Journal of large-scale research facilities, 2, A86 (2016) http://dx.doi.org/10.17815/jlsrf-2-139

Published: 17.08.2016

STG-CT: High-vacuum plume test facility for
chemical thrusters

Deutsches Zentrum für Luft- und Raumfahrt,
Institute for Aerodynamics and Flow Technology *

Instrument Scientists:
- Martin Grabe, Deutsches Zentrum für Luft- und Raumfahrt (DLR),

Institute for Aerodynamics and Flow Technology, Göttingen, Germany,
phone: +49(0) 551 709 2476, email: martin.grabe@dlr.de

Abstract: The STG-CT, operated by the DLR Institute for Aerodynamics and Flow Technology in Göt-
tingen, is a vacuum facility speci�cally designed to provide and maintain a space-like vacuum environ-
ment for researching plume �ow and plume impingement from satellite reaction control thrusters. Its
unique liquid-helium driven cryopump of 30 m2 allows maintaining a background pressure < 10−5 mbar
even when molecular hydrogen is a plume constituent.

1 Introduction

Space vehicles may control their attitude in orbit by means of a number of reaction control thrusters.
These typically operate by expanding a gas through a convergent-divergent nozzle, thus converting
internal into kinetic energy. Thrust is produced by expelling a rather high mass �ow (on the order of
grams per second) of gas at a rather low velocity (on the order of a kilometer per second). This type
of reaction control thrusters shall be referred to as chemical thrusters to discern them from electric
propulsion devices.
The plume emanating from a reaction control thruster into high vacuum expands well into the half-
space upstream of the nozzle exit plane and invariably impinges on adjacent spacecraft surfaces. It is
thus a source for contamination, parasitic forces and moments, and heat load. The latter two impinge-
ment e�ects are discussed in a review article by Dettle� (1991). Whether or not they are of relevant
magnitude to require special attention in the design or operation of a space vehicle is typically decided
by means of engineering models of the plume expansion and interaction. These plume and impinge-
ment models may be derived from experiments. Experiments become mandatory when the necessarily
simplifying engineering models are expected to not capture the impingement e�ects with su�cient

*Cite article as: DLR Institute for Aerodynamics and Flow Technology. (2016). STG-CT: High-vacuum plume test facility
for chemical thrusters. Journal of large-scale research facilities, 2, A86. http://dx.doi.org/10.17815/jlsrf-2-139

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accuracy or when the applicability of the model is not known.
Ground-based investigation of free plume expansion requires a vacuum facility able to maintain a suf-
�ciently low background pressure even during thruster operation. The STG-CT is speci�cally designed
to provide and maintain a space-like vacuum environment for researching plume �ow and plume im-
pingement from satellite reaction control thrusters, cf. Dettle� & Plähn (1997) and Dettle� & Plähn
(1999), but may serve in other applications as well.

2 Operation Principle

Figure 1: View into the test section.

The essential feature of STG-CT is a liquid helium-driven cryopump with an area of about 30 m2 that
almost completely encloses the test section, Fig. 1. In the ribbed pipes of the cryowall helium is kept
in a boiling state at a pressure of about 1 bar, thus maintaining a wall temperature of about 4.2 K. At
this temperature most technical gases (with the exception of hydrogen and helium itself ) have a vapor
pressure orders of magnitude lower than 10−10 mbar and are thus condensing to the cryowall. With
hydrogen gas present in the test section a pressure less than 10−5 mbar can be obtained by cryopumping.
As long as the cryowall temperature is kept low enough to condense the most volatile gas species
under investigation, mass �ow rates of the order of grams per second are permissible inside the test
section without a signi�cant increase in background pressure. The factor limiting the achievable level
of background pressure thus is the energy �ux imposed upon the cryowall and its cooling agent. By
design, the cryopump can withstand a continuous heat load of about 500 W (short-duration peak: about
25 kW) and still maintain a wall temperature of 4.2 K.

3 Technical Description

3.1 Construction

The test section is a cylindrical room of 10 m3 with a length of 5.25 m and a diameter of 1.6 m, enclosed
by the cryowall manufactured from highly heat-conducting copper (Fig.1). The outer vacuum vessel
(62.2 m3) is made from stainless steel. A multi-layer insulation (MLI) protected sheet metal layer and a
liquid nitrogen cooled surface fully enclose the inner cryopump and shield it from thermal radiation.

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http://dx.doi.org/10.17815/jlsrf-2-139 Journal of large-scale research facilities, 2, A86 (2016)

Figure 2: Front and side view of the STG-CT vacuum chamber, displaying the front face of the copper-
walled test section with access door closed.

While the liquid nitrogen (pre-)cooling system is open, STG-CT is connected to a closed helium cycle.
Liquid helium is stored in a cryogenic storage dewar designed to hold about 3 m3. From there it is
pressure-fed to the cryopump, where it evaporates. The cold gaseous helium passes a sequence of
electric heaters before it is compressed for storage in pressure cylinders. A liquefaction machine �lls
the dewar tank from the gas storage at a rate of about 20 l/h.

3.2 Access to the test section

For physical access to the test section one front face of the cryopump is equipped with a hinged door
345 mm wide and 700 mm high. These dimensions limit the size of individual pieces of the test setup,
but the test section is large enough for a person to climb inside and conduct the �nal assembly there.
A venting system is installed to supply fresh air to the test section during assembly.

Nom. diameter Flange system Quantity

DN50 ISO-KF 28
DN100 ISO-K 24
DN250 ISO-K 4
DN500 ISO-K 2
DN630 ISO-F 2

Table 1: Available �ange connections.

The outer stainless steel vacuum vessel is equipped with a number of �ange connections distributed
over the surface. Table 1 lists the available �anges. Fittings to other �ange systems and diameters are
available or may be manufactured.
Direct mechanical and optical access is limited by the coldwalls surrounding the test section. The half-
shells of the coldwalls are spaced about 30 mm, admitting a narrow-angled �eld of view in the vertical
plane parallel to the principal axis of the test section, cf. Fig.1.

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3.3 Test Cycle

Phase Description Duration

Evacuation The vacuum vessel is closed and evacuated by
means of a mechanical pump line (from high to low
inlet pressure):

• Leybold VAROVAC®S 630 F (rotary vane)
• Leybold RUVAC®WAU 1000 (roots blower)
• Leybold RUVAC®RA 3001 (roots blower)
• Pfei�er TPH 1500 (turbomolecular pump)

to a pressure of about 10−3 mbar.

5 h

LN2 cooling Pre-cooling of the cryopump, cooling of the radia-
tion shield to a temperature of 78 K. Pressure in the
test section drops to about 10−5 mbar.

48 h

LHe cooling Cooling of the cryopump to 4.2 K. Pressure in the
test section drops to about 10−10 mbar.

6 h

Experiment Duration depends on heat load on cryopump and
amount of liquid helium available.

4...8 h

Warm-up & venting Slow radiation-driven warming required to miti-
gate thermal stresses.

170 h

Liquefaction May run in parallel to the warm-up phase. 150 h

Table 2: Phases of a typical test run in STG-CT.

Table 2 summarizes the sequential phases of a typical test run in STG-CT along with the approximate
time frame for each phase. It is apparent that the cooling and warming stages limit the minimum
turnaround time of the facility to about ten days per test run. The warming step may be shortened in
between two consecutive runs if no changes are required to the experimental setup in the test section,
but only to as much time as is required to reliquefy the gaseous helium.

4 Equipment

4.1 Actuators

STG-CT is equipped by default with two linear actuators, mounted above and below the cryopump,
that run parallel to the principal axis and over the entire length of the test section. Each linear motor
carries a rotary stage from which a cylindrical rod (∅28 mm) extends into the test section. The rods
serve as mounting points for lightweight measurement devices.

4.2 Chamber Instrumentation

The copper surfaces of the cryopump are equipped at various locations with C10 resistance thermome-
ters to monitor the temperature in the range 4 K...20 K. A selection of these temperature measure-
ments can be made available to the data acquisition system of the experiment. The background gas
pressure is typically monitored by hot cathode ionization gauges (HP and Bayard-Alpert).

4.3 Sensors and Probes

Which particular sensors and probes are put to use in STG-CT of course depends largely on the purpose
of the experiment and the object under investigation. Table 3 thus list only exemplarily a number of

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Name Description

Thermocouples Ni-CrNi or PtRh types.
Pressure transducers Various types:

• capacitive,
• ionizing,
• piezo-resistive.

Pitot-probe Measure total pressure (behind normal shock) in
hypersonic plumes.

Patterson-probe Measure particle �ux.
Electrostatic probes Detect electrically charged droplets in bipropellant

thruster plumes.
Photo diodes Signal light emission e. g. from combustion cham-

ber; also serve as receiver for droplet detection in
laser beam attenuation experiments.

Witness plates Simulate spacecraft surface in contamination ex-
periments.

Quartz crystal microbalance (QCM) Quantitative molecular contamination analysis.

Table 3: Some measurement devices employed in plume research.

measurement devices previously employed in reseaching thruster plume expansion. For details regard-
ing these techniques and their application refer to Dettle� & Grabe (2011).

5 Application

Examples of use cases STG-CT is particularly suited for:
• Contamination analysis with bipropellant attitude control thrusters of the 10 N-class,
• Realistic molecular contamination of surface samples,
• Investigation of material degradation through plume impingement,
• Investigation of material outgassing,
• Characterization of hot- and cold-gas thruster plumes,
• Characterization plume interference with adjacent surfaces or other plumes,
• Simulation of cold space environment,
• Functional tests of low-energy electric propulsion devices.

References

Dettle�, G. (1991). Plume �ow and plume impingement in space technology. Progress in Aerospace
Sciences, 28(1), 1 - 71. http://dx.doi.org/10.1016/0376-0421(91)90008-R

Dettle�, G., & Grabe, M. (2011). Basics of plume impingement analysis for small chemical and cold gas
thrusters. In Models and computational methods for rare�ed �ows (chap. 12). von Karman Institute,
Rhode St. Genèse, Belgium: RTO/NATO. (RTO AVT/VKI Lecture Series)

Dettle�, G., & Plähn, K. (1997). Initial experimental results from the new DLR-high vacuum plume test
facility STG. In 33rd joint propulsion conference and exhibit. Seattle.

Dettle�, G., & Plähn, K. (1999). Experimental investigation of fully expanding free jets and plumes. In
Rare�ed Gas Dynamics, Proceedings of the 21st International Symposium on Rare�ed Gas Dynamics,
Vol. 1 (p. 607 - 614).

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	Introduction
	Operation Principle
	Technical Description
	Construction
	Access to the test section
	Test Cycle

	Equipment
	Actuators
	Chamber Instrumentation
	Sensors and Probes

	Application