TIBTIDNotes/TIBTIDIntNote/SiStripLayout.tex

\section{TIB and TID layout}

TIB and TID are very compact objects with high readout granularity;
channel and module densities are three to four times larger than in
the other SST subsystems as shown in Table~\ref{table:Density} where
the main parameters of the SST subsystems are
reported. The TIB and TID layout has been designed matching the
following features: simple mechanical structure; easy routing of the
large number of service connections (cooling, readout, controls); easy
component mounting in the case of the TIB non-planar (cylindrical)
geometry; optimization the theta (and phi?) for the TID. 

The TIB is structured in four concentric layers. Each layer is
split along the vertical plane at $z=0$ into two almost identical half-layers. Each
half-layer is further split along the horizontal at $y=0$ into two semi-cylindrical
structures, also referred to as ``shells''. The shell structure is a
semi-cylindrical carbon fiber assembly strenghten by two circular
flanges at both ends. Modules and services are hold either on
the external and the internal surfaces. The services are laid down on
the surface and run parallel to the $z$ axis.
% on the surface toward the end (i.e. in the
%direction along which $|z|$ increases).
The modules and the related
services that sit on the same side of a shell at the same $\phi$
coordinate constitute a \textit{string}. 

The TID is split into six disks (three per each side of
TIB). The disk is made up by three sub-disks called "rings" since each
ring holds modules at the same radius. The ring structure consists of 
a mechanical support made of an annular carbon fiber honeycomb,
hosting modules and services on both sides to decrease the density
and therefore providing a better accessibility during ring integration
and  disk assembly.

As a result of the above described structure the TIB/TID system is
divided into two physically separated structures, one located in the
$z > 0$ region and one located in the $z < 0$ region and known as
TIB/TID+ and TIB/TID- respectively. Each TID+ and TID- is obtained by
inserting, positioning and fixing each disk into a carbon fiber
cylinder called {\it Service Cylinder}. Each Service Cylinder has
several holes at the position of disk, in order to allow the
connection of the power lines and to route out all the fibers of the
disk. The Service Cylinder is also used to connect mechanically TIB+/-
and TID+/-, and to route out the services of the TIB and of the TID.

The cooling in the TIB/TID is distributed via aluminum pipe circuits  
that  are bent into loops and soldered to inlet/outlet manifolds at
the flange for the TIB, and at the ring outer edge for the TID.
The thermal connection between pipes and sensor modules is made with Aluminum ledges which are 
precisely glued on the carbon fiber support structure and in good thermal contact with the pipes. 
On each ledge there are two threaded M1 holes onto which the modules are tightened.
Precisely drilled slots, coaxial with the threaded holes, are the reference point where
insets are stick in providing mechanical reference for modules. An example for a TIB module
is shown in Fig.~\ref{fig:module_cooling}). 

The TIB and TID substructures, 16 shells and 18 rings, are relatively
large-sized: shells hold 135 to 216 modules, rings hold 40 to 48 modules.
Some other relevant specifications of the TIB and TID substructures are
summarized in Table~\ref{table:layers}. 
A finished half of the TIB and a TID Disk are shown in
Fig.~\ref{fig:tibtid}. The pictures allow the sub-structures to be
recognized.


\begin{figure}[!htb]
\begin{center}
  \includegraphics[width=0.45\textwidth]{Figs/shell.pdf} 
%  \includegraphics[height=0.5\textwidth]{Figs/TIB-assembled.pdf} 
  \hskip 1cm
  \includegraphics[width=0.45\textwidth]{Figs/TIB_barrel.png}
\end{center}
\caption{A L3 TIB shell (left panel) and half of TIB assembled (right panel).}
\label{fig:tib}       % Give a unique label
\end{figure}

\begin{figure}[!htb]
\begin{center}
  \includegraphics[height=0.35\textwidth]{Figs/ring.pdf} 
%  \includegraphics[height=0.5\textwidth]{Figs/TIB-assembled.pdf} 
  \hskip 3cm
  \includegraphics[height=0.35\textwidth]{Figs/TID-disk.pdf}
\end{center}
\caption{A R1 TID ting assembled (left panel) and one TID disk (right panel).}
\label{fig:tid}       % Give a unique label
\end{figure}


\begin{table}[!htb]
\begin{center}
%\begin{tabular}{|l||c|c|c|c|c|c|c|}
\caption[smallcaption]{Total number of modules, strips (or electronic readout channels), detector volume and 
channel density for the different tracker subsystems. Service access area is also defined
for barrel geometry detectors (TIB and TOB) as their flange area. The channel density in this 
area gives also an idea of the complexity of the detector integration.}
\label{table:Density}
\begin{tabular}{|l|ccccccc|}
\hline
 &         &          &        & Module   & Channel                    & Service  & Service              \\
 & \# of   &\# of     & Volume & Density   & Density                    & Area & Density             \\
 & modules & channels & [m$^3$]& [$\times 10^3$  m$^{-3}$] & [$\times 10^6$ ch m$^{-3}$] & [m$^2$] &  [$\times 10^6$ ch m$^{-2}$]\\
%\hline
\hline
TIB & 2724 & 1 787 904 & 0.82 & 3.2 &  2.2 & 1.6 & 1.11\\
%\hline
TID & 816 & 565 248 & 0.5 & 1.6  & 1.1  & & \\
%\hline
TOB & 5208 & 3 096 576 & 5.9 & 0.89  & 0.52 & 5.7 & 0.54\\
%\hline
TEC & 6400 & 3 866 624 & 11 & 0.58 & 0.35  & & \\
\hline
\end{tabular}
\end{center}
\end{table}


\begin{table}[!htb]
\begin{center}
\caption[smallcaption]{Details on the different layers/rings of the TIB/TID. }
\label{table:layers}
%\begin{tabular}{|l||c|c|c|c|c|c|c|}
\begin{tabular}{|l|ccccccc|}
\hline
 Layer & \# mechanical & \# cooling  &  DS/SS & \# of modules  & \# of channels & \# Control & \# Mother  \\  
       &   structures  &  circuits    &  layer &  total         & per module         &  Rings     &  Cables  \\
 \hline
% \hline
TIB L1  & 4 shells &    & DS & & & &  \\
TIB L2  & 4 shells &    & DS & & & &  \\
TIB L3  & 4 shells &    & SS & & & &  \\
TIB L4  & 4 shells &    & SS & & & &  \\
TID R1  & 6 rings  & 24 & DS & 288 & 768 & 12 & 48 \\
TID R2  & 6 rings  & 24 & DS & 288 & 768 & 12 & 48 \\
TID R3  & 6 rings  & 24 & SS & 240 & 512 & 12 & 48 \\
\hline 
\end{tabular} 
\end{center}
\end{table}


%\subsection{Mechanical Structures}

%A TIB shell is shown on Fig.~\ref{fig:tibshell}).

%Each cooling loop hosts three modules placed in a straight row, which is called a
%A string of modules is connected to the same CCU, thus forming a control branch.

%\begin{figure}
%\centering
%\includegraphics[width=\textwidth]{   }
%\caption{TIB shell: are visible the internal and external parts, the cooling pipes and the string}
%\label{fig:tibshell}
%\end{figure}


%\begin{figure}
%\centering 
%\includegraphics[width=\textwidth]{   }
%\caption{TID ring }
%\label{fig:tidring}
%\end{figure}


\begin{figure}
\centering
\includegraphics[width=0.6\textwidth]{Figs/module_cooling.pdf}
\caption{Module Cooling. 
\textbf{Upper picture:} a whole cooling loop with six ledges to hold three modules and three
smaller ledges to hold Analog Opto-Hybrids (two more cooling loops are partially visible).
\textbf{Lower picture:} a detail of a cooling loop. The cooling fluid direction
is evidenced with blue arrows, and the precision insets for module insertion are circled in
red. A module mounted on the nearby position is also visible.}
\label{fig:module_cooling}
\end{figure}
Revision:	1.4
Committed:	Mon Mar 9 15:41:05 2009 UTC (16 years, 1 month ago) by sguazz
Content type:	application/x-tex
Branch:	MAIN
Changes since 1.3:	+175 -0 lines
Log Message:	Text revision, some figures added, some removed
#	User	Rev	Content
1	sguazz	1.4	\section{TIB and TID layout}
2
3			TIB and TID are very compact objects with high readout granularity;
4			channel and module densities are three to four times larger than in
5			the other SST subsystems as shown in Table~\ref{table:Density} where
6			the main parameters of the SST subsystems are
7			reported. The TIB and TID layout has been designed matching the
8			following features: simple mechanical structure; easy routing of the
9			large number of service connections (cooling, readout, controls); easy
10			component mounting in the case of the TIB non-planar (cylindrical)
11			geometry; optimization the theta (and phi?) for the TID.
12
13			The TIB is structured in four concentric layers. Each layer is
14			split along the vertical plane at $z=0$ into two almost identical half-layers. Each
15			half-layer is further split along the horizontal at $y=0$ into two semi-cylindrical
16			structures, also referred to as ``shells''. The shell structure is a
17			semi-cylindrical carbon fiber assembly strenghten by two circular
18			flanges at both ends. Modules and services are hold either on
19			the external and the internal surfaces. The services are laid down on
20			the surface and run parallel to the $z$ axis.
21			% on the surface toward the end (i.e. in the
22			%direction along which $\|z\|$ increases).
23			The modules and the related
24			services that sit on the same side of a shell at the same $\phi$
25			coordinate constitute a \textit{string}.
26
27			The TID is split into six disks (three per each side of
28			TIB). The disk is made up by three sub-disks called "rings" since each
29			ring holds modules at the same radius. The ring structure consists of
30			a mechanical support made of an annular carbon fiber honeycomb,
31			hosting modules and services on both sides to decrease the density
32			and therefore providing a better accessibility during ring integration
33			and disk assembly.
34
35			As a result of the above described structure the TIB/TID system is
36			divided into two physically separated structures, one located in the
37			$z > 0$ region and one located in the $z < 0$ region and known as
38			TIB/TID+ and TIB/TID- respectively. Each TID+ and TID- is obtained by
39			inserting, positioning and fixing each disk into a carbon fiber
40			cylinder called {\it Service Cylinder}. Each Service Cylinder has
41			several holes at the position of disk, in order to allow the
42			connection of the power lines and to route out all the fibers of the
43			disk. The Service Cylinder is also used to connect mechanically TIB+/-
44			and TID+/-, and to route out the services of the TIB and of the TID.
45
46			The cooling in the TIB/TID is distributed via aluminum pipe circuits
47			that are bent into loops and soldered to inlet/outlet manifolds at
48			the flange for the TIB, and at the ring outer edge for the TID.
49			The thermal connection between pipes and sensor modules is made with Aluminum ledges which are
50			precisely glued on the carbon fiber support structure and in good thermal contact with the pipes.
51			On each ledge there are two threaded M1 holes onto which the modules are tightened.
52			Precisely drilled slots, coaxial with the threaded holes, are the reference point where
53			insets are stick in providing mechanical reference for modules. An example for a TIB module
54			is shown in Fig.~\ref{fig:module_cooling}).
55
56			The TIB and TID substructures, 16 shells and 18 rings, are relatively
57			large-sized: shells hold 135 to 216 modules, rings hold 40 to 48 modules.
58			Some other relevant specifications of the TIB and TID substructures are
59			summarized in Table~\ref{table:layers}.
60			A finished half of the TIB and a TID Disk are shown in
61			Fig.~\ref{fig:tibtid}. The pictures allow the sub-structures to be
62			recognized.
63
64
65
66			\begin{figure}[!htb]
67			\begin{center}
68			\includegraphics[width=0.45\textwidth]{Figs/shell.pdf}
69			% \includegraphics[height=0.5\textwidth]{Figs/TIB-assembled.pdf}
70			\hskip 1cm
71			\includegraphics[width=0.45\textwidth]{Figs/TIB_barrel.png}
72			\end{center}
73			\caption{A L3 TIB shell (left panel) and half of TIB assembled (right panel).}
74			\label{fig:tib} % Give a unique label
75			\end{figure}
76
77			\begin{figure}[!htb]
78			\begin{center}
79			\includegraphics[height=0.35\textwidth]{Figs/ring.pdf}
80			% \includegraphics[height=0.5\textwidth]{Figs/TIB-assembled.pdf}
81			\hskip 3cm
82			\includegraphics[height=0.35\textwidth]{Figs/TID-disk.pdf}
83			\end{center}
84			\caption{A R1 TID ting assembled (left panel) and one TID disk (right panel).}
85			\label{fig:tid} % Give a unique label
86			\end{figure}
87
88
89			\begin{table}[!htb]
90			\begin{center}
91			%\begin{tabular}{\|l\|\|c\|c\|c\|c\|c\|c\|c\|}
92			\caption[smallcaption]{Total number of modules, strips (or electronic readout channels), detector volume and
93			channel density for the different tracker subsystems. Service access area is also defined
94			for barrel geometry detectors (TIB and TOB) as their flange area. The channel density in this
95			area gives also an idea of the complexity of the detector integration.}
96			\label{table:Density}
97			\begin{tabular}{\|l\|ccccccc\|}
98			\hline
99			& & & & Module & Channel & Service & Service \\
100			& \# of &\# of & Volume & Density & Density & Area & Density \\
101			& modules & channels & [m$^3$]& [$\times 10^3$ m$^{-3}$] & [$\times 10^6$ ch m$^{-3}$] & [m$^2$] & [$\times 10^6$ ch m$^{-2}$]\\
102			%\hline
103			\hline
104			TIB & 2724 & 1 787 904 & 0.82 & 3.2 & 2.2 & 1.6 & 1.11\\
105			%\hline
106			TID & 816 & 565 248 & 0.5 & 1.6 & 1.1 & & \\
107			%\hline
108			TOB & 5208 & 3 096 576 & 5.9 & 0.89 & 0.52 & 5.7 & 0.54\\
109			%\hline
110			TEC & 6400 & 3 866 624 & 11 & 0.58 & 0.35 & & \\
111			\hline
112			\end{tabular}
113			\end{center}
114			\end{table}
115
116
117			\begin{table}[!htb]
118			\begin{center}
119			\caption[smallcaption]{Details on the different layers/rings of the TIB/TID. }
120			\label{table:layers}
121			%\begin{tabular}{\|l\|\|c\|c\|c\|c\|c\|c\|c\|}
122			\begin{tabular}{\|l\|ccccccc\|}
123			\hline
124			Layer & \# mechanical & \# cooling & DS/SS & \# of modules & \# of channels & \# Control & \# Mother \\
125			& structures & circuits & layer & total & per module & Rings & Cables \\
126			\hline
127			% \hline
128			TIB L1 & 4 shells & & DS & & & & \\
129			TIB L2 & 4 shells & & DS & & & & \\
130			TIB L3 & 4 shells & & SS & & & & \\
131			TIB L4 & 4 shells & & SS & & & & \\
132			TID R1 & 6 rings & 24 & DS & 288 & 768 & 12 & 48 \\
133			TID R2 & 6 rings & 24 & DS & 288 & 768 & 12 & 48 \\
134			TID R3 & 6 rings & 24 & SS & 240 & 512 & 12 & 48 \\
135			\hline
136			\end{tabular}
137			\end{center}
138			\end{table}
139
140
141			%\subsection{Mechanical Structures}
142
143			%A TIB shell is shown on Fig.~\ref{fig:tibshell}).
144
145			%Each cooling loop hosts three modules placed in a straight row, which is called a
146			%A string of modules is connected to the same CCU, thus forming a control branch.
147
148			%\begin{figure}
149			%\centering
150			%\includegraphics[width=\textwidth]{ }
151			%\caption{TIB shell: are visible the internal and external parts, the cooling pipes and the string}
152			%\label{fig:tibshell}
153			%\end{figure}
154
155
156			%\begin{figure}
157			%\centering
158			%\includegraphics[width=\textwidth]{ }
159			%\caption{TID ring }
160			%\label{fig:tidring}
161			%\end{figure}
162
163
164
165			\begin{figure}
166			\centering
167			\includegraphics[width=0.6\textwidth]{Figs/module_cooling.pdf}
168			\caption{Module Cooling.
169			\textbf{Upper picture:} a whole cooling loop with six ledges to hold three modules and three
170			smaller ledges to hold Analog Opto-Hybrids (two more cooling loops are partially visible).
171			\textbf{Lower picture:} a detail of a cooling loop. The cooling fluid direction
172			is evidenced with blue arrows, and the precision insets for module insertion are circled in
173			red. A module mounted on the nearby position is also visible.}
174			\label{fig:module_cooling}
175			\end{figure}