Chapter 4 - THE CAUSE OF THE ACCIDENT

   The consensus of the Commission and participating investigative
agencies is that the loss of the Space Shuttle Challenger was caused
by a failure in the joint between the two lower segments of the right
Solid Rocket Motor.  The specific failure was the destruction of the
seals that are intended to prevent hot gases from leaking through the
joint during the propellant burn of the rocket motor.  The evidence
assembled by the Commission indicates that no other element of the
Space Shuttle system contributed to this failure.

  In arriving at this conclusion, the Commission reviewed in detail
all available data, reports and records; directed and supervised
numerous tests, analyses, and experiments by NASA, civilian
contractors and various government agencies; and then developed
specific scenarios and the range of most probable causative factors.

FINDINGS 

 1.  A combustion gas leak through the right Solid Rocket
     Motor aft field joint initiated at or shortly after ignition
     eventually weakened and/or penetrated the External Tank initiating
     vehicle structural breakup and loss of the Space Shuttle Challenger
     during STS Mission 51-L.

 2.  The evidence shows that no other STS 51-L Shuttle element or the
     payload contributed to the causes of the right Solid Rocket Motor aft
     field joint combustion gas leak.  Sabotage was not a factor.

 3.  Evidence examined in the review of Space Shuttle material,
     manufacturing, assembly, quality control, and processing on
     non-conformance reports found no flight hardware shipped to the launch
     site that fell outside the limits of Shuttle design specifications.

 4.  Launch site activities, including assembly and preparation, from
     receipt of the flight hardware to launch were generally in accord with
     established procedures and were not considered a factor in the
     accident.

 5.  Launch site records show that the right Solid Rocket Motor segments
     were assembled using approved procedures.  However, significant
     out-of-round conditions existed between the two segments joined at the
     right Solid Rocket Motor aft field joint (the joint that failed).

      a. While the assembly conditions had the potential of generating
         debris or damage that could cause O-ring seal failure, these 
         were not considered factors in this accident.

      b. The diameters of the two Solid Rocket Motor segments had grown
         as a result of prior use.

      c. The growth resulted in a condition at time of launch wherein 
         the maximum gap between the tang and clevis in the region of 
         the joint's O-rings was no more than .008 inches and the average 
         gap would have been .004 inches.

      d. With a tang-to-clevis gap of .004 inches, the O-ring in the 
         joint would be compressed to the extent that it pressed against 
         all three walls of the O-ring retaining channel.

      e. The lack of roundness of the segments was such that the smallest
         tang-to-clevis clearance occurred at the initiation of the assembly
         operation at positions of 120 degrees and 300 degrees around the
         circumference of the aft field joint.  It is uncertain if this tight
         condition and the resultant greater compression of the O-rings at
         these points persisted to the time of launch.

 6.  The ambient temperature at time of launch was 36 degrees
     Fahrenheit, or 15 degrees lower than the next coldest previous launch.

      a.  The temperature at the 300 degree position on the right aft
          field joint circumference was estimated to be 28 degrees plus
          or minus 5 degrees Fahrenheit.  This was the coldest point on the 
          joint.

      b.  Temperature on the opposite side of the right Solid Rocket
          Booster facing the sun was estimated to be about 50 degrees
          Fahrenheit.

 7.  Other joints on the left and right Solid Rocket Boosters
     experienced similar combinations of tang-to-clevis gap clearance 
     and temperature.  It is not known whether these joints experienced
     distress during the flight of 51-L.

 8.  Experimental evidence indicates that due to several effects
     associated with the Solid Rocket Booster's ignition and combustion
     pressures and associated vehicle motions, the gap between the tang and
     the clevis will open as much as .017 and .029 inches at the secondary
     and primary O-rings, respectively.

     a.  This opening begins upon ignition, reaches its maximum rate of
         opening at about 200-300 milliseconds, and is essentially complete
         at 600 milliseconds when the Solid Rocket Booster reaches its 
         operating pressure.

     b.  The External Tank and right Solid Rocket Booster are connected
         by several struts, including one at 310 degrees near the aft field
         joint that failed.  This strut's effect on the joint dynamics is to
         enhance the opening of the gap between the tang and clevis by about
         10-20 percent in the region of 300-320 degrees.

 9.  O-ring resiliency is directly related to its temperature.

     a. A warm O-ring that has been compressed will return to its
        original shape much quicker than will a cold O-ring when compression
        is relieved.  Thus, a warm O-ring will follow the opening of the
        tang-to-clevis gap.  A cold O-ring may not.

     b.  A compressed O-ring at 75 degrees Fahrenheit is five times more
         responsive in returning to its uncompressed shape than a cold O-ring
         at 30 degrees Fahrenheit.

     c.  As a result it is probable that the O-rings in the right solid
         booster aft field joint were not following the opening of the gap
         between the tang and cleavis at time of ignition.

 10.  Experiments indicate that the primary mechanism that actuates
      O-ring sealing is the application of gas pressure to the upstream
      (high-pressure) side of the O-ring as it sits in its groove or
      channel.

      a. For this pressure actuation to work most effectively, a space
         between the O-ring and its upstream channel wall should exist 
         during pressurization.

      b.  A tang-to-clevis gap of .004 inches, as probably existed in the
          failed joint, would have initially compressed the O-ring to the
          degreethat no clearance existed between the O-ring and its 
          upstream channel wall and the other two surfaces of the channel.

      c. At the cold launch temperature experienced, the O-ring would be
         very slow in returning to its normal rounded shape.  It would not
         follow the opening of the tang-to-clevis gap.  It would remain in its
         compressed position in the O-ring channel and not provide a space
         between itself and the upstream channel wall.  Thus, it is probable
         the O-ring would not be pressure actuated to seal the gap in time to
         preclude joint failure due to blow-by and erosion from hot combustion
         gases.

 11.  The sealing characteristics of the Solid Rocket Booster O-rings
      are enhanced by timely application of motor pressure.

      a.  Ideally, motor pressure should be applied to actuate the O-ring
          and seal the joint prior to significant opening of the 
          tang-to-clevis gap (100 to 200 milliseconds after motor ignition).

      b.  Experimental evidence indicates that temperature, humidity and
          other variables in the putty compound used to seal the joint can 
          delay pressure application to the joint by 500 milliseconds or more.

      c.  This delay in pressure could be a factor in initial joint
          failure.

 12.  Of 21 launches with ambient temperatures of 61 degrees Fahrenheit
      or greater, only four showed signs of O-ring thermal distress; i.e.,
      erosion or blow-by and soot.  Each of the launches below 61 degrees
      Fahrenheit resulted in one or more O-rings showing signs of thermal
      distress.

      a.  Of these improper joint sealing actions, one-half occurred in
          the aft field joints, 20 percent in the center field joints, 
          and 30 percent in the upper field joints.  The division between 
          left and right Solid Rocket Boosters was roughly equal.

      b.  Each instance of thermal O-ring distress was accompanied by a
          leak path in the insulating putty.  The leak path connects the
          rocket's combustion chamber with the O-ring region of the tang
          and clevis.  Joints that actuated without incident may also have
          had these leak paths.

 13.  There is a possibility that there was water in the clevis of the
      STS 51-L joints since water was found in the STS-9 joints during a
      destack operation after exposure to less rainfall than STS 51-L.  At
      time of launch, it was cold enough that water present in the joint
      would freeze.  Tests show that ice in the joint can inhibit proper
      secondary seal performance.

 14.  A series of puffs of smoke were observed emanating from the 51-L
      aft field joint area of the right Solid Rocket Booster between 0.678
      and 2.500 seconds after ignition of the Shuttle Solid Rocket Motors.  

      a. The puffs appeared at a frequency of about three puffs per
         second.  This roughly matches the natural structural frequency
         of the solids at lift off and is reflected in slight cyclic 
         changes of the tang-to-clevis gap opening.

      b. The puffs were seen to be moving upward along the surface of 
         the booster above the aft field joint.

      c.  The smoke was estimated to originate at a circumferential
          position of between 270 degrees and 315 degrees on the booster
          aft field joint, emerging from the top of the joint.

 15.  This smoke from the aft field joint at Shuttle lift off was the
      first sign of the failure of the Solid Rocket Booster O-ring seals on
      STS 51-L.

 16.  The leak was again clearly evident as a flame at approximately 58
      seconds into the flight.  It is possible that the leak was continuous
      but unobservable or non-existent in portions of the intervening
      period.  It is possible in either case that thrust vectoring and
      normal vehicle response to wind shear as well as planned maneuvers
      reinitiated or magnified the leakage from a degraded seal in the
      period preceding the observed flames.  The estimated position of the
      flame, centered at a point 307 degrees around the circumference of the
      aft field joint, was confirmed by the recovery of two fragments of the
      right Solid Rocket Booster.

      a.  A small leak could have been present that may have grown to
          breach the joint in flame at a time on the order of 58 to 60 seconds
          after lift off.

      b.  Alternatively, the O-ring gap could have been resealed by
          deposition of a fragile buildup of aluminum oxide and other 
          combustion debris.  This resealed section of the joint could 
          have been disturbed by thrust vectoring, Space Shuttle motion
          and flight loads inducted by changing winds aloft.

      c.  The winds aloft caused control actions in the time interval of
          32 seconds to 62 seconds into the flight that were typical of the
          largest values experienced on previous missions.

CONCLUSION

   In view of the findings, the Commission concluded that the cause of
the Challenger accident was the failure of the pressure seal in the
aft field joint of the right Solid Rocket Booster.  The failure was
due to a faulty design unacceptably sensitive to a number of factors.
These factors were the effects of temperature, physical dimensions,
the character of materials, the effects of reusability, processing and
the reaction of the joint to dynamic loading.

(Source:  The Presidential Commission on the Space Shuttle Challenger
Accident Report, June 6, 1986 p.40, p.70-81)