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220l+.20l6 828{j
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Yüksek Teknoloji Üniversite Sanayi
İşbirliği İmkAnları (ESS Projeleri)
Küreselleşen Dünyamızda ülkelerin artık birbirinden tümüyle bağımsız birimler olarak hareket etme imk6nı
oıtadan kalkmış, ekonomik, teknolojik, araştırma -geliştirme, sosyal ve kültürel konular başta olmak üzere
her alanda birbiriyle koordinasyon ve işbirliği halinde bulunulması bir zorunluluk haline gelmiştir.
Ülkemizin kalkınma hedefleri arasında, orta gelir gurubu bir ülke olmaktan çıkarak yüksek gelir gurubu ülkeler
arasına katılma hedefi bulunmaktadır. Bu da ancak yüksek teknoloji ürünler üreterek, bu konulardaki
teknolojiyi yurdumuza transfer ederek ve bu konuda yüksek nitelikli eğitim vererek ulaşılabilecek bir hedeftir.
Bu amaçla İsviçre'de yer a|an CERN'in ihtiyaç duyduğu ileri teknoloji de içeren ürünlerin ihracatını
gerçekleştirebilmek için TOBB bünyesinde bir Türkiye Sanayi İrribat Ofisi kurularak faaliyete geçmiş olup
ihalelere teklif verilmesine teknik destek sağlanmış ve ilk ihalemiz kazanı|arak bu ileri teknoloji projede
Türkiye olarak yer almamz sağlanmıştır.
Şimdi benzer bir imkAn İsveç'in Lund şehrinde kurulmakta olan European Spallation Source (ESS) için
mevcuttur.
20l5 yılında Avrupa Komisyonu tarafindan Avrupa Araştırma Altyapıları Konsorsiyumu (European Research
Infrastructure Consortium - ERIC) olarak devam etmesine karar verilen European Spallation Source (ESS),
20l0 yılında İsviçre ve Danimarka Hükümetleri himayesinde kurulmuş bir ortaklıktır. Daha sonra bu ortakhk
Çek Cumhuriyeti, Danimarka, Estonya, Fransa, Almanya, Macaristan, |ta|ya, Norveç, Polonya, İsveç ve
İsviçre'nin katılımı ve desteğiyle bir Avrupa Araştırma Altyapısı olarak yeniden şekillendirilmiştir. Söz
konusu oluşumun merkezinin 2019'da faaliyete geçirilmesi planlanmaktadır. Alanında dünyanın en büyüğü
olacak Merkez'de nötron saçılımı (Neutron Scattering) tekniğini kullanarak ileri seviye ma|zeme araştırmaları,
yaşam bilimleri, enerji, çevre teknolojileri ve temel fizik alanlarında araştırmacılara katkı sağlanması
hedeflenmektedir. ESS'ye katılım tam üyelik (membership) veya gözlemci üyelik (observer) olmak üzere iki
şekilde mümkün olmaktadır. Düzenlenen bilgi günü ve katılım sağlanan toplantılarda yapılan görüşmeler
neticesinde Türkiye'nin şu aşamada ilgili platforma "Gözlemci Üye" olarak katılmasının faydalı bir yöntem
olabileceği soılucuna varılmıştır. Gözlemci üyelik için ESS Konsey Başkanı'na yazıIıb\r talep iletilmesi ve
bu talebin ilgili ülkedeki araştırma camiasının altyapıya sağlayacağı katkıyı da içermesi gerekmektedir.
Gözlemci üyelik ile elde edilecek olan ESS projelerinde ortak olarak yer alma imk6nı ve ESS merkezine insan
kaynağı desteği sağlama hakkı ile araştırmalara katılım sağlanması; ilgili alanda nitelikli insan gücü
yetiştirilmesine de imk6n sağlayacaktır.
Ekte verilen metnin incelenmesinden de görüleceği üzere Türkiye'de Üniversite-Sanayi işbirliği ile ESS'ye
katkı verilebilecek pek çok alan bulunmakladır. Üniversitelerimiz ve firmalarımızın ilgilerini çeken konularda
ESS'nin talep ettiği mal ve hizmetleri sağlamanın yanı sıra elde edilecek bir başka fayda da ülkemize teknoloji
transferinin sağlanması olacaktır. Bu mal ve hizmetlerin finansmanı konusunda çalışmalar bir taraftan
yürütülmekte olup Türkiye Cumhuriyeti_1_0,Kalk_lnpa planında d4 yulguIqdığı gibi, bazı teknolojik yatırımlar
Ayrıntılı Bilgi
F
o22l
1
Dumlupınar Bulvan No:252 (Eskişehir Yolu 9. Km.) 06530 /ANKARA
Tel: +90 (3|2) 2|8 20 00 (PBX) O Faks: +90 (312)2l9 4090 -9| ,92 -93
e-posta : [email protected] O Web, i,vrrı-ı,.tobb.orq.lr
İçin: M.Hakan KIZILTOPRAK TELEFON : +90 (312) 218,2039 E-MAIL cern@,tobb.
Birliğimizde
ISO 900l:2008
org.tI
kalite yönetim sistemi
uygulanmaktadır
SayfaNo1l2
lo1.07 .2003/1/06.06.201 3
,;
.|r:
ve araştırma-geliştirme (Ar-Ge) faaliyetlerinin sadece serbest piyasa mekanizmasıyla değil, kamunun
yönlendirici, düzenleyici ve destekleyici yaklaşımlarıyla da geliştirilmesi amaçlanmaktadır.
TOBB olarak üstlendiğimiz görev, Üniversite, Sanayi ve Kamu sektörü arasında oluşturulmaya çalışılan ara
yüze ve ESS'nin ihtiyaçları doğrultusunda geliştirilecek projeler ve iş paketlerinin ortaya
çıkmasına katkıda
bulunmaktır.
Bu çerçevede ESS'nin ihtiyacı bulunan teknik destek ve araştırma alt yapısında görev alabilecek
akademik kadroların tespit edilerelg ülkemizin gözlemci üyeliğine karar verme aşamasında bulunan
ESS'deki üniversite-sanayi işbirliği fırsatlarının belirlenmesini teminen, TOBB bünyesinde Yüksek teknoloji
konularında Üniversite-Sanayi İşbirliğini gerçekleştirmek üzere kurulan ve rÜbİra« ile de etkin bir
koordinasyon halinde çalışan TOBB CERN Sanayi İrtibat Ofisi koordinatörümüz Hakan KIZILTopRAK ile
i ved il ikle irtibata geç i lme si n in önem arz ettiği değerlend iri lmektedir.
Ülkemizin kalkınma hedefleri açısından son derece önemli olan bu konuya değerli vaktinizi ayırarak
Üniversitelerimiz ve firmalarımızın birbirlerini tamam|ayarak yapılabilecek katkıların genel çeİçevesi
hakkında irtibat ofisimizi bilgilendirmeniz halinde , tarafımıza ulaşan bilgiler bütünleştirilerek Üniversite ve
SanaYicilerimizin yer alabileceği projeler belirlenecektir. Ülkemizin söz konusu resmi başvurusunun Haziran
20|6'da yapılması planlandığı göz önünde bulundurularak, İlgili Fakültelerinizle irtibata geçerek ESS,nin
ilgi alanına giren konu başIıklarından Üniversitelerimiz ve firmalarımzın işbirliği ile sağlanabileceğini
düŞündüğünüz iş paketlerinin velveya ilgili olabilecek akademik kadroların iletişim bitğilerinin .n g"ç
l 8 Mayıs 20l6 tarihine kadar tarafımıza bildirilmesini arz ederiz.
ırtibat ofisi:
M. Hakan KIZILTOPRAK
Başkanlık Özel Müşaviri
Türkiye Odalar ve Borsalar Birliği
(ESS/CERN - Türkiye Sanayi İrtibat Ofisi)
hakan. kizi [email protected]
+90
3l2 2l8 2039 iş
+90 530
EK:
5ll
7762 cep
ESS Genel Sunumu ve İş Paketleri
Dumlupınar Bulvarı No:252 (Eskişehir Yo|u 9. Km.) 06530 /ANKARA
Birliğimizde
Teı: +90 (3l2) 2l8 20 00 (PBX). Fak§: +9O (312)219 40gO -gl -92 -93
ISo9O0l:2008
e-posta : [email protected],tr O Web : ıvrvrv.tobb.org.tr
Kalite Yönetim Sisteıni
_
İçin M.Hakan KIZILTOPRAK TELEFON : +90 (3 l2) 2|8-2039 E-MAİL: [email protected] uygulanmaktadır
lı Bilgi
.2003/1/06.06.20
1
3
SayfaNo2/2
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EuRoPEAN
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ESS !K potential work packages
Status:April 2016
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Table of content
lNTRoDucTloN To THE EURoPEAN sPA[[ATloN souRcE ERlc
3
oPEN ll(c oPPoRTUNlTlEs lN THC Acc€LERAToR
4
oPEN lKc oPPoRTuNlTl€s
8
lN THE NEuTRoN scATTERlNG sYsTEMs
oPEN IKc oPPoRTUNlTlEs lN THE TARGET
10
OPEN lKC OPPORTUNlTlES İN THE lNTEGRATED CONTROL SYSTEMS
12
2
lntroduction to the
European Spallation
Source ER|C
The world's most powerful
neutron source for life sciences,
energy, environmentol
te ch n ology, cu ltu ro l h e rito ge
and fundamental physics
TYPE: Single site
MEMBER COUNTRlES
Denmark
Fra nce
Germany
Hungary
conditions. The Neutron Scattering systems (NSS) Project at ESS is responsible
for the development and coordination of state-of-the-art instrument concepts
for ESS, in collaboration with international partners. Around 40 concepts were
developed by ESS scientists and our partners. of those, 1-6 concepts have now
been selected and approved by the Ess steering committee for construction
within the Nss project. our partners from the member countries will lead the
construction of most of the instruments, and many wilI benefit from
contributions from two or more participating organisations. The Nss project is
coordinating the construction and installation of these instruments, and the
associated support systems (such as sample environments and data processing
Norway
Poland
Sweden
switzerland
OBSERVER COUNTRlES
Belgium
The Netherlands
5pain
United Kingdom
TlMELlNE
o ESFRl Roadmap entry:2006
Preparation phase: 2008-2010
Pre-construction phase: 2OTO-Z01,2
. Construction phase: 2013-2025
ı
ı
operation phase:2025
Legal entity establishment: ERlc,
201,5
ESTİMATED COSTS
o Capital value: 1.843 M€
. Operation: 140 M€/year
HEADQUARTERS
European Spal|ation Source ESS ERIC
u6,
SE-22]. 00 Lund
and analysis capabilities) to ensure the highest quality outcomes for the
European community. selection of the additional 6 instruments will occur
once construction of the initial suite of 8 instruments is approaching
completion.
ıMPACT
Ess wi|l be an attractive and environmentally sustainable large compound
including industrial and laboratory buildings, office space, and guest
accommodation facilities all housed within a significant architectural design
that will make an impact on the world's stage. Before the expected worldscale scientific impact can be realised with the operation phase, the
construction of the Ess does have a direct economic impact by generating
growth and jobs, advance development and fuel innovation potential in the
öresund region and across the Eu. with Ess being built as a collaborative
project, the growth effect will be shared between the host countries (sweden
and Denmark) and the Ess-ERlc partners. The realisation of ESS enables access
to frontier technology, experienced technical and scientific staff as well as
unique production facilities and technologies, which would otherwise be
unattainable. ln addition, the Ess will be a key instrument for addressing the
Grand challenges through novel insights on matter at the molecular and
wEB slTE
http://www.europeanspa
ESS Data Management and Software Centre (DMSC) will be located in
copenhagen (Denmark). The foreseen milestones include the beginning of the
first on-site Accelerator installations (Sep 2016), facility ready for Accelerator
beam on the Target (Dec 2019), the first call for user proposals (2022), the
Machine installed for 2.o GeV performance (Dec 2022|, start user programme
(2023}, and the completion of the ].6 construction phase instruments
enabling neutron methods to study real-world samples under real-world
ltaIy
P.o Box
transformative capabilities for interdisciplinary research in the physical and life
sciences.
ESS officially became a European Research lnfrastructure consortium (ERIC) in
october 2015. The facility is under construction in Lund (Sweden), while the
AcTıVlTY
A total of ]_6 instruments will be built during the construction phase to serve
the neutron user community with more instruments built during operations.
The suite of Ess instruments will gain 10-1oo times over current performance
Eston ia
ı
goal of building and operating the world leading facility for research using
neutrons. The Ess will deliver a neutron peak brightness of at least 30 times
greater than the current state-of-the-art, thus providing the much-desired
(Dec 2025).
Czech Republic
.
DESCRİPTlON
The European spallation source is a research infrastructure committed to the
i!ationsource. se
atomic leveI and applications to energy, carbon sequestration methods, health
issues at biology level as well as drug development and delivery strategies,
plant water-uptake processes of relevance for agriculture, novel data storage
materials, and more.
3
Within the Accelerator opportunities for lKc are requested in the following and other fields as
described below and in the following table.
High-Beta Modulotors roted for 660kvA
. The type of RF amplifiers for the High Beta section of the Linac is not decided yet. Two
options are
open:- klystrons of the same type as the ones used in the Medium Beta or
'till is
loT's. The choice
expected to be made by end 2017. should the choice be klystrons, then
ESS would require 21 klystron modulators, each modulator feeding 4 7o4MHz 1.6Mwpk
klystrons in parallel. lf the choice would be loT's, 21 loT modulators would be required, each
one capable of supplying 4 loT's in parallel. ln both scenarios the power rating of the
modulators would be nearly the same (-660kVA, on the electrical power grid side);
option
1)- K|vstron moduIators:
o
Ess is deveıoping a Stacked Muıti-Level (SML) klystron modulator concept and
prototype, which will provide a scalable, compact and cost effective solution for Ess.
The work package with open ln-kind potentaal requires production on a .'built-toprint" basis and testing of 9 units in autumn 2o16.
The stacked Multi-Level (SML} modulatorl
- Development roadmap
'un'ı3
ı|
.ı.
-E
ı
s.,
'ı3 - M.r,ıa
option 2)- |oT moduIators:
o
The topology and the procurement strategy for loT modulators i5 still under
con5ideration. The deVelopment, procurement and production plan spans from 2018
untjl 2022.
RF
Ampliİiers
.
loT (lnductive output fubes)
E55 is developing innovatave Multa-Beam lnductive output Tubes (MB-loT), a type of powerefficient source for generating radio frequency (RF) waves on the accelerator. Multi-beam
loT is a novel development pioneered by Ess, where several electron beam' (in our case 10)
are combined to reach high power. 2 prototypes have been ordered and decisions for an 84
tube order is scheduled for early 2018 with open ln-kind opportunities.
1.200 -
|,000
*]
600
ö/
l
.ıoo. l
*f-J
(9,** g=gg THALEs
Medium-Beta Klystrons
Ess has ordered 3 prototypes, which will be delivered and tested in Q2-Q3 2016. The Ess
linac will have 36 medium beta klystrons. A tender will op€n towards the end of 2016 with
possible ln-kind opportunities.
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Accelerator
WBS No.
sub-section
WP description
Brief Description
oİ lK lD
I1,.7.7
II.7.|o
Value
start Date
(k Eurol
Beam
cold Linac wire
To design and built 16 actuators that move a
Diagnostics
Scanners
wire through the proton beam, inc|uding all
mechanical parts (l.e forks, linear drive,
Beam
Beam
Diagnostics
lnstrumentation
for Target and
motors...). Allvacuum parts shall be compliant
with HUV vacuum and particle free.
The detailed design, production. integration,
274
May-16
564
May-16
10965
Sep-16
261,35
Dec-15
installation, and commissioning of the aperture
monitoring systems and the grid system.
Tuning Beam
Beam-line devices (sensors) and supporting
Dump
electronics are inc|uded as deliverables. The
aperture monitor system consists of 4 devices,
each containing an array of metal blades and
thermocouples that intercept the edge of the
proton beam. The grid system consısts of one
device in the target monolith with over 100
wires that intercept the core of the proton
beam.
11.8.5.6
RF
Medium Beta
Amplifiers
Klystron s
Medium beta amplifiers are high power RF
klystrons providing up to 1.5 MW of peak RF
power at 7o4.42 MHz frequency. Repetition
rate is 14 Hz and pu|se width is 3.5 ms. The ESS
linac wi|l have 36 medium beta klystrons.
11.8.5.7
RF
High-Beta
The high beta sources are either multi-beam
Amplifiers
Klystrons or lOTs
lOTs or klystrons providing 1.2 MW peak RF
power at the same RF frequency, repetition
rate and pulse width as for medium beta.
Multi-beam lOT is a novel development
pioneered by ESS, where several electron
beams (in our case 10) are combined to reach
high power. Multi-beam lOT is the baseline.
The fall-back solution is to use klystrons similar
to the medium beta. The ESS linac will have 84
high beta lOTs or klystrons
13. 15
Electrica
Support
l
Cab|es, Power
Distribution
Cabinets
lnstallation of cables - cable pulling and
termination of cables under ESS / (or ESS
contractor) supervision. Design and
Manufacture of power distribution cubicles
and system; for example low voltage power
distribution panels, rack power distribution
units etc. Design work includes detailed design
(layout, thermal and overload dimensioning,
mechanical enclosures) and creation of
schematics, drawings, Bil1-of-Materials, Test- &
Assembly lnstructions, Q & A documentation
etc. Manufacturing includes: Procurement of
components, assembly, quality controls,
testing and logistics support.
1600
J
un-17
Accelerator
WB§ No.
Value
(k Eurol
or lK lD
11".16
Cooling
su
pport
Design,
construction,
Piping design and installation for cooling-water
pipes in the accelerator and tunnel: Design
instaIlation of
work inc|udes detailed design (layout, routing,
piping
components) and creation of drawings, and
2000
May-16
other documentation. lnstallation work
includes installation planning, coordination,
11.16
Cooling
Design,
Cooling water skids: mechanical and electrical
5upport
con struction,
detail design of cooling-skids for accelerator
installation of
and neutron instruments, including design of
demineralizer and degassing system.
cooling skids
May-16
Manufacturing includes procuring
components, assembly, and testing (pressure
TI.I7.5.7
Modulators
High-Beta
Mod
u
lators
Production on a "built-to-print" basis and
testing of 21 pulsed klystron or lOT modulators
(depending on the choice of RF amplifier) rated
for pulse voltage/current of 115kV/1OOA
(klystrons) or 50kV/200A (lOT's) with pulse
|ength of 3.Sms and a pulse repetition rate of
I4Hz,
235o7
Dec-15
open lkc opportunities in the Neutron scatterinF svstems
One of the main open lKC opportunities within NSS is the Bunker project. The Bunker is the common
shie|ding of the instruments extending from the Target monolith (see drawing betow). The materials
that will be mainly used in the bunker are concrete and steel. Another lKC opportunity is the Fast Slit
Shutter Prototype package, where NSS needs an assessment of fast direct linear actuator
technologies, like voice coils or linear motors.
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There are also opportunities for lKC with DMSC (Data Management and Software Centre) for the
User Office and also within the Science Support Systems for Laboratories and Facilities as well as for
Sample Environment Equipment.
Project lnstruments Resources Status and lKC percentoge
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wBs No.
sub-section
WP description
Brıef DesCİıptıon
Value
or ıK lD
NlK 4#7
start Date
(k Euro|
DMSc
user office
WP to provide User Office Staff from Jan 20].8
1638
201,8
c. 500
TBD
TBD
TBD
100
20t6
15000
Q2-2016
1638
2018
to Dec 2021 to establish operations
procedures and support functions for the
DMsC.
NA
NA
5SS
SSS
Laboratories and
To supply and fit out laboratory equipment for
Facilities
scientific users of Ess
Sample
Mechantronics, Software lntegration,
environment
Biological/Chemical
equipment
Deutration, Microscopes
-
cellgrowth, high
temperatu re/pressure/magnetic field
environments. Mixture of commerical
equipment and some design effort.
NlK 6.25
lnstrument
Fast slit shutter
To assess fast direct linear actuator
#1
construction
Prototype
technologies (like voice coils or linear motors)
in delivering the performance requirements of
the fast slit and shutter systems. A prototype
test rig is required to a|low testing of Various
motion parameter5 and configurations prior to
deployment on instruments.
NA
lnstru ment
Bunker
construction
The Bunker is the common shielding of the
instruments extending from the Target
monolith.
The maximum outside radius of the bunker
wall will be 28 m. The materials will be mainly
concrete and steel. The shielding blocks need
to be easily movable for maintenance and to
give access to the instrument beamlines.
NlK 4#7
DMsC
user office
WP to provide User Office Staff from Jan 2018
to Dec 2021 to establish operations
procedures and support functions for the
DMsc.
Target has open lKc opportunities namely in the design and procurement of monolith steel 5hielding,
which i5 currently being broken down into severaI smaller work packages. Furthermore, pu.tn"r,
needed for the design and procurement of shielding casks used to transfer highlv activated
"re
components from the monolith to the Active cells as part of the internal Casks and Handling Devices,
as well as for the procurement of machine equipment for the activated components workshop,
mock-up test stand, and complementary shielding. The uncommitted ln-kind work packages are
summarised below.
Uncommitted ln-kind Work Packages
.
Target monitoring plug (0.5M€j
-
Plut on downstream side of taİteı wheel wİh
instfumentation to monitor ta.get health
.
Helium Atmosphere system (ı.3M€)
.
Monolith Shielding Systems U4.2M€}
.
P8w Primary cooling System (0.5M€)
_
-
Atmosphere within the monolith
Breakint th|s into smaller packages
- Hellum €oolant
. lnternal
casks and Handling Devices (3.3M€)
.
-
For t.ensferrint activated components from the
monolith to the active cells
Remote Handlin8 support (1.2M€)
-
Mock-up ı€st stand, complementaıy shieldin&
other items
10
Target
wBs No.
sub-section
wP descrıptıon
Brief Description
or ıK ıD
TlK 4.1
Value
start Date
(k Eurol
Tar8et Monitoring
Plug
Design and prbcurement of a vertical stringer
that is located just downstream of the target
483
Nov-16
1295
Nov-16
1,4227
May-15
528
May-16
3293
Sep-16
T2Io
Dec-16
whee| with in5trumentation to diagnose the
proper function of the target.
TlK 4.7
He Atmosphere
Design and procurement of the helium
system
atmosphere control system for the target
monolith.
TlK 4.8
TlK.5.4
Monolith
Design and procurement of monolith steel
ShieIding System
shielding. This TlK is currently being broken
into several smaller packages.
Proton Beam
Design and procurement of a helium cooiing
Window Primary
loop with a thermal capacity of about 3 kW.
cooling system
TlK 6.2
TlK 6.7
Internal casks and
Design and procurement of shielding casks
Handling Devices
used to transfer highly activated components
from the monolith to the Active cells.
Remote Handling
Procurement of machine equipment for the
activated components workshop, mock-up test
support
stand, and complementary shieldins.
11
open ıkc opportunıtıes ın the ıntegrated controı svstems
At this point lCS has identified 22% of the construction funding as possible lKC with the goal of
reaching up to 5O%. Additional Work Package definitions are ongoing. The majority of value within
lCS's scope during the construction phase is represented as manual labor, many of which are
transient positions, namely in the following fields:
. Software development services
.
.
.
Hardwaredevelopmentservices(electronics)
PLC programming services
"lntegration"
Technicalscope for lcs
'
.
.
.
.
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lııfrastructure: networking, data centre contrcl
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12
WBs
No. or
Sub-
WP description
Brief Description
section
Value
{Euro)
ıK ıD
lCs
L4,2
Development of lCS
specific applications
lcS
14.2
Software quality
processes and
Development of lCS specific applications
such as our controls configuration database,
lOC factory and others. Requires
competence in JaVa, database, Web based
Ul. Some applications are partially
Start
Date
250000 2000000
1H 2016
100000 300000
2H 2016
500000 1000000
2H 2oI8
200000 _
1000000
IH 2016
500000 1000000
1H 2018
200000 500000
2H 2oL6
150000 _
900000
2H 2016
1000000 3000000
2H 2016
250000 _
500000
2H 2077
400000 700000
2H 201,6
completed
environment
lCS
14.2
software interlock
system
lCS
lcS
t4.3
DeVelopment and
L4.3
enhancement of
EP|CS v4 community
software packaRes
preventive
Maintenance
system
lCS
|4.3
calibration
database
lCS
14.3
Application for
Save, compare and
restore
lCs
1,4.4
lntegration of
instrumentation
lC5
14,4
Robustness and
availability analyses
lcs
14.4
Small FMC carrier
Studies and development of applicab|e
software quality processes and
environment. Support for applying
continuous integration, test driven
methodology and other techniques.
Extension of the MPS to do proactive
machine protection with advanced software
technologies such as neural network
analysis etc
Development and enhancements of areas in
Eplcs v4 that are identified as critical for Ess
operations. Requires competence in C, C++
and Java
MES-class application to manage
maintenance of the machine. calculates
wear, running time etc and schedules
maintena nce.
DeveIopment and deployment of
application for storage and retreival of
calibration data for devices with versioning
5upport. ldeas include integration with the
configuration solution already under
development in lCS.
Storage of a set of pv Values, comparison
functions with stored values, and restore of
saved values. Current design ideas include
"goIden snapshot" concept, grouping pv:s
into request files and database storage of
the information. May be partaally using open
source components.
lntegration of instrumentation systems into
the lcs standardized electronic front-end
platform. Requires competence in
electronics, FPGA and low-level software
Development of test environment for
specialized and stress-testing of lCS
5tandardized'eIectronic front-end platform.
Requires electronics, test and software
competence
Design and development of a small form
factor FMc carrier board with cpu
capability. Design conceptis inc|ude DlN-rail
mountab|e unit. Ethernet connectivity
required.
13
lntegrated Control Systems
WBs
WP description
Value
No. or
ıK lD
lCS
(Euro)
74.1
Cyber-security
assessment and
enhancement to
control system data
network
Assessment of cyber security of the control
system infrastructure network inc|uding
vulnerability and penetration testing, stress
testing of equipment and software. Requires
80000 150000
2H 2076
lCs
14.8
Physics application
200000 500000
2H 2016
lcs
Development and support for online physics
model in OpenXAL framework (Java) for
linear accelerator simulation5,
1,4.Io
lnstallation of equipment and infrastructure
lcS
Automation
software
development
Development of specialized automation
software for control system application5,
Competence in automation systems from
500000 1500000
100000 1000000
1H 201,8
I4.Io
Control system
installation services
14
2H 201,6
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Host countries of sweden and Denmark
l
Construction 47.5o/o ln-kind Deliverables - 30^
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Denmark (member) *
Germany (member) United Kingdom (observer)
France (member)
ltaly (member)
Spain (observer) switzerland (member)
Nonıay (member)
Poland (membeO
Czech Republic (member)
Hungary (member)
Lithuania (future member)
Estonia (member)
Total
Czech Republic
35.0%
12.5%
11.o %
10,o%
8.0 o/o
6.0%
5.0 Yo
3.5%
2.5%
2.o o^
2.0%
0.95 %
o.45%
Poland
.
ŞWtzerlano
Lithuania
Estonia
To be determined
_Norwavi
0.25%
99.15 %
Belgium (observer)
Netherlands (observer)
Greece (future observer)
lceland
Latvia
Discussions: Portugal, Tu rkey, Finland
' lncludes pre-construction costs
tbd
tbd
tbd
tbd
tbd
Denmark
7
Organisation
Administıation & Fjnance committğe
Praft. Vice-chajr
,
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EUROPEAN SPALLAT|ON SOURCE ERlC COUNClL
M. schartf, chair
N.
lrııiı
'
souRcE
Technıcal Advlsory commıtt€e
P. Lebrun, chaif
L. Börjesson, CHA|R
ln-kind Review committee
M. Marazıi, chair
. EuRoPEAN
, spAtLATıoN
EUROPEAN SPALLAT|ON SOURCE AB BOARO
s. Landelius, cHAlR
B. smith, VlcE-cHAlR
science Advisory commitlee
A, Mey€İ, chair
s, Mcclaın. co_chaİr
EUROPEAN SPALLATION
Partners and growing
ENVlRoNMENT.
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T. Welandar
ADMıN|STRAToR
M. Herbst
M. Po*€ll
DlREcToR
PERSoNAL AsslsTANT
DEPUTY
J, Haine§ (l)
H. Fröderberg
sclENcE DlREcToMTE
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{2oo0)
sclENcE DlREcToR
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s. Kennedy
Deıl Anno Boulton
s. Ghatnekar Nılsson
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D. Adonls (A)
M. LinÖberg (L)
lvl.
sENıoR ADVlsoR
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, .r"oo.o,
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EsS AB
l
Swedish limited liability
corporation
-
owned by the Swedish
and Danish governments
transfer of assets,
obligations and
personnel
by Oct 1, 2015
European Research
nfrastructu re consortium
Sole governing body: the
European Spallation
Source ERlC Council,
comprised of
representatives from the
Member and observer
countries
9
Ground Break Event
.
.
2 September 2014 (200 guests)
official start of the construction!
\-.------l-
Foundation Stone Ceremony
. 9 October 2014 (700 guests)
.
.
o
Programme on site incIuding speeches, partner
video, wolking tour and reception
Science Symposium in Lund
Mobilized partners and stakeholders for
construction!
ER|C P|ate Ceremony
Handing over of the ER|G Plate
.
.
.
8 September 2015 (60 guests) onsite
Marks the transition from ESS AB to
The European Spallation Source ERlC
Speakers:
. Robert-Jan Smits, DirectorGeneral for Research and
lnnovation, European Commission
. Helene Hellmark Knutsson,
Swedish Minister for Higher
Education and Research
. Dr. Esben Lunde Larsen, Danish
Minister for Higher Education and
Science
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Ş+-.{
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2014
construction work
starts on the site
ESS starts
user program
2009
ı-/
Decision: ESS will
be built in Lund
,,
2003
First European design
effort of ESS completed
2012
ESS Design Update
phase complete
2019
First neutrons on
instruments
2023
Key Project Parameters
Deliver on the Technical Design Report performance and Steering
committee commitments
5 MW accelerator capabllity
Cost Book construction cost of 1.843 B€,o,,
Cost Book annual operations cost target of 140 M€ro,,
22"public" instruments (16 included in the construction budget)
Start w/ unconstrained resources (technically limited schedule) and develop
credible project execution plans
Comprehensive review of project baseline and execution plans
Secure funding and resources and align schedules with the available
resources
-
Ess
construction cost baseline
@,Şii,:|jfJ"
(Jan 2013 pricing)
conventional FaciIities
CF scope supported by host countries
531.9
-93.0
Accelerator Systems
510.2
Target Systems
155.2
lntegrated Control System
73.o
Design & Engineering
33.7
Neutron Scattering Systems
350.0
Project Support & Administration and Licensing
123,8
Contingency
158.2
Total Construction Budget and ESS Cost Book Value
1843.0
Construction cost: C 1.84 Blllion
ln kind:
747.5 Million
ı
€
€
€
€
€
€
600
€510M
500
€350M
400
ı Cash
ı lKC
300
€ 155 M
200
100
€00
Controls
Target
lnstruments (NSS)
Accelerator
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