Upgrade of the LARES-lab Remote Controllable Thermo-vacuum
Facility
Lab Improvements for Remote Testing and e-Learning
Claudio Paris
1, 2
and Giampiero Sindoni
2
1
Museo Storico della Fisica e Centro Studi e Ricerche Enrico Fermi, Via Panisperna 89/a, 00184, Rome, Italy
2
Scuola di Ingegneria Aerospaziale, Sapienza University of Rome, Via Salaria 851, 00138, Rome, Italy
Keywords:
Thermo-vacuum Testing, Space Simulator, Remote Lab, e-Learning, LARES.
Abstract:
The LARES-lab facility was specifically designed to perform tests in simulated space environment on the
optical payload of the LAser RElativity Satellite (LARES). Since the facility was intended to perform de-
manding tests, it was equipped with the best technology available at the time. After the launch of LARES the
facility was used both for testing payloads and small university satellites and for didactic activities. Testing
in simulated space environment is fundamental for the development of a space mission, so a well equipped
facility in a university is a precious resource for teaching. At the moment, room dimension and the location
limit the access to the lab to a small number of students per lesson. To fully exploit the didactic potential of
the LARES-lab an improvement over the remote control operation of the thermo-vacuum chamber is planned.
The project, which has been described in a previous paper, is currently under development. A new device
implemented is a robotic arm to manipulate some mechanisms and to gain experience for remote controlling
other servo mechanisms. This way both researchers and students can operate the facility remotely with mini-
mal need of on site operations. Once the improvements will be fully operational, LARES-lab will allow access
to the laboratory didactic activities to a much larger number of students.
1 INTRODUCTION
LARES-lab facility was designed for performing tests
on the optical payload of the LAser RElativity Satel-
lite (LARES) (Paolozzi et al., 2012a; Paolozzi et al.,
2012b). LARES mission was supported and funded
by the Italian Space Agency (ASI) (Paolozzi et al.,
2011), while the European Space Agency (ESA) pro-
vided the launch with the maiden flight of the new
launcher VEGA (Paolozzi and Ciufolini, 2013). The
goal of the mission is the precise measurement of
frame-dragging (Ciufolini et al., 2012b), predicted by
General Relativity, improving the previous 10% accu-
racy obtained with data from LAGEOS and LAGEOS
2 satellites (Ciufolini and Pavlis, 2004; Ries et al.,
2011). The LAGEOS satellites are two passive spher-
ical spacecrafts tracked by the ground stations of the
International Laser Ranging Service (ILRS )(Pearl-
man et al., 2002) by means of the laser retroreflec-
tors mounted on the satellites. The addition of data
from LARES is expected to bring the accuracy to-
ward 1% (Ciufolini et al., 2013; Ciufolini et al.,
2012a). To reach that precision the spacecraft was
designed for reducing the non-gravitational perturba-
tions by means of a very high mass-to-surface ratio
(Paolozzi et al., 2015a). The particular material cho-
sen for obtaining a high density satellite, a tungsten
alloy, was challenging for manufacturing (Paolozzi
et al., 2009; Paolozzi et al., 2012c) and for modelling
the surface thermal-optical properties. Thermal test-
ing was needed for verifying that the laser retrore-
flectors could work on a wide range of temperatures,
and in particular at the very high temperatures ex-
pected because of the optical properties of the bare
tungsten alloy (Paolozzi et al., 2010; Paolozzi et al.,
2012b). Indeed, even if higher temperature increases
the thermal thrust (Bosco et al., 2007; Ciufolini et al.,
2014), a passive thermal control by painting the satel-
lite body could have been even more dangerous for
the results because the thermo-optical properties of
the coatings were expected to change dramatically
during the operational life of LARES (Marco et al.,
2003; Pippin, 1995; Jaggers et al., 1993). Tests of
the LARES retroreflectors mounted in uncoated tung-
sten alloy breadboards were successfull and quali-
fied the final design. After the launch, the ILRS
Paris, C. and Sindoni, G.
Upgrade of the LARES-lab Remote Controllable Thermo-vacuum Facility - Lab Improvements for Remote Testing and e-Learning.
In Proceedings of the 8th International Conference on Computer Supported Education (CSEDU 2016) - Volume 2, pages 347-352
ISBN: 978-989-758-179-3
Copyright
c
2016 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
347
ground stations are receiving good reflected signals
from LARES, which demonstrates to be one of the
best laser ranging targets and the best test particle for
studying the gravitational field of the Earth (Pavlis
et al., 2015a). LARES is also a useful addition to the
constellation of geodetic satellites for environmental
monitoring (Pavlis et al., 2015b). Once the satellite
was sent in orbit, the LARES-lab was used for fur-
ther measurements on the retroreflectors of LARES
and of other laser ranged spacecrafts (Paris and Neu-
bert, 2015). Because of the small dimensions, low
cost operation and the wide equipment of LARES-
lab, it is particularly suited for testing small pay-
loads ( Di Roberto et al., 2015a; Di Roberto et al.,
2015b) and microsatellites (Paris et al., 2015a; Paris
et al., 2015b). The tests sometimes require long du-
ration, for example when performing thermal cycling
in vacuum; when needed it was possible a basic re-
mote control of the tests (mainly to check the tem-
peratures), but the presence of at least one operator
was still needed. Furthermore the presence of a well
equipped space environment simulation facility in a
university is a great opportunity for teaching. How-
ever the limited space in the lab does not allow to ac-
commodate more than very few students at a time.
Also, sometimes the didactic activities needs to be
planned according to the time schedule of the uni-
versity courses to allow the students to participate.
Nevertheless the experience with university courses
that are using LARES-lab for lessons and seminars
showed a good appreciation both from professors and
students, and a good potential for increasing the di-
dactic activities. Therefore turning LARES-lab into
a remote controllable lab will be useful both for test-
ing and for teaching. However the two fields require
different capabilities. Indeed while it is acceptable
for a remote operator to have full access to the lab
equipment for a test, safety reasons require to limit the
access privileges for students. Feasibility of remote
labs for e-learning and teaching have been demon-
strated by a number of experiences worldwide (Casini
et al., 2001; Gustavsson, 2003; Aliane et al., 2007;
Eslami et al., 2008; May et al., 2013), however no
project based on thermo-vacuum testing was found in
the literature. The upgade of LARES-lab has been al-
ready discussed on a previous paper (Paolozzi et al.,
2015b); in the meanwhile some upgrades described in
the 2015 paper have been discarded or changed. In the
next sections the state of the project and the changes
made will be discussed.
2 SHORT DESCRIPTION OF
LARES-LAB
LARES-lab was designed with the goal of performing
optical tests in simulated space environment accord-
ing to the standard requirements of ESA for space
testing (ECSS, 2012; ECSS, 2002). The items to
be tested are put in a cubic vacuum chamber, where
the pressure can be maintained below 10
−6
mbar by
two pumps. The first is a dry scroll pump (Ed-
wards XDS5) that brings the pressure below 2 mbar,
that is the limit required to start the turbomolecu-
lar pump (Edwards EXT255DX). The turbomolecu-
lar pump brings the pressure to the operational value.
The time to reach the ultimate pressure depends on
the volume and the materials of the item under test:
large surfaces and materials which have not been de-
gassed before the test need more time to reach the
ultimate pressure. A pressure gauge allow to mon-
itor pressure inside the chamber and is used to de-
cide when starting the turbomolecular pump. The tur-
bomolecular pump and the pressure gauge are con-
nected to a controller (Edwards TIC Instrument Con-
troller), which is connected to a personal computer.
A software (TIC PC monitor) is installed on the PC
for monitoring the pressure and the pump parameters.
The TIC PC monitor allows also to switch on and off
the turbomolecular pump. The dry pump, instead, is
not controlled by the TIC Instrument Controller. Fig-
ure 1 shows the vacuum chamber and some compo-
nents discussed in the paper. The vacuum chamber is
cubic. The length of the internal edge is 60 cm but
the presence of a cooling shroud on five walls short-
ens the length to about 55 cm. The cooling shroud is
composed of five copper plates cooled by an open cir-
cuit liquid nitrogen coil. Liquid nitrogen is fed from a
pressurized container. Temperatures down to -192 °C
can be reached when the liquid nitrogen valve is fully
open; partly closing and fine tuning the valve allows
to set the temperature to a higher value. To simulate
the heath exchange toward a black body, the shroud
is painted with Aeroglaze Z307, a vacuum compati-
ble black paint having high absorbivity and emissivity
(ε = 0.89, α = 0.97) (Persky, 1999). Sun and Earth
radiation are simulated by means of a Sun simula-
tor with AM0 spectrum and a Earth infrared radiation
simulator disk. The Sun simulator lamp projects a
beam with AM0 spectrum and a constant power over
a 12x12 cm surface. The lamp is positioned outside
the chamber, and the light enters through a fused sil-
ica window with low absorption also in the ultraviolet
portion of the spectrum. The Earth infrared simula-
tor disk is positioned inside the chamber; temperature
on the disk is controlled by resistive heathers and set
CSEDU 2016 - 8th International Conference on Computer Supported Education
348
Figure 1: LARES-lab vacuum chamber. 1: turbomolecular pump; 2: pressure gauge; 3: TIC Instrument Controller; 4: liquid
nitrogen pipes; 5: electrical feed-throughs with multi-pin connectors; 6: inspection window.
to -18 °C , that is the blackbody equivalent tempera-
ture of Earth (Macdonald and Badescu, 2014). Resis-
tive heathers are used for additional thermal inputs.
The temperatures are recorded by platinum resistance
thermometers PT100. Two monitoring systems, a
HBM MGC-plus modular data logger and a PicoTech
PT104, allow to record data from up to 12 PT100
sensors (8 by the MGC-Plus and 4 by the PT104).
The same PC that controls the TIC Instrument Con-
troller also controls both the monitoring systems at
the same time. Three multi-pin feed-throughs (two
25-pins connectors and one 9-pin connector) provide
electrical contact with sensors, heathers and instru-
ments inside the chamber. A programmable power
supply is used to feed the heathers. Specimen under
test can be rotated by a one-degree-of-freedom ma-
nipulator. Optical testing in vacuum is possible by
means of a high quality optical window with a very
accurate surface finish (lambda/20 peak to valley at
632.8 nm).
3 REMOTE CONTROL OF
LARES-LAB
A Virtual Network Computing system (VNC) in-
stalled on the laboratory PC, allows simple control
of the turbomolecular pump and recording the tem-
peratures. We have tried different open source and
freeware software to find the best solution for re-
mote control. For testing, any VNC is adequate but
for e-learning more control is needed over the stu-
dents privilege. We are still experimenting with Team
Viewer remote access software to configure safe ac-
cess to the lab. In the meanwhile, we are testing a sim-
pler configuration for providing remote access during
a lesson to a room of students under the supervision
of a teacher.
4 UPGRADES OF LARES-LAB
In this section the upgrade with respect to what pro-
posed in (Paolozzi et al., 2015b) is described.
Upgrade of the LARES-lab Remote Controllable Thermo-vacuum Facility - Lab Improvements for Remote Testing and e-Learning
349
4.1 Dry Pump Control
The dry pump is not controlled by the TIC Instru-
ment Controller. The electric switch on the pump re-
mains in the ”on” or ”off” position when manually
operated. To have the possibility to remotely con-
trol the dry pump it is necessary to leave the switch
in the ”ON” position, then a single-board microcon-
troller (Arduino Uno) with AC 220 V relay module
controlled by the lab PC can be used to close or open
the power circuit of the pump.
4.2 Lights and Webcam
A strip of LED lights illuminates the vacuum cham-
ber. A webcam positioned on the door inspection win-
dow will show to the classroom the experiment inside
the vacuum chamber.
4.3 Robotic Arm and Manipulator
A small six degree-of-freedom robotic arm was pur-
chased for didactic activities and to gain experience
about servo-mechanism controls. The arm is con-
trolled by a 6 channel Pololu Micro Maestro con-
troller (Figure 2). The controller is connected with
a USB cable to the PC and can be remotely controlled
by the VNC system. In the previous paper we de-
scribed the planned remote operation of the manipu-
lator using a stepper motor coupled to the manipula-
tor drive; here we propose instead the use of a robotic
arm. The manipulator drive has several screw holes
that can be used to mount knobs. A simple knob has
been screwed on the drive and allows to move the ma-
nipulator using the robotic arm (Figure 3).
A second robotic arm to be mounted inside the
chamber is under study. The major difficulty being to
find a device that can operate under vacuum.
4.4 Sun Simulator Screen
Another change to the previous plan regards the sys-
tem to cut the Sun beam. Initially we proposed a
sliding screen operated by a stepper motor. Learn-
ing from the experience gained with the robotic arm,
a more cost effective solution will be using a ser-
vomechanism operated by a second Pololu Micro
Maestro controller to move a smaller screen in front
of the Sun window. Using the same components and
control software for both the robotic arm and the Sun
screen allows an easier integration of the subsystems
on the remote controlled architecture.
Figure 2: The 6 channel controller for servomechanisms
(Pololu Micro Maestro). The controller is connected with
a USB cable to the lab PC.
Figure 3: The 6 degrees-of-freedom robotic arm operating
the manipulator drive using a simple knob. A better knob
will be created and mounted soon.
5 CONCLUSIONS
LARES-lab space environment simulation facility
was created for testing satellite components. Since
it is a university facility it is an important resource for
teaching. For fully exploiting the didactic potential of
LARES-lab, an upgrade of the facility for creating a
remote controlled testing and teaching platform is un-
der development. The plan presented in the 2015 pa-
per has been modified and some systems have been al-
ready installed and tested, including a robotic arm for
moving the manipulator and for gaining experience
for other remote controlled systems based on servo-
mechanisms. Further improvements are under study,
including the use of a second robotic arm inside the
chamber. Once the improved lab will be fully opera-
tional, the number of students that would have access
to the didactic experiments will be much increased.
CSEDU 2016 - 8th International Conference on Computer Supported Education
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