupants. He concluded:[1] In 1953, the project split into two sub-projects, namely the Automobile Crash Injury Research (ACIR) and the Aviation Crash Injury Research (AvCIR) projects.[4] Flight Safety Foundation takes over AvCIR (later Aviation Safety Engineering and Research (AvSER)), and continues the crash survival research started by DeHaven. AvSER is now part of Dynamic Science, Inc.[10][11]
Quotes
- We will get into anybody’s automobile, go any desired distance at dangerous speeds, without safety belts, without shoulder harness, and with a very minimum of padding or other protection to prevent our heads and bodies from smashing against the inside of a car in an accident. The level of safety which we accept for ourselves, our wives and our children is, therefore, on a par with shipping fragile valuable objects loose inside a container.[12]
- "...people knew more about protecting eggs in transit than they did about protecting human heads"[13]
See also
References
- 1 2 Hugh DeHaven - Still Relevant for Rollovers
- 1 2 Hugh DeHaven - Dynamic Sciences Inc
- ↑ Comparative Study into Occupant Support Concept with Respect to Crash Response - Page 22
- 1 2 The Hugh DeHaven, PhD (1895-1980) Papers
- ↑ Albaum M. "Safety Sells: Market Forces and Regulation in the Development of Airbags" (PDF). pp. Chapter 1. p 3.
- ↑ US Patent 2710649
- ↑ Safety and Health Hall of Fame
- ↑ Albaum M. "Safety Sells: Market Forces and Regulation in the Development of Airbags" (PDF). pp. Chapter 1.
- ↑ Head Knocker/Hugh DeHaven and Collision Safety
- ↑ History of Exodyne, Inc
- ↑ Dynamic Science, Inc.
- ↑ DeHaven H (1964). "Accident Survival-Airplane and Passenger Automobile". In Haddon W, Suchman EA, Klein D. Accident Research. Methods and approaches. New York: Harper & Rowe.
- ↑ DeHaven H (March 2000). "Mechanical analysis of survival in falls from heights of fifty to one hundred and fifty feet. 1942". Inj. Prev. 6 (1): 62–8. doi:10.1136/ip.6.1.62-b. PMC 1730592. PMID 10728546.