From 72f580f6cbf70c211cb2ff49701bd83692c6d125 Mon Sep 17 00:00:00 2001 From: niepra01 <rolf.niepraschk@ptb.de> Date: Wed, 18 Mar 2015 08:07:32 +0100 Subject: [PATCH] =?UTF-8?q?Fu=C3=9Fbereich=20auf=20Textunterkante=20bezoge?= =?UTF-8?q?n=20(Querformat!)?= MIME-Version: 1.0 Content-Type: text/plain; charset=UTF-8 Content-Transfer-Encoding: 8bit --- ptbposter/ptbposter-test-quer.tex | 97 +++++++++++++++++++++++++++++++ ptbposter/ptbposter.cls | 93 +++++++++++++++-------------- 2 files changed, 147 insertions(+), 43 deletions(-) diff --git a/ptbposter/ptbposter-test-quer.tex b/ptbposter/ptbposter-test-quer.tex index e69de29..27ceba0 100644 --- a/ptbposter/ptbposter-test-quer.tex +++ b/ptbposter/ptbposter-test-quer.tex @@ -0,0 +1,97 @@ + +\documentclass[english,landscape,sanserif]{ptbposter} +%\documentclass[ngerman,sanserif]{ptbposter} + +\author{Ute Becker} +\phone{+49-30-3481-7467} +\fax{+49-30-3481-7503} +\email{Ute.Becker@ptb.de} +\workingGroup{7.54 Vacuum Metrology} +\department{7.5 Heat and Vacuum} +\location{10587 Berlin} +\street{Abbestraße 2--12} +\QRcode{http://www.ptb.de/cms/fachabteilungen/abt7/fb-75/ag-754.html} + +\title{Das Liebesleben der Maikäfer} + +\begin{document} + +\begin{multicols}{2} +\section{Introduction} + +Regarding to the Kyoto Protocol, the European Union and its members have +committed themselves to reduce the emissions of refrigerant greenhouse gases, +like R-134a, during the period 2008--2012. To control the emission of +refrigerant equipment, it is necessary to check the accuracy of leak detectors +and room controllers. In the European standard EN 14624 it is pointed out, only +to use calibrated leaks (called sniffer test leaks) based on a primary +standard. + +\begin{itemize} + \item The range of the PTB primary standard is from $4\cdot10^{-11}$ mol/s to + $4\cdot10^{-9}$ mol/s which is the most needed range in industry of around 1 g + loss per year of the cooling agent R134a. + +%%%\includegraphics[width=0.5\linewidth]{TL2} +%%%\includegraphics[width=0.495\linewidth]{skizze} + +The leakrate $q_{pv}$ is calculated by $q_{pv}= \frac{\Delta V}{\Delta t} \cdot +p_{atm}$ and the molar flow follows from $q_{\nu} = \frac{q_{pV}}{R\cdot +T_{wv}}$. +\end{itemize} +\section{Measurements} +There are two types of leaks, capillary and permeation leaks. Both kinds of +leaks contain the gas R-134a which flow to atmospheric pressure. With the +following measurements the influence of the fill pressure, the atmospheric +pressure on the leak rate and stability is examined. +\begin{itemize} + \item The capillary leak is equipped with a pressure reducer and generates a + gas flow of $q_{\nu}=8\cdot10^{-3}$\,Pa\,l/s. The measurements did not show a + significant dependence on the fill pressure and the atmospheric pressure, + however the repeatability is $\pm\,3.4\,\%$. + +%%%\includegraphics[width=0.8\columnwidth]{qvonpatmcap} + +\item The permeation leak is equipped with a Teflon membrane and generates a +gas flow of $q_{\nu}=1\cdot10^{-3}$\,Pa\,l/s. In the following graph the mean +leak rate is shown vs. different fill pressures. The measurements show a +significant dependence on the fill pressure $p_{fill}$ and the atmospheric +pressure $p_{atm}$. The slope of the linear least square fit determines the +atmospheric coefficients $(\Delta q_{\nu}/q_{\nu}(1010\,hPa))/\Delta p_{atm}$ of +the flow rates. The uncertainty bars show the standard deviation of repeat +measurements.The permeation leak is equipped with a Teflon membrane and +generates a gas flow of $q_{\nu}=1\cdot10^{-3}$ Pa l/s. In the following graph +the mean leak rate is shown vs. different fill pressures. The measurements show +a significant dependence on the fill pressure $p_{fill}$ and the atmospheric +pressure $p_{atm}$. The slope of the linear least square fit determines the +atmospheric coefficients $(\Delta q_{\nu}/q_{\nu}(1010\,hPa))/\Delta p_{atm}$ +of the flow rates. The uncertainty bars show the standard deviation of repeat +measurements. + + +%%%\includegraphics[width=0.8\columnwidth]{qvonpatmper} + +In the next step, the data were normalized for a gas flow $q_{\nu}$ at an +atmospheric pressure of 1010\,hPa. Thus the fill pressure coefficients $(\Delta +q_{\nu}/q_{\nu}(1bar))/\Delta p_{fill}$ could be calculated. + +%%%\includegraphics[width=0.8\columnwidth]{qvonpfill} + +\end{itemize} +\section{Results} +\begin{center} + \begin{tabular}{@{}lll@{}} + \toprule + & capillary leak & permeation leak \\ + \midrule + $(\Delta q_{\nu}/q_{\nu}(1010\,hPa))/\Delta p_{atm}$ & - & $ \leq -0.0063/hPa $ \\ + $(\Delta q_{\nu}/q_{\nu}(1bar))/\Delta p_{fill}$ & - & $\leq 0.46/bar$\\ + repeatability & $\pm 3.4 \%$ & $\pm\,0.7\,\% \cdots \pm\,1.6\,\%$ \\ + \bottomrule + \end{tabular} +\end{center} +So far, no temperature dependence could be measured due to consistencies +probably caused by experimental shortcoming. +\end{multicols} + +\end{document} diff --git a/ptbposter/ptbposter.cls b/ptbposter/ptbposter.cls index 1e9c4f3..4b0d811 100644 --- a/ptbposter/ptbposter.cls +++ b/ptbposter/ptbposter.cls @@ -4,7 +4,7 @@ \NeedsTeXFormat{LaTeX2e}[1999/12/01] \ProvidesClass{ptbposter} - [2015/03/17 v0.2b PTB-Poster-Klasse (RN)] + [2015/03/18 v0.2b PTB-Poster-Klasse (RN)] \PassOptionsToPackage{paper=a0paper}{geometry} @@ -26,11 +26,14 @@ top=\the\dimexpr\PTB@topmargin-\PTB@textsep}{geometry}} \PTB@tempa } -\DeclareOption{landscape}{% TODO: überarbeiten +\DeclareOption{landscape}{% \setlength\PTB@leftmargin{0.5\dimexpr 1189mm-1130mm} - \setlength\PTB@topmargin{228mm}% ??? - \PassOptionsToPackage{landscape,textwidth=1130mm,textheight=550mm, - left=\PTB@leftmargin,top=\PTB@topmargin}{geometry} + \setlength\PTB@topmargin{228mm} + \edef\PTB@tempa{\noexpand\PassOptionsToPackage{landscape, + textwidth=\the\dimexpr1130mm-2\PTB@textsep, + textheight=\the\dimexpr550mm-2\PTB@textsep,hcentering, + top=\the\dimexpr\PTB@topmargin-\PTB@textsep}{geometry}} + \PTB@tempa } \DeclareOption{sanserif}{% TODO! @@ -104,9 +107,8 @@ \RequirePackage[texcoord]{eso-pic} \RequirePackage{pict2e,picture,ifdraft,qrcode,booktabs} -\AddToShipoutPictureBG{% TODO: Evtl. besser auf untere Blattkante beziehen. +\AddToShipoutPictureBG{% === Kopf === \put(\PTB@leftmargin,-95.4mm){\includegraphics[width=477mm]{ptbposter-logo.pdf}}% - % TODO: Besser so \DeclareFixedFont{\Big}{\encodingdefault}{\sfdefault}{m}{n}{10} \put(\PTB@leftmargin,-160mm){\sffamily\titleFontSize\@title}% \put(\PTB@leftmargin,-190mm){\sffamily\authorFontSize\@author}% \put(\PTB@leftmargin,-105mm){% @@ -117,42 +119,47 @@ \put(-\PTB@textsep,-\PTB@textsep){\framebox(\dimexpr\textwidth+2\PTB@textsep, \dimexpr\textheight+2\PTB@textsep){}} }% - \linethickness{.5mm}% - \put(\PTB@leftmargin-.5\@wholewidth,-1144mm){% - \raisebox{19mm}{\qrcode[height=47mm,tight]{\PTB@qrcode}}% - \color{PTBcolor}% - \hspace{2mm}\raisebox{-.5mm}{\rule{47mm}{47mm}}% - \hspace{2mm}\framebox(46mm,46mm){}% - %\circle*{1mm}% - \color{black}% - \hspace{3mm}\raisebox{40.5mm}{{\parbox[t][47mm]{155mm}{% - \footFontSize\sffamily - Physikalisch-Technische Bundesanstalt \\ - Braunschweig und Berlin \par\vspace{1em} - \textbf{\@author} \\ - \PTB@department \\ - \PTB@workingGroup - %\rule{\linewidth}{5mm}% - }}}% - \hspace{12mm}\raisebox{40.5mm}{{\parbox[t][47mm]{125mm}{% - \footFontSize\sffamily - \begin{tabular}[t]{@{}ll@{}} - \ifx\PTB@street\@empty\else\PTB@street\\ \fi - \ifx\PTB@location\@empty\else\PTB@location\\ \fi - \ifx\PTB@phone\@empty\else Telefon:&\PTB@phone\\ \fi - \ifx\PTB@fax\@empty\else Fax:&\PTB@fax\\ \fi - \ifx\PTB@email\@empty\else E-Mail:&\PTB@email\\ \fi - www.ptb.de - \end{tabular}% - %\rule{\linewidth}{5mm}% - }}}% - \hspace{12mm}\raisebox{40.5mm}{{\parbox[t][47mm]{175mm}{% - \footFontSize\sffamily - % TODO: Siehe Lösung für abstracts - %%%$^{1}$Physikalisch-Technische Bundesanstalt \\ - %%%$^{2}$Muster Universität Forschungsstadt - %\rule{\linewidth}{5mm}% - }}}% +} + +\AddToShipoutPictureBG{% === Fuß === + \AtTextLowerLeft{% + \linethickness{.5mm}% + \put(-.5\@wholewidth-\PTB@textsep,-57mm){% + \raisebox{19mm}{\qrcode[height=47mm,tight]{\PTB@qrcode}}% + \color{PTBcolor}% + \hspace{2mm}\raisebox{-.5mm}{\rule{47mm}{47mm}}% + \hspace{2mm}\framebox(46mm,46mm){}% + %\circle*{1mm}% + \color{black}% + \hspace{3mm}\raisebox{40.5mm}{{\parbox[t][47mm]{155mm}{% + \footFontSize\sffamily + Physikalisch-Technische Bundesanstalt \\ + Braunschweig und Berlin \par\vspace{1em} + \textbf{\@author} \\ + \PTB@department \\ + \PTB@workingGroup + %\rule{\linewidth}{5mm}% + }}}% + \hspace{12mm}\raisebox{40.5mm}{{\parbox[t][47mm]{125mm}{% + \footFontSize\sffamily + \begin{tabular}[t]{@{}ll@{}} + \ifx\PTB@street\@empty\else\PTB@street\\ \fi + \ifx\PTB@location\@empty\else\PTB@location\\ \fi + \ifx\PTB@phone\@empty\else Telefon:&\PTB@phone\\ \fi + \ifx\PTB@fax\@empty\else Fax:&\PTB@fax\\ \fi + \ifx\PTB@email\@empty\else E-Mail:&\PTB@email\\ \fi + www.ptb.de + \end{tabular}% + %\rule{\linewidth}{5mm}% + }}}% + \hspace{12mm}\raisebox{40.5mm}{{\parbox[t][47mm]{175mm}{% + \footFontSize\sffamily + % TODO: Siehe Lösung für abstracts + %%%$^{1}$Physikalisch-Technische Bundesanstalt \\ + %%%$^{2}$Muster Universität Forschungsstadt + %\rule{\linewidth}{5mm}% + }}}% + } } } -- GitLab