Quality control facilities for large optical reflectors at ENEA-Casaccia for physics application
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Quality control facilities for large optical reflectors at ENEA-Casaccia for physics application Stefania Baccaro a,d , Carlo Bosio b,d , Augusto Maccari c , Marco Montecchi a,d a) ENEA FIS-ION, Casaccia, Roma, Italy b) Dipartimento di Fisica Università La Sapienza, Roma, Italy c) ENEA SOLTERM, Casaccia, Roma, Italy d ) INFN – Sezione di Roma1, Roma, Italy
description
Quality control facilities for large optical reflectors at ENEA-Casaccia for physics application. Stefania Baccaro a,d , Carlo Bosio b,d , Augusto Maccari c , Marco Montecchi a,d a) ENEA FIS-ION, Casaccia, Roma, Italy b) Dipartimento di Fisica Università La Sapienza , Roma, Italy - PowerPoint PPT Presentation
Transcript of Quality control facilities for large optical reflectors at ENEA-Casaccia for physics application
Quality control facilities for large optical reflectors at ENEA-
Casaccia for physics application
Stefania Baccaro a,d, Carlo Bosio b,d, Augusto Maccari c, Marco Montecchi a,d
a) ENEA FIS-ION, Casaccia, Roma, Italyb) Dipartimento di Fisica Università La Sapienza, Roma, Italy
c) ENEA SOLTERM, Casaccia, Roma, Italyd ) INFN – Sezione di Roma1, Roma, Italy
Large optical reflectors are used in…
• Astronomy: in telescope (imaging)
• High Energy Physics: in RICH, to focus Cherenkov radiations on optical sensor (quasi-imaging)
• ……
• Solar Energy: as sun-power collectors (collecting)
… for information completeness
• How large? Single panel, up to some meters
• Imaging use is much more demanding than collecting one
• Composition and shape are designed for the specific application and .....
... HAVE TO BE TESTED !!!
Irradiation plants at ENEA – Casaccia
• TAPIRO: fast neutrons• TRIGA: thermal neutrons• CALLIOPE: 1.17 and 1.33 MeV
Optical laboratory tender to Calliope: spectrophotometers and spectrometer Light-Yield damped optical top with light sources, lenses,
mirrors, detectors, etc.. custom set-up
Optical tests at ENEA-Casaccia
spectrophotometer – specular and diffused (small flat sample)
spectrometer – specular (full scale reflector)
2f optical test focal length and image spot dimension
pin-hole optical test visual inspection of the curvature
profilometer accurate measurement of the curvature
Shape performances:
Reflectance:
2f optical test:focal length and image-spot dimension
2 f
screen
image
LED ( = 5 mm)
in the ideal case, image and source have the same dimension
Pin-hole optical test:a visual inspection of the curvature
where the surface image is dark, the curvature is wrong
surfaceimage
2 f
LED
pin-hole f1
p q
LHCb RICH mock-up: carbon fiber + honeycomb
~ 600 mm 2f = 1700 20 mm
image spot ~ 15 mm
LHCb mock-up : polymethylmethacrylate (PMMA) hot bended and honeycomb
~ 400 mm 2f = 2370 20 mm
image spot ~ 25 mm
LHCb RICH mock-up:PMMA poured liquid on master
~ 350 mm 2f = 2330 20 mm
LHCb mock-up: electrodeposited Ni
= 200 mm 2f = 315 5 mm
Accurate test of the reflector curvature: profilometer
In the framework of the Concentrating Solar Power Project, ENEA is providing with an optical profilometer to test large linear parabolic reflectors
the measurement is automatic - PC controlled
the profilometer can be used also for reflectors differently shaped (e.g. spherical reflector)
actually the instrument performs 1D scanning
2D upgrade is imminent
ENEA optical profilometer (1D)
x
HeNe
screen
y
x0xS(xC,yC)
yS
Nikon D1X, 4.024 x 1.324 px
rotation axis
• the surface is scanned by tilting the incident beam () with a high precision rotation stage (20 rad repeatability)
• the intersection of the reflected beam with the screen (XS) is deduced by processing the digital image
Data processing – 1th method: fit
N
j S
jSS
M xErr
xxppMF
1
2expsim
1,..,
x
y
x0xS simulated
xS experimental
yS
y = f (x,p1,..,pM)
y = tg() (x - x0)
best fit by minimising
Data processing - 2nd method:iterative extrapolation (I.E.)
the next point P2 is: along the incident beam, by definition in AB, if 1; P1C, P2C P1P2
univocally determined by assuming:
yS
central point ( = 90°):
(xc,yc) directly measured
set dy/dx = 0 by tilting
x
y
x0
AB
P1
P2
C
P1
P2
C
circular:P1C =CP2
P1
P2
x1 x2xC
y = x2 parabolic:
xC = (x1+x2)/2
Example: reduced scale linear parabolic reflector (aperture 0.6 m)
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32
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52
rotational measurement
XS (
cm)
(deg)
experimental best fit of 32/49 data
best fit parameters:
2 = 1.23 (32/49 data)
P4 = 0.32 0.04
= 11.3 0.8 deg
f = 185.5 0.5 mm
22
424 22)1(
4 ffP
f
P
high precision
comparison of the two methods
I.E. method gives a realistic profile of the reflector
I.E. method allows to evaluate the locale deviations from the project specifications of both profile and slope
-20 -10 0 10 20
-9
-8
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-4
-3
-2
-1
0
1profile
Y (
cm)
X (cm)
best fit extrapolation
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-30
-20
-10
0
10
20
30
40slope
atan
(dY
/dx)
(de
g)X (cm)
best fit extrapolation
validation of the iterative extrapolation method
direct measurement
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-0.5
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
profile deviation from circle r = 376mm
rad
ial d
evi
atio
ns
(mm
)
X (cm)
comparator iterative extrapolation
comparator
rotation stage
harm
reflector
Conclusions
The ENEA-Casaccia facilities allow to measure the most important features of large optical reflectors:
specular and hemispherical reflectance focal length surface profile
2D upgrade of the profilometer is imminent
