MSL Public Affairs Status Report #6
8:00 a.m. CDT, July 4, 1997
MET 02/16:58
Spacelab Mission Operations Control
Marshall Space Flight Center

Through the evening and into the morning on Friday, Space 
Shuttle crew members and ground controllers worked together 
to complete a variety of experiments and resolve some of the 
challenges associated with keeping a complex science payload 
up and running.  The Microgravity Science Laboratory consists 
of more than 30 experiments in the primary areas of 
combustion, biotechnology, materials science and fluid 
physics.  

"Great teamwork by the orbiter crew and science teams on the 
ground has worked around some anomalies enabling us to 
collect very valuable science data" said Dr. Patton Downey, 
assistant mission scientist.

Aboard Columbia, runs of the Droplet Combustion Experiment 
were slightly delayed while troubleshooting teams 
investigated a suspected correlation between three brief 
malfunctions of the computer which oversees all the 
experiments aboard Spacelab.  Within minutes of each 
malfunction, the crew was able to reboot the computer with no 
impact to science. 

Meanwhile, Payload Commander Dr. Janice Voss performed 
another run of the soot experiment in the Combustion Module -
1 that had originally been slated for Payload Specialist Dr. 
Roger Crouch.  Shifting the schedule allowed Crouch to 
perform the Internal Flows in a Free Drop experiment that had 
been scheduled for a later time.

Crouch began the experiment in which free drops of liquid are 
deployed and manipulated in the Glovebox using sound waves.  
Attempts to deploy the drops were, however,  unsuccessful.  
The science team on the ground suspects that a change in the 
alignment of the liquid injector may have been the cause of 
the unsuccessful drop deployment and is troubleshooting the 
problem.

Before the end of his shift, Crouch performed a sample 
exchange in the Large Isothermal Furnace, initiating the 
second run of the Liquid Phase Sintering experiment, which is 
led by Dr. Randall German of Pennsylvania State University in 
University Park, Pa.   

In industry, the liquid phase sintering process is used to 
form very hard and dense solids -- which, in turn, are used 
to manufacture products such as cutting tools, car 
transmission gears and radiation shields.  The sintering 
process involves heating metal or ceramic powders.  Under 
high pressure and temperature, the powder grains liquefy and 
bond to form strong shapes, such as tools.  On Earth, gravity 
affects the dispersal of the powders and causes the resulting 
solid to be less uniform.  Investigators hope to better 
understand this process and develop techniques that can be 
used to lower costs of production and create even better 
sintered materials.

In the electromagnetic processing facility known as TEMPUS, 
an experiment to further the understanding of the 
fundamentals of undercooling and formation of metallic glass 
was initiated around 10:00 p.m. (CDT)  Thursday.  The 
facility uses a combination of an electromagnetic field and 
the microgravity environment to suspend metal alloys in a 
free space within a set of coils.  Within the coils, the 
suspended alloy  may be melted and resolidified in an ultra-
pure environment.  The sample of zirconium-nickel was cycled 
through two stable melting and solidification runs, then 
became molten and contacted the side of the sample container, 
adhering there.  The experiment run was then terminated and 
the sample was removed.

"Before the sample stuck to the coils, we were able to get 
some good data", said the principal investigator, Dr. Hans 
Fecht of the Technical University in Berlin, Germany.  The 
experiment team is evaluating data concerning the unexpected 
contact and sticking.  The next TEMPUS experiment run is 
scheduled for later this afternoon.

Before the handover from the on-board blue shift science crew 
to the red shift, teams on the ground determined that the 
apparent cause of earlier glitches with the Experiment 
Control Computer System was data transmission from the 
Droplet Combustion Experiment.  Transmission of this data was 
disabled and the droplet combustion team -- commanding the 
experiment from the ground -- resumed the combustion 
investigation which resulted in several "good burns",
according to researchers.

Voss and Crouch handed off to Mission Specialist Dr. Donald 
Thomas and Payload Specialist Dr. Gregory Linteris around 
1:00 a.m. (CDT).

After his daily planning session, Payload Specialist Dr. Greg 
Linteris began the first of several runs of the Droplet 
Combustion Experiment.  The experiment takes place in a 
specially designed enclosed chamber in which single droplets 
of heptane fuel can be burned in an atmosphere composed of a 
mixture of helium and oxygen.  The droplet is formed by 
injecting heptane through two injectors on opposite sides of 
the test platform within the chamber.  Once the drop is 
formed, the injectors are retracted and the drop is then 
ignited by two hot-wire igniters that are brought near the 
droplet from opposite sides.  The burning droplets observed 
and recorded using video cameras and high-resolution 
photographs.  The investigators will study these recordings 
to obtain data about the physical and chemical processes that 
take place in droplet combustion, including conditions under 
which the flames extinguish, the chemistry of the combustion 
reaction, and the production of pollutants such as nitrogen 
oxides and soot particles.

 "We can't get this information from ground-based 
experiments", said principal investigator Dr. Forman Williams 
of the University of California at San Diego.  "For the first 
time, we're burning free fuel droplets".  Findings' from this 
investigation are providing researchers with a better 
understanding of the combustion process and may lead to 
cleaner and safer ways to burn fossil fuels as well as more 
efficient methods of generating heat and power on Earth.

Around 3:45 a.m. (CDT) Friday, Thomas set up another 
combustion study led by Williams --the Fiber Supported 
Droplet Combustion investigation.  During the experiment, 
single large droplets of fuel are ignited to study how fuel 
burns and test a new technique of droplet deployment using 
thin fiber material.

To burn large fuel droplets -- even in the near-weightless 
environment of space -- it is necessary to have a support 
mechanism for the drops of fuel.  Otherwise the burning drop 
may move around, hit the walls of the container or move out 
of the camera's field of view.  

The Fiber Supported Droplet Combustion experiment allows 
combustion investigators to study the burning of fuels -- 
such as n-heptane, n-decane, methanol, ethanol, 
methanol/water mixtures and heptane/hexadecane mixtures -- in 
droplets as large as nearly one-quarter-inch diameter.  
Additionally, the experiment will shed light on the role that 
convection plays in burning by introducing a controlled air-
flow into the flame environment during the experiment.

As the red shift crew continues its 12-hour duty day, Thomas 
and Linteris will perform further combustion studies aboard 
Columbia -- including runs of the Fiber Supported Droplet 
Combustion Experiment and the Droplet Combustion Experiment.

The next scheduled Public Affairs status report will 
be issued at approximately 6 a.m., July 5.

For more information call the Spacelab Newscenter at Marshall 
Space Flight Center at (205) 544-6535 or visit our web sites. 
For Spacelab payload information: 
http://liftoff.msfc.nasa.gov/shuttle/msl and for science 
information: http://www.ssl.msfc.nasa.gov/msl1/msl1hframe.htm