´´Treppen auf Platten Beispiel 1 - Treppenhauses in einem mehrgeschossigen Wohnhaus Treppenlauf biegesteif Podest angeschlossen´´

Aufgabenstellung

Bild

Für den gegebenen Grundriss eines Treppenhauses in einem mehrgeschossigen Wohnhaus mit sechs Wohnungen soll eine gegenläufige Treppe Entworfen und Bemessen werden. Baustoffe, Umgebungsbedingungen und die Bauteilabmessungen wurden vorab festgelegt. Der Bauherr verzichtet auf ein besonderes maß des Schallschutzes. Als Treppenlauf Belag wurde ein Natursteinplattenbelag oberhalb und unterhalb wird die Treppe mit einem Gipsputz versehen. gewählt Gewählt wurde eine Ausführung mit Arbeitsfuge Die Podestplatten werden im Rahmen des Beispiels als einachsig gespannte platte betrachtet. Die Berechnung dient als Vergleich zu der Berechnung mit dem MB Modul

Vorgaben

Geschosshöhe ${\displaystyle h}$:	2,72m
Plattenstärke ${\displaystyle h_L}$:	20 cm
Natursteinplattenstärke ${\displaystyle N_s}$:	6,0 cm
Gipsputz ${\displaystyle G_s}$:	1,5 cm
Treppenform:	Gegenläufige Treppe
Expositionsklasse:	XC1 - trocken, ständig nass
Betonfestigkeitsklasse:	C25/30
Betonstahl:	B500

Anforderungen an Treppenkonstruktionen

geometrische Bestimmung

zu Entwerfen ist eine Treppe für ein Treppenhauses in einem mehrgeschossigen Wohnhaus mit sechs Wohnungen da die Treppe zu einem nicht zu ebener Erde liegende Geschoss führt spricht man von einer Baurechtlich notwendige Treppe

Grenzmaße ^{[N 1]}

	1	2	3	4	5	6	7
	Gebäudeart	Treppenart	minimale nutzbare Laufbreite (b) [cm]	Steigung (s) [cm]		Auftritt (a) [cm]
				min.	max.	min.	max.
1	Gebäude im Allgemeinen (Fertigmaße im Endzustand)	Baurechtlich notwendige Treppe	100	14	19	26	37
2		Baurechtlich nicht notwendige (zusätzliche)	50	14	21	21	37
3	Wohngebäude mit bis zu zwei Wohnungen und innerhalb von Wohnungen	Baurechtlich notwendige Treppe	80	14	20	23	37
4		Baurechtlich nicht notwendige (zusätzliche)	50	14	21	21	37

minimale nutzbare Laufbreite ${\displaystyle b}$

${\displaystyle b\le \underset{\_}{100cm}}$.

Steigung ${\displaystyle s}$

um die Geschosshöhe von 272 cm zu überbrücken, wurde eine gegenläufige Treppe mit jeweils 8 Steigungen pro Treppenlauf gewählt

${\displaystyle s=\frac{h}{\text{Anzahl Steigungen}}=\frac{272cm}{16}=\underset{\_}{17cm}}$

${\displaystyle 14cm\le \underset{\_}{s=17}\le 19cm}$

Auftritt ${\displaystyle a}$

${\displaystyle a-s\approx 12cm}$	${\displaystyle |+s}$
${\displaystyle a\approx s+12cm}$	${\displaystyle |mit:s=17cm}$
${\displaystyle a\approx 17cm+12cm}$
${\displaystyle a\approx 29cm}$
${\displaystyle 26cm\le \underset{\_}{a=29cm}\le 37cm}$

Überprüfung Schrittmaß

${\displaystyle 59cm\le 2\cdot s+a\le 65cm}$	${\displaystyle |mit:s=17cm}$
	${\displaystyle |mit:a=29cm}$
${\displaystyle 59cm\le 2\cdot 17cm+29\le 65cm}$
${\displaystyle 59cm\le \underset{\_}{63cm}\le 65cm}$

Treppenaugebreite ${\displaystyle b^{\text{'}}}$

Es wird ein Treppenauge von 25 cm gewählt

${\displaystyle 20cm\le b^{\text{'}}=25\le 30cm}$

• Steigungswinkel

${\displaystyle \alpha =ta{n}^{-1}(\frac{s}{a})}$	${\displaystyle |mit:s=17cm}$
	${\displaystyle |mit:a=29cm}$
${\displaystyle \alpha =ta{n}^{-1}(\frac{17cm}{29cm})}$
Fehler beim Parsen (Syntaxfehler): {\displaystyle \alpha \approx 30,38° }

Schallschutz

Da der Bauherr keine privatrechtlichen Anforderungen gestellt hat. wird bei der Planung lediglich das Mindestschallniveau nach DIN 4109 einzuhalten. Für die Konstruktion wird in dieser Treppe das typische beispiel für die Mindestanforderungen des Schallschutzes

Treppenlauf und Treppenpodest werden biegesteif miteinander verbunden. Die Treppenpodeste werden hierbei mit schwimmendem Estrich ausgestattet.Desweiteren wird der Lauf schalltechnisch mit einer Fugenplatte von den Wänden entkoppelt.

Brandschutz

es wird keine besondere Anforderungen an den Brandschutz gestellt daher reicht die Normale Betondeckung aus dem EC2.

Lösung für den Treppenlauf

Einwirkungen

Teilsicherheiten

${\displaystyle {\gamma }_{\mathrm{Q}}=1,50}$
${\displaystyle {\gamma }_{\mathrm{G}}=1,35}$

Ständige

Die ständigen Lasten werden auf den Grundriss bezogen.

${\displaystyle g_d=g_k\cdot {\gamma }_{\mathrm{G}}}$

${\displaystyle g_k=g_k^{*}+g_k^{**}}$

${\displaystyle g_k^{**}=\frac{s\cdot {\gamma }_2}{2}}$	${\displaystyle |mit:s=17cm}$
	${\displaystyle |mit:{\gamma }_2=24\frac{kN}{m^3}}$
${\displaystyle g_k^{**}=\frac{0,17m\cdot 24\frac{kN}{m^3}}{2}}$
${\displaystyle g_k^{**}=2.04\frac{kN}{m^2}}$

${\displaystyle g_k^{*}=\frac{h\cdot {\gamma }_1+{\gamma }_{G_s=1,5cm}+N_s\cdot {\gamma }_{Naturstein}}{cos(\alpha )}}$	${\displaystyle |mit:h=20cm}$
	${\displaystyle |mit:{\gamma }_1=25\frac{kN}{m^3}}$
	${\displaystyle |mit:{\gamma }_{G_s=1,5cm}=0,18\frac{kN}{m^2}}$
	${\displaystyle |mit:{\gamma }_{Naturstein}=0,3\frac{\frac{kN}{m^2}}{cm}}$
	${\displaystyle |mit:N_s=6cm}$
	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: \alpha = 30,38° }
Fehler beim Parsen (Syntaxfehler): {\displaystyle g^{*}_{k} = \frac{ 0,20m \cdot 25 \frac{kN}{m^{3}} + 0,18 \frac{kN}{m^{2}}+ 6 cm \cdot 0,3 \frac{\frac{kN}{m^{2}}}{cm} }{cos(30,38°)} }
${\displaystyle g_k^{*}\approx 8,09\frac{kN}{m^2}}$

${\displaystyle g_k=g_k^{*}+g_k^{**}}$	${\displaystyle |mit:g_k^{*}=8,09\frac{kN}{m^2}}$
	${\displaystyle |mit:g_k^{**}=2.04\frac{kN}{m^2}}$
${\displaystyle g_k=8,09\frac{kN}{m^2}+2.04\frac{kN}{m^2}}$
${\displaystyle g_k=10,13\frac{kN}{m^2}}$

${\displaystyle g_d=g_k\cdot {\gamma }_{\mathrm{G}}}$	${\displaystyle |mit:{\gamma }_{\mathrm{G}}=1,5}$
	${\displaystyle |mit:g_k=10,13\frac{kN}{m^2}}$
${\displaystyle g_d=10,13\frac{kN}{m^2}\cdot 1,5}$
${\displaystyle g_d=15,2\frac{kN}{m^2}}$

Veränderliche

Lotrechte Nutzlasten für Treppen ^{[F 1]}

	1		2	3	4	5
	Kategorie		Nutzung	Beispiele	${\displaystyle q_k[\frac{kN}{m^2}]}$	${\displaystyle Q_k[kN]}$
19	T	T1	Treppen und Treppenpodeste	Treppen und Treppenpodeste in Wohngebäuden, Bürogebäuden und von Arztpraxen ohne schweres Gerät	3,0	2,0
20		T2		alle Treppen und Treppenpodeste, die nicht in TI oder T3 eingeordnet werden können	5,0	2,0
21		T3		Zugänge und Treppen von Tribünen ohne feste Sitzplätze, die als Fluchtwege dienen	7,5	3,0

${\displaystyle \underset{\_}{q_k=3,0\frac{kN}{m^2}}}$

${\displaystyle q_d=q_k\cdot {\gamma }_{\mathrm{Q}}}$	${\displaystyle |mit:q_k=3,0\frac{kN}{m^2}}$
	${\displaystyle |mit:{\gamma }_{\mathrm{Q}}=1,5}$
${\displaystyle q_d=3,0\frac{kN}{m^2}\cdot 1,5}$
${\displaystyle q_d=4,5\frac{kN}{m^2}}$

Gesamtlasten

${\displaystyle f_d=g_d+q_d}$	${\displaystyle |mit:q_d=4,5\frac{kN}{m^2}}$
	${\displaystyle |mit:g_d=15,2\frac{kN}{m^2}}$
${\displaystyle f_d=15,2\frac{kN}{m^2}+4,5\frac{kN}{m^2}}$
${\displaystyle f_d=19,7\frac{kN}{m^2}}$

Statisches System

${\displaystyle l_L=8\cdot a}$	${\displaystyle |mit:a=29cm}$
${\displaystyle l_L=8\cdot 29cm}$
${\displaystyle l_L=2,32m}$

Bild

Schnittgrößen

maximales Feldmoment

${\displaystyle M_{Ed,F}=f_d\cdot \frac{l_L^2}{8}}$	${\displaystyle |mit:f_d=19,7\frac{kN}{m^2}}$
	${\displaystyle |mit:l_L=2,32m}$
${\displaystyle M_{Ed,F}=19,7\frac{kN}{m^2}\cdot \frac{2,32m^2}{8}}$
${\displaystyle M_{Ed,F}=13.25\frac{kNm}{m}}$

Stützmoment

${\displaystyle M_{Ed,S}=-f_d\cdot \frac{l_L^2}{16}}$	${\displaystyle |mit:f_d=19,7\frac{kN}{m^2}}$
	${\displaystyle |mit:l_L=2,32m}$
${\displaystyle M_{Ed,S}=-19,7\frac{kN}{m^2}\cdot \frac{2,32m^2}{16}}$
${\displaystyle M_{Ed,S}=6.63\frac{kNm}{m}}$

Auflagekraft

${\displaystyle C_{Ed}=f_d\cdot \frac{l_L}{2}}$	${\displaystyle |mit:f_d=19,7\frac{kN}{m^2}}$
	${\displaystyle |mit:l_L=2,32m}$
${\displaystyle C_{Ed}=19,7\frac{kN}{m^2}\cdot \frac{2,32m}{2}}$
${\displaystyle C_{Ed}=22.86\frac{kN}{m}}$

Maximale Normalkraft

${\displaystyle extrn=\pm C_{Ed}\cdot sin(\alpha )}$	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: \alpha = 30,38° }
	${\displaystyle |mit:C_{Ed}=22.86\frac{kN}{m}}$
Fehler beim Parsen (Syntaxfehler): {\displaystyle extr n = \pm 22.86 \frac{kN}{m} \cdot sin( 30,38° ) }
${\displaystyle extrn=\pm 11,56\frac{kN}{m}}$

Bemessung im Grenzzustand der Tragfähigkeit

Materialparameter

${\displaystyle f_{cd}=\frac{{\alpha }_{cc}\cdot f_{ck}}{{\gamma }_C}}$	${\displaystyle |mit:{\gamma }_C=1.5}$
	${\displaystyle |mit:{\alpha }_{cc}=0.85}$
	${\displaystyle |mit:f_{ck}=25\frac{kN}{c{m}^2}}$
${\displaystyle f_{cd}=\frac{0.85\cdot 25\frac{kN}{c{m}^2}}{1.5}}$
${\displaystyle f_{cd}=14,2\frac{kN}{c{m}^2}}$

${\displaystyle f_{yd}=\frac{f_{yk}}{{\gamma }_s}}$	${\displaystyle |mit:f_{yk}=500\frac{N}{m{m}^2}}$
	${\displaystyle |mit:{\gamma }_s=1.15}$
${\displaystyle f_{yd}=\frac{50\frac{kN}{c{m}^2}}{1,15}}$
${\displaystyle f_{yd}=43,5\frac{kN}{c{m}^2}}$

Biegebemessung

Feldbereich des Lauf´s

Vorbemessung

${\displaystyle z_{est}=0,75\cdot h}$	${\displaystyle |mit:h=h_L=20cm}$
${\displaystyle z_{est}=0,75\cdot 20cm}$
${\displaystyle z_{est}=15cm}$

${\displaystyle M_{Ed,est}=M_{Ed}-N_{Ed}\cdot z_{s1,est}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:N_{Ed}=0}$
	${\displaystyle |mit:M_{Ed}=M_{Ed,F}=13.25\frac{kNm}{m}}$
${\displaystyle M_{Ed,est}=13.25\frac{kNm}{m}-0kN\cdot 0,15m}$
${\displaystyle M_{Ed,est}=13.25\frac{kNm}{m}}$

${\displaystyle A_{s,est}=\frac{M_{Ed,est}}{z_{s1,est}\cdot f_{yd}}+\frac{N_{Ed}}{f_{yd}}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:f_{yd}=43,5\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:N_{Ed}=0}$
	${\displaystyle |mit:M_{Ed,est}=13.25\frac{kNm}{m}}$
${\displaystyle A_{s,est}=\frac{1325\frac{kNcm}{m}}{15cm\cdot 43,5\frac{kN}{c{m}^2}}+\frac{0}{43,55\frac{kN}{c{m}^2}}}$
${\displaystyle A_{s,est}\approx 2,03\frac{kNcm}{m}}$

gewählt: R257 ø7/15cm, ${\displaystyle a_s}=2,57\frac{c{m}^2}{m}$

Querschnittsgeometrie

Fehler beim Parsen (Unbekannte Funktion „\begin{cases}“): {\displaystyle c_{v}=\mathrm{max}\begin{cases} C_{nom,dur} \\ C_{nom,b,Bü} \\ C_{nom,b,L} \end{cases}}

${\displaystyle C_{nom,dur}=C_{min,dur}+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,dur}=10mm}$ für XC1
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
${\displaystyle C_{nom,dur}=10mm+10mm}$
${\displaystyle C_{nom,dur}=20mm}$

Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = C_{min,b,Bü} + \Delta C_{dev} }	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: C_{min,b,Bü} = 0 mm }
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 0 mm + 10 mm }
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 10 mm }

${\displaystyle C_{nom,b,L}=C_{min,b,L}-\varnothing bue+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,b,L}=7mm}$
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
${\displaystyle C_{nom,b,L}=7mm-0mm+\mathrm{\Delta }10mm}$
${\displaystyle C_{nom,b,L}=17mm}$

${\displaystyle c_v=\mathrm{m}\mathrm{a}\mathrm{x}\{\begin{array}{l}20mm\\ 10mm\\ 17mm\end{array}}$

${\displaystyle d_1=c_v+\varnothing bue+\frac{\varnothing L}{2}}$	${\displaystyle |mit:c_v=20mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
	${\displaystyle |mit:\varnothing L=7mm}$
${\displaystyle d_1=20mm+0mm+\frac{7mm}{2}}$
${\displaystyle d_1=23,5mm}$

${\displaystyle d=h_L-d_1}$	${\displaystyle |mit:d_1=27mm}$
	${\displaystyle |mit:h_L=200mm}$
${\displaystyle d=200mm-23,5mm}$
${\displaystyle d=176,5mm\approx 17,6cm}$

Bemessung mit dem ω-Verfahren

${\displaystyle {\mu }_{Eds}=\frac{M_{Eds}}{b\cdot d^2\cdot f_{cd}}}$	${\displaystyle |mit:d=17,6cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:M_{Ed}=M_{Ed,F}=1325\frac{kNcm}{m}}$
${\displaystyle {\mu }_{Eds}=\frac{1325\frac{kNcm}{m}}{100cm\cdot (17,6cm{)}^2\cdot 1,42\frac{kN}{c{m}^2}}}$
${\displaystyle {\mu }_{Eds}=0,03012}$

${\displaystyle \omega ={\omega }_1+\frac{{\omega }_2-{\omega }_1}{{\mu }_{Eds,2}-{\mu }_{Eds,1}}\cdot ({\mu }_{Eds}-{\mu }_{Eds,1})}$	${\displaystyle |mit:{\omega }_1=0,03012}$
	${\displaystyle |mit:{\omega }_2=0,0410}$
	${\displaystyle |mit:{\mu }_{Eds}=0,0312}$
	${\displaystyle |mit:{\mu }_{Eds,1}=0,03}$
	${\displaystyle |mit:{\mu }_{Eds,2}=0,04}$
${\displaystyle \omega =0,0306+\frac{0,0410-0,0306}{0,04-0,03}\cdot (0,03012-0,03)}$
${\displaystyle \omega =0,0307}$

${\displaystyle a_{s,1}=\frac{1}{{\sigma }_{sd}}\cdot (\omega \cdot b\cdot d\cdot f_{cd}+N_{Ed})}$	${\displaystyle |mit:\omega =0,0307}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:d=17,3cm}$#
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:N_{Ed}=0kN}$
${\displaystyle a_{s,1}=\frac{1}{43,5\frac{kN}{c{m}^2}}\cdot (0,0307\cdot 100cm\cdot 17,3cm\cdot 1,42\frac{kN}{c{m}^2}+0kN)}$
${\displaystyle a_{s,1}=1,73\frac{c{m}^2}{m}}$

gewählt:R257 ø7/15cm, ${\displaystyle a_{sw}}=2,57\frac{c{m}^2}{m}$

Bereich der Arbeitsfuge Kopfpunkt

Vorbemessung

${\displaystyle z_{est}=0,75\cdot h}$	${\displaystyle |mit:h=h_L=20cm}$
${\displaystyle z_{est}=0,75\cdot 20cm}$
${\displaystyle z_{est}=15cm}$

${\displaystyle M_{Ed,est}=M_{Ed}-N_{Ed}\cdot z_{s1,est}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:N_{Ed}=extrn=-11,56\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed}=M_{Ed,S}=6.63\frac{kNm}{m}}$
${\displaystyle M_{Ed,est}=6.63\frac{kNm}{m}-(-11,56\frac{kN}{m})\cdot 0,15m}$
${\displaystyle M_{Ed,est}=8.36\frac{kNm}{m}}$

${\displaystyle a_{s,est}=\frac{M_{Ed,est}}{z_{s1,est}\cdot f_{yd}}+\frac{N_{Ed}}{f_{yd}}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:f_{yd}=43,5\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:N_{Ed}=extrn=-11,56\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed,est}=6.63\frac{kNm}{m}}$
${\displaystyle a_{s,est}=\frac{8.36\frac{kNm}{m}}{15cm\cdot 43,5\frac{kN}{c{m}^2}}+\frac{-11,56\frac{kN}{m}}{43,5\frac{kN}{c{m}^2}}}$
${\displaystyle a_{s,est}\approx 1,02\frac{kNcm}{m}}$

gewählt: R188 ø6/15cm, ${\displaystyle a_s}=1,88\frac{c{m}^2}{m}$

Querschnittsgeometrie

Fehler beim Parsen (Unbekannte Funktion „\begin{cases}“): {\displaystyle c_{v}=\mathrm{max}\begin{cases} C_{nom,dur} \\ C_{nom,b,Bü} \\ C_{nom,b,L} \end{cases}}

${\displaystyle C_{nom,dur}=C_{min,dur}+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,dur}=10mm}$ für XC1
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
${\displaystyle C_{nom,dur}=10mm+10mm}$
${\displaystyle C_{nom,dur}=20mm}$

Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = C_{min,b,Bü} + \Delta C_{dev} }	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: C_{min,b,Bü} = 0 mm }
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 0 mm + 10 mm }
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 10 mm }

${\displaystyle C_{nom,b,L}=C_{min,b,L}-\varnothing bue+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,b,L}=7mm}$
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
${\displaystyle C_{nom,b,L}=6mm-0mm+\mathrm{\Delta }10mm}$
${\displaystyle C_{nom,b,L}=16mm}$

${\displaystyle c_v=\mathrm{m}\mathrm{a}\mathrm{x}\{\begin{array}{l}20mm\\ 10mm\\ 16mm\end{array}}$

${\displaystyle d_1=c_v+\varnothing bue+\frac{\varnothing L}{2}}$	${\displaystyle |mit:c_v=20mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
	${\displaystyle |mit:\varnothing L=6mm}$
${\displaystyle d_1=20mm+0mm+\frac{6mm}{2}}$
${\displaystyle d_1=23,0mm}$

${\displaystyle d=h_L-d_1}$	${\displaystyle |mit:d_1=23mm}$
	${\displaystyle |mit:h_L=200mm}$
${\displaystyle d=200mm-23,0mm}$
${\displaystyle d=177mm=17,7cm}$

Bemessung mit dem ω-Verfahren

${\displaystyle z_s=d-\frac{h_L}{2}}$	${\displaystyle |mit:d=17,7cm}$
	${\displaystyle |mit:h_L=20cm}$
${\displaystyle z_s=17,7cm-\frac{20cm}{2}}$
${\displaystyle z_s=7,7cm}$

${\displaystyle M_{Eds}=M_{Ed,S}-extrn\cdot z_s}$	${\displaystyle |mit:z_s=7,7cm}$
	${\displaystyle |extrn=(-11,56)\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed,S}=663\frac{kNcm}{m}}$
${\displaystyle M_{Eds}=663\frac{kNcm}{m}-(-11,56)\frac{kN}{m}\cdot 7,7cm}$
${\displaystyle M_{Eds}=752,01\frac{kNcm}{m}}$

${\displaystyle {\mu }_{Eds}=\frac{M_{Eds}}{b\cdot d^2\cdot f_{cd}}}$	${\displaystyle |mit:d=17,7cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:M_{Eds}=752,01\frac{kNcm}{m}}$
${\displaystyle {\mu }_{Eds}=\frac{752,01\frac{kNcm}{m}}{100cm\cdot (17,7cm{)}^2\cdot 1,42\frac{kN}{c{m}^2}}}$
${\displaystyle {\mu }_{Eds}=0,0169}$

${\displaystyle \omega ={\omega }_1+\frac{{\omega }_2-{\omega }_1}{{\mu }_{Eds,2}-{\mu }_{Eds,1}}\cdot ({\mu }_{Eds}-{\mu }_{Eds,1})}$	${\displaystyle |mit:{\omega }_1=0,0101}$
	${\displaystyle |mit:{\omega }_2=0,0203}$
	${\displaystyle |mit:{\mu }_{Eds}=0,0169}$
	${\displaystyle |mit:{\mu }_{Eds,1}=0,01}$
	${\displaystyle |mit:{\mu }_{Eds,2}=0,02}$
${\displaystyle \omega =0,0101+\frac{0,0203-0,0101}{0,02-0,01}\cdot (0,0169-0,01)}$
${\displaystyle \omega =0,01714}$

${\displaystyle a_{s,1}=\frac{1}{{\sigma }_{sd}}\cdot (\omega \cdot b\cdot d\cdot f_{cd}+N_{Ed})}$	${\displaystyle |mit:\omega =0,01714}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:d=17,7cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:N_{Ed}=extrn=(-11,56)\frac{kN}{m}}$
${\displaystyle a_{s,1}=\frac{1}{43,5\frac{kN}{c{m}^2}}\cdot (0,0151\cdot 100cm\cdot 17,7cm\cdot 1,42\frac{kN}{c{m}^2}+(-11,56)\frac{kN}{m})}$
${\displaystyle a_{s,1}=0,61\frac{c{m}^2}{m}}$

gewählt: R188 ø6/15cm, ${\displaystyle a_s}=1,88\frac{c{m}^2}{m}$

Bereich der Arbeitsfuge Fußpunkt

Vorbemessung

${\displaystyle z_{est}=0,75\cdot h}$	${\displaystyle |mit:h=h_L=20cm}$
${\displaystyle z_{est}=0,75\cdot 20cm}$
${\displaystyle z_{est}=15cm}$

${\displaystyle M_{Ed,est}=M_{Ed}-N_{Ed}\cdot z_{s1,est}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:N_{Ed}=extrn=11,56\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed}=M_{Ed,S}=6.63\frac{kNm}{m}}$
${\displaystyle M_{Ed,est}=6.63\frac{kNm}{m}-11,56\frac{kN}{m}\cdot 0,15m}$
${\displaystyle M_{Ed,est}=4.9\frac{kNm}{m}}$

${\displaystyle a_{s,est}=\frac{M_{Ed,est}}{z_{s1,est}\cdot f_{yd}}+\frac{N_{Ed}}{f_{yd}}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:f_{yd}=43,5\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:N_{Ed}=extrn=11,56\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed,est}=4.9\frac{kNm}{m}}$
${\displaystyle a_{s,est}=\frac{490\frac{kNcm}{m}}{15cm\cdot 43,5\frac{kN}{c{m}^2}}+\frac{11,56\frac{kN}{m}}{43,5\frac{kN}{c{m}^2}}}$
${\displaystyle a_{s,est}\approx 1,02\frac{kNcm}{m}}$

gewählt: R188 ø6/15cm, ${\displaystyle a_s}=1,88\frac{c{m}^2}{m}$

Querschnittsgeometrie

Fehler beim Parsen (Unbekannte Funktion „\begin{cases}“): {\displaystyle c_{v}=\mathrm{max}\begin{cases} C_{nom,dur} \\ C_{nom,b,Bü} \\ C_{nom,b,L} \end{cases}}

${\displaystyle C_{nom,dur}=C_{min,dur}+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,dur}=10mm}$ für XC1
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
${\displaystyle C_{nom,dur}=10mm+10mm}$
${\displaystyle C_{nom,dur}=20mm}$

Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = C_{min,b,Bü} + \Delta C_{dev} }	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: C_{min,b,Bü} = 0 mm }
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 0 mm + 10 mm }
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 10 mm }

${\displaystyle C_{nom,b,L}=C_{min,b,L}-\varnothing bue+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,b,L}=7mm}$
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
${\displaystyle C_{nom,b,L}=6mm-0mm+\mathrm{\Delta }10mm}$
${\displaystyle C_{nom,b,L}=16mm}$

${\displaystyle c_v=\mathrm{m}\mathrm{a}\mathrm{x}\{\begin{array}{l}20mm\\ 10mm\\ 16mm\end{array}}$

${\displaystyle d_1=c_v+\varnothing bue+\frac{\varnothing L}{2}}$	${\displaystyle |mit:c_v=20mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
	${\displaystyle |mit:\varnothing L=6mm}$
${\displaystyle d_1=20mm+0mm+\frac{6mm}{2}}$
${\displaystyle d_1=23,0mm}$

${\displaystyle d=h_L-d_1}$	${\displaystyle |mit:d_1=23mm}$
	${\displaystyle |mit:h_L=200mm}$
${\displaystyle d=200mm-23,0mm}$
${\displaystyle d=177mm=17,7cm}$

Bemessung mit dem ω-Verfahren

${\displaystyle z_s=d-\frac{h_L}{2}}$	${\displaystyle |mit:d=17,7cm}$
	${\displaystyle |mit:h_L=20cm}$
${\displaystyle z_s=17,7cm-\frac{20cm}{2}}$
${\displaystyle z_s=7,7cm}$

${\displaystyle M_{Eds}=M_{Ed,S}-extrn\cdot z_s}$	${\displaystyle |mit:z_s=7,7cm}$
	${\displaystyle |extrn=11,56\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed,S}=663\frac{kNcm}{m}}$
${\displaystyle M_{Eds}=663\frac{kNcm}{m}-11,56\frac{kN}{m}\cdot 7,7cm}$
${\displaystyle M_{Eds}=573.988\frac{kNcm}{m}}$

${\displaystyle {\mu }_{Eds}=\frac{M_{Eds}}{b\cdot d^2\cdot f_{cd}}}$	${\displaystyle |mit:d=17,7cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:M_{Eds}=573.99\frac{kNcm}{m}}$
${\displaystyle {\mu }_{Eds}=\frac{573.99\frac{kNcm}{m}}{100cm\cdot (17,7cm{)}^2\cdot 1,42\frac{kN}{c{m}^2}}}$
${\displaystyle {\mu }_{Eds}=0,0129}$

${\displaystyle \omega ={\omega }_1+\frac{{\omega }_2-{\omega }_1}{{\mu }_{Eds,2}-{\mu }_{Eds,1}}\cdot ({\mu }_{Eds}-{\mu }_{Eds,1})}$	${\displaystyle |mit:{\omega }_1=0,0101}$
	${\displaystyle |mit:{\omega }_2=0,0203}$
	${\displaystyle |mit:{\mu }_{Eds}=0,0129}$
	${\displaystyle |mit:{\mu }_{Eds,1}=0,01}$
	${\displaystyle |mit:{\mu }_{Eds,2}=0,02}$
${\displaystyle \omega =0,0101+\frac{0,0203-0,0101}{0,02-0,01}\cdot (0,0169-0,01)}$
${\displaystyle \omega =0,01306}$

${\displaystyle a_{s,1}=\frac{1}{{\sigma }_{sd}}\cdot (\omega \cdot b\cdot d\cdot f_{cd}+N_{Ed})}$	${\displaystyle |mit:\omega =0,01306}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:d=17,7cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:N_{Ed}=extrn=11,56\frac{kN}{m}}$
${\displaystyle a_{s,1}=\frac{1}{43,5\frac{kN}{c{m}^2}}\cdot (0,0151\cdot 100cm\cdot 17,7cm\cdot 1,42\frac{kN}{c{m}^2}+11,56\frac{kN}{m})}$
${\displaystyle a_{s,1}=1,02\frac{c{m}^2}{m}}$

gewählt: R188 ø6/15cm, ${\displaystyle a_s}=1,88\frac{c{m}^2}{m}$

Querkraftbemessung

Bauteile ohne Querkraftbewehrung

${\displaystyle V_{Ed}=C_{Ed}\cdot cos(\alpha )}$	${\displaystyle |mit:C_{Ed}=22.86\frac{kN}{m}}$
	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: \alpha = 30,38° }
Fehler beim Parsen (Syntaxfehler): {\displaystyle V_{Ed} = 22.86 \frac{kN}{m} \cdot cos( 30,38° ) }
${\displaystyle V_{Ed}=19.72\frac{kN}{m}}$

${\displaystyle C_{Rdc}=\frac{0,15}{{\gamma }_c}}$	${\displaystyle |mit:{\gamma }_c=1,5}$
${\displaystyle C_{Rdc}=\frac{0,15}{1,5}}$
${\displaystyle C_{Rdc}=0,1}$

${\displaystyle k=1+\sqrt{\frac{200}{d}}}$	${\displaystyle \{\begin{array}{l}\ge 1,0\\ \le 2,0\end{array}}$
	${\displaystyle |mit:d=177mm}$
${\displaystyle k=1+\sqrt{\frac{200}{177}}}$
${\displaystyle k=2,06}$	${\displaystyle \{\begin{array}{l}\ge 1,0\\ \ge 2,0\end{array}}$
${\displaystyle k=2}$

${\displaystyle {\rho }_l=\frac{A_{sl}}{b_w\cdot d}}$	${\displaystyle \le 0,02}$
	${\displaystyle |mit:A_{sl}=1,88\frac{c{m}^2}{m}}$
	${\displaystyle |mit:b_w=100cm}$
	${\displaystyle |mit:d=17,7cm}$
${\displaystyle {\rho }_l=\frac{1,88\frac{c{m}^2}{m}}{100cm\cdot 17,7cm}}$
${\displaystyle {\rho }_l=1,06\cdot 10^{-3}}$	${\displaystyle \le 0,02}$

${\displaystyle A_c=A-A_s}$	${\displaystyle |mit:A=b_w\cdot h_L=b_w\cdot h_L=1000mm\cdot 200mm=200000}$
	${\displaystyle |mit:A_{s,R188,R257}=188\frac{m{m}^2}{m}+257\frac{m{m}^2}{m}=445\frac{m{m}^2}{m}}$
${\displaystyle A_c=200000m{m}^2-445m{m}^2}$
${\displaystyle A_c=199555m{m}^2}$

${\displaystyle {\sigma }_{cp}=\frac{N_{Ed}}{A_c}}$	${\displaystyle |mit:N_{Ed}=extrn=\pm 11560\frac{N}{m}}$
	${\displaystyle |mit:A_c=199555m{m}^2}$
${\displaystyle {\sigma }_{cp}=\frac{11560\frac{N}{m}}{199555m{m}^2}}$
${\displaystyle {\sigma }_{cp}\approx 0,06\frac{N}{m\cdot m{m}^2}}$

${\displaystyle V_{Rd,c}=[C_{Rdc}\cdot k\cdot {(100\cdot {\rho }_l\cdot f_{ck})}^{\frac{1}{3}}+0,12\cdot {\sigma }_{cp}]\cdot b_w\cdot d}$	${\displaystyle |mit:{\sigma }_{cp}=0,06\frac{N}{m{m}^2}}$
	${\displaystyle |mit:{\rho }_l=1,06\cdot 10^{-3}}$
	${\displaystyle |mit:k=2}$
	${\displaystyle |mit:C_{Rdc}=0,1}$
	${\displaystyle |mit:f_{ck}=25\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:b_w=1000mm}$
	${\displaystyle |mit:d=177mm}$
${\displaystyle V_{Rd,c}=[0,1\cdot 2\cdot {(100\cdot 1,06\cdot 10^{-3}\cdot 25\frac{N}{m{m}^2})}^{\frac{1}{3}}+0,12\cdot 0,06\frac{N}{m{m}^2}]\cdot 1000mm\cdot 177mm}$
${\displaystyle V_{Rd,c}=50261N}$	${\displaystyle \ge V_{Ed}}$
${\displaystyle V_{Rd,c}=50,26kN}$	${\displaystyle \ge 19.72kN}$

Weitere Bemessung Hinsichtlich der Querkraft für dieses Bauteil nicht erforderlich da der Nachweis erfüllt ist .

Bemessung im Grenzzustand der Gebrauchstauglichkeit

Begrenzung der Biegeschlankheit des Treppenlauf

${\displaystyle \frac{l}{d}\le K[11+1,5\cdot \sqrt{f_{ck}}\cdot \frac{{\rho }_0}{\rho }+3,2\cdot \sqrt{f_{ck}}\cdot (\frac{{\rho }_0}{\rho }-1{)}^{3/2}]\le {\left(\frac{l}{d}\right)}_{max}}$		für: ${\displaystyle \rho \le {\rho }_0}$
${\displaystyle \frac{l}{d}\le K[11+1,5\sqrt{f_{ck}}\cdot \frac{{\rho }_0}{\rho -{\rho }_{\text{'}}}+\frac{1}{12}\cdot \sqrt{f_{ck}}\cdot (\frac{{\rho }_{\text{'}}}{{\rho }_0}{)}^{1/2}]\le {\left(\frac{l}{d}\right)}_{max}}$		für: ${\displaystyle \rho >{\rho }_0}$

${\displaystyle {\rho }_0=10^{-3}\cdot \sqrt{f_{ck}}}$	${\displaystyle |mit:f_{ck}=25\frac{N}{m{m}^2}}$
${\displaystyle {\rho }_0=10^{-3}\cdot \sqrt{25\frac{N}{m{m}^2}}}$
${\displaystyle {\rho }_0=5\cdot 10^{-3}}$

${\displaystyle \rho =\frac{A_{s1}}{b\cdot d}}$	${\displaystyle |mit:A_{s1}=2,57\frac{c{m}^2}{m}}$
	${\displaystyle |mit:d=17,3cm}$
	${\displaystyle |mit:b=100cm}$
${\displaystyle \rho =\frac{2,57\frac{c{m}^2}{m}}{100cm\cdot 17,3cm}}$
${\displaystyle \rho =1,49\cdot 10^{-3}}$	${\displaystyle \le {\rho }_0}$

${\displaystyle \frac{l}{d}\le K[11+1,5\cdot \sqrt{f_{ck}}\cdot \frac{{\rho }_0}{\rho }+3,2\cdot \sqrt{f_{ck}}\cdot (\frac{{\rho }_0}{\rho }-1{)}^{3/2}]\le {\left(\frac{l}{d}\right)}_{max}}$

${\displaystyle {\left(\frac{l}{d}\right)}_{vorh}=\frac{l}{d}}$	${\displaystyle |mit:d=0,173m}$
	${\displaystyle |mit:l=\sqrt{(8\cdot 0,29m{)}^2+(8\cdot 0,17m{)}^2}=2,69m}$
${\displaystyle {\left(\frac{l}{d}\right)}_{vorh}=\frac{2,69m}{0,173m}}$
${\displaystyle {\left(\frac{l}{d}\right)}_{vorh}=15,55}$

${\displaystyle {\frac{l}{d}}_{zul}=K[11+1,5\cdot \sqrt{f_{ck}}\cdot \frac{{\rho }_0}{\rho }+3,2\cdot \sqrt{f_{ck}}\cdot (\frac{{\rho }_0}{\rho }-1{)}^{3/2}]}$	${\displaystyle |mit:K_{Innenfeld}=1,5}$
	${\displaystyle |mit:f_{ck}=25\frac{N}{m{m}^2}}$
	${\displaystyle |mit:\rho =1,49\cdot 10^{-3}}$
	${\displaystyle |mit:{\rho }_0=5\cdot 10^{-3}}$
${\displaystyle {\frac{l}{d}}_{zul}=1,5[11+1,5\cdot \sqrt{25\frac{N}{m{m}^2}}\cdot \frac{5\cdot 10^{-3}}{1,49\cdot 10^{-3}}+3,2\cdot \sqrt{25\frac{N}{m{m}^2}}\cdot (\frac{5\cdot 10^{-3}}{1,49\cdot 10^{-3}}-1{)}^{3/2}]}$
${\displaystyle {\frac{l}{d}}_{zul}=155.64}$	${\displaystyle \ge {\left(\frac{l}{d}\right)}_{vorh}}$

${\displaystyle {\left(\frac{l}{d}\right)}_{max}\le \{\begin{array}{l}K\cdot 35\\ K^2\cdot \frac{150}{l}\end{array}}$

${\displaystyle {\left(\frac{l}{d}\right)}_{max}K\cdot 35}$	${\displaystyle |mit:K_{Innenfeld}=1,5}$
${\displaystyle {\left(\frac{l}{d}\right)}_{max}=1,5\cdot 35}$
${\displaystyle {\left(\frac{l}{d}\right)}_{max}=52,5}$	${\displaystyle \ge {\left(\frac{l}{d}\right)}_{vorh}}$

${\displaystyle {\left(\frac{l}{d}\right)}_{max}=K^2\cdot \frac{150}{l}}$	${\displaystyle |mit:K_{Innenfeld}=1,5}$
	${\displaystyle |mit:l=\sqrt{(8\cdot 0,29m{)}^2+(8\cdot 0,17m{)}^2}=2,69m}$
${\displaystyle {\left(\frac{l}{d}\right)}_{max}=1,5^2\cdot \frac{150}{2,69m}}$
${\displaystyle {\left(\frac{l}{d}\right)}_{max}=125,46}$	${\displaystyle \ge {\left(\frac{l}{d}\right)}_{vorh}}$

Lösung des Zwischenpodest

Das Zwischenpodest wird in diesem Beispiel anders als das Hauptpodest als Dreiseitig gelagert und somit zweiseitig gespannt betrachtet

Einwirkungen

Teilsicherheiten

${\displaystyle {\gamma }_{\mathrm{Q}}=1,50}$
${\displaystyle {\gamma }_{\mathrm{G}}=1,35}$

Ständige

${\displaystyle g_d=g_k\cdot {\gamma }_{\mathrm{G}}}$

${\displaystyle g_k=h\cdot {\gamma }_1+{\gamma }_{G_s=1,5cm}+N_s\cdot {\gamma }_{Naturstein}+{\gamma }_{Estrich}\cdot d_{Estrich}}$	${\displaystyle |mit:h_P=20cm}$
	${\displaystyle |mit:{\gamma }_1=25\frac{kN}{m^3}}$
	${\displaystyle |mit:{\gamma }_{G_s=1,5cm}=0,18\frac{kN}{m^2}}$
	${\displaystyle |mit:{\gamma }_{Naturstein}=0,3\frac{\frac{kN}{m^2}}{cm}}$
	${\displaystyle |mit:N_s=3cm}$
	${\displaystyle |mit:{\gamma }_{Estrich}=22\frac{\frac{kN}{m^2}}{cm}}$
	${\displaystyle |mit:d_{Estrich}=4cm}$
	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: \gamma_{Trittschalldämmung} = 0,01 \frac{\frac{kN}{m^{2}}}{cm} }
	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: d_{Trittschalldämmung} = 4 cm }
${\displaystyle g_k=0,20m\cdot 25\frac{kN}{m^3}+0,18\frac{kN}{m^2}+3cm\cdot 0,3\frac{\frac{kN}{m^2}}{cm}+0,01\frac{\frac{kN}{m^2}}{cm}\cdot 4cm+0,22\frac{\frac{kN}{m^2}}{cm}\cdot 4cm}$
${\displaystyle g_k=7\frac{kN}{m^2}}$

${\displaystyle g_d=g_k\cdot {\gamma }_{\mathrm{G}}}$	${\displaystyle |mit:{\gamma }_{\mathrm{G}}=1,5}$
	${\displaystyle |mit:g_k=7\frac{kN}{m^2}}$
${\displaystyle g_d=7\frac{kN}{m^2}\cdot 1,5}$
${\displaystyle g_d=10,5\frac{kN}{m^2}}$

Veränderliche

Lotrechte Nutzlasten für Treppen ^{[F 1]}

	1		2	3	4	5
	Kategorie		Nutzung	Beispiele	${\displaystyle q_k[\frac{kN}{m^2}]}$	${\displaystyle Q_k[kN]}$
19	T	T1	Treppen und Treppenpodeste	Treppen und Treppenpodeste in Wohngebäuden, Bürogebäuden und von Arztpraxen ohne schweres Gerät	3,0	2,0
20		T2		alle Treppen und Treppenpodeste, die nicht in TI oder T3 eingeordnet werden können	5,0	2,0
21		T3		Zugänge und Treppen von Tribünen ohne feste Sitzplätze, die als Fluchtwege dienen	7,5	3,0

${\displaystyle \underset{\_}{q_k=3,0\frac{kN}{m^2}}}$

${\displaystyle q_d=q_k\cdot {\gamma }_{\mathrm{Q}}}$	${\displaystyle |mit:q_k=3,0\frac{kN}{m^2}}$
	${\displaystyle |mit:{\gamma }_{\mathrm{Q}}=1,5}$
${\displaystyle q_d=3,0\frac{kN}{m^2}\cdot 1,5}$
${\displaystyle q_d=4,5\frac{kN}{m^2}}$

Gesamt Einwirkungen

${\displaystyle F_d=g_d+q_d}$	${\displaystyle |mit:q_d=4,5\frac{kN}{m^2}}$
	${\displaystyle |mit:g_d=10,5\frac{kN}{m^2}}$
${\displaystyle F_d=10,5\frac{kN}{m^2}+4,5\frac{kN}{m^2}}$
${\displaystyle F_d=15,0\frac{kN}{m^2}}$

${\displaystyle F_0=C_{Ed}}$	${\displaystyle |mit:C_{Ed}=22.86\frac{kN}{m}}$
${\displaystyle F_0=22.86\frac{kN}{m}}$

${\displaystyle m_0=M_{Ed,S}}$	${\displaystyle |mit:M_{Ed,S}=6.63\frac{kNm}{m}}$
${\displaystyle m_0=6.63\frac{kNm}{m}}$

Statisches System

Es wurde sich im Rahmen dieses Beispiels für eine Zwischenpodestplatte mit dreiseitig frei drehbar gelagerten Rändern entschieden.

${\displaystyle a_1=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}\frac{h_P}{2}\\ \frac{t}{2}\end{array}}$
	${\displaystyle |mit:h_P=20cm}$
	${\displaystyle |mit:t_1=36,5cm}$
${\displaystyle a_1=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}\frac{20cm}{2}\\ \frac{36,5cm}{2}\end{array}}$
${\displaystyle a_1=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}10cm\\ 18,25cm\end{array}}$
${\displaystyle a_1=10cm}$

${\displaystyle a_2=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}\frac{h_P}{2}\\ \frac{t}{2}\end{array}}$
	${\displaystyle |mit:h_P=20cm}$
	${\displaystyle |mit:t_2=24cm}$
${\displaystyle a_2=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}\frac{20cm}{2}\\ \frac{24cm}{2}\end{array}}$
${\displaystyle a_2=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}10cm\\ 12cm\end{array}}$
${\displaystyle a_2=10cm}$

${\displaystyle b_P=2\cdot b+b^{\text{'}}+a_2+a_2}$	${\displaystyle |mit:b=1,0m}$
	${\displaystyle |mit:a_1=0,1m}$
	${\displaystyle |mit:a_2=0,1m}$
	${\displaystyle |mit:b^{\text{'}}=0,25m}$
${\displaystyle b_P=2\cdot 1,0m+0,25m+0,1m+0,1m}$
${\displaystyle b_P=2,45m}$

${\displaystyle a_1=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}\frac{h_P}{2}\\ \frac{t}{2}\end{array}}$
	${\displaystyle |mit:h_P=20cm}$
	${\displaystyle |mit:t_1=12,5cm}$
${\displaystyle a_1=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}\frac{20cm}{2}\\ \frac{12,5cm}{2}\end{array}}$
${\displaystyle a_1=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}10cm\\ \approx 6cm\end{array}}$
${\displaystyle a_1=6cm}$

${\displaystyle t_P=ln+a_1+a_2}$	${\displaystyle |mit:b=1,0m}$
	${\displaystyle |mit:a_1=0,1m}$
	${\displaystyle |mit:a_2=0m}$
${\displaystyle t_P=1,0m+0,06m+0m}$
${\displaystyle t_P=1,06m}$

Schnittgrößen

Verhältnis Podesttiefe zu Podestbreite feststellen

${\displaystyle \frac{t_P}{b_P}}$	${\displaystyle |mit:b_P=2,45m}$
	${\displaystyle |mit:t_P=1,06m}$
${\displaystyle \frac{t_P}{b_P}=\frac{1,06m}{2,45m}}$
${\displaystyle \frac{t_P}{b_P}\approx 0,4}$

Ermittnlung der Momente über Tabelle

Tafel zur Schnittgrößen Ermittlung von Podestplatten mit dreiseitig frei drehbar gelagerten Rändern ^{[F 2] [F 3]}

	1	2	3
	Belastungsvariante	${\displaystyle \frac{t_P}{b_P}}$	0,4
			${\displaystyle \chi }$
1	I	${\displaystyle m_{x,m}=\frac{F_d\cdot t_P^2}{\chi }}$	8,04
2		${\displaystyle m_{y,m}=\frac{F_d\cdot t_P^2}{\chi }}$	10,5
3		${\displaystyle m_{x,r}=\frac{F_d\cdot t_P^2}{\chi }}$	4,41
4	II	${\displaystyle m_{x,m}=\frac{F_0\cdot b_P}{\chi }}$	10,5
5		${\displaystyle m_{x,m}=-\frac{F_0\cdot b_P}{\chi }}$	91,0
6		${\displaystyle m_{x,r}=\frac{F_0\cdot b_P}{\chi }}$	5,60
7	III	${\displaystyle m_{y,m}=\frac{m_0}{\chi }}$	5,70
8		${\displaystyle m_{y,m}=-\frac{m_0}{\chi }}$	2,20
9		${\displaystyle m_{x,r}=\frac{m_0}{\chi }}$	2,35
${\displaystyle \chi }$ = Wert in der Tabelle in Belastungsvariante I wird eine Podestplatte betrachtet die ausschließlich durch eine Gleichflächenlast ${\displaystyle F_d}$ belastet ist in Belastungsvariante II wird eine Podestplatte betrachtet die ausschließlich Streckenlast ${\displaystyle F_0}$ am Rand aus der Auflagerkraft des Treppenlaufs belastet ist in Belastungsvariante III wird eine Podestplatte betrachtet die ausschließlich Streckenmoment ${\displaystyle m_0}$ aus der elastischen Einspannung des Treppenlaufs belastet ist

m_{x,m}

${\displaystyle m_i=m_{i,I}+m_{i,II}+m_{i,III}}$

${\displaystyle m_{x,m,I}=\frac{F_d\cdot t_P^2}{\chi }}$	${\displaystyle |mit:\chi =8,04}$
	${\displaystyle |mit:t_P=1,06m}$
	${\displaystyle |mit:F_d=15,0\frac{kN}{m^2}}$
${\displaystyle m_{x,m,I}=\frac{15,0\frac{kN}{m^2}\cdot (1,06m{)}^2}{8,04}}$
${\displaystyle m_{x,m,I}\approx 2,1\frac{kNm}{m}}$

${\displaystyle m_{x,m,II}=\frac{F_0\cdot b_P}{\chi }}$	${\displaystyle |mit:\chi =10,5}$
	${\displaystyle |mit:b_P=2,45m}$
	${\displaystyle |mit:F_d=22.86\frac{kN}{m}}$
${\displaystyle m_{x,m,II}=\frac{22.86\frac{kN}{m}\cdot 2,45m}{10,5}}$
${\displaystyle m_{x,m,II}\approx 5,33\frac{kNm}{m}}$

${\displaystyle m_{x,m,III}=\frac{m_0}{\chi }}$	${\displaystyle |mit:\chi =5,70}$
	${\displaystyle |mit:m_0=6.63\frac{kNm}{m}}$
${\displaystyle m_{x,m,III}=\frac{6.63\frac{kNm}{m}}{5,70}}$
${\displaystyle m_{x,m,III}\approx 1,16\frac{kNm}{m}}$

${\displaystyle m_{x,m}=m_{x,m,I}+m_{x,m,II}+m_{x,m,III}}$	${\displaystyle |mit:m_{x,m,I}=2,1\frac{kNm}{m}}$
	${\displaystyle |mit:m_{x,m,II}=5,33\frac{kNm}{m}}$
	${\displaystyle |mit:m_{x,m,III}=1,16\frac{kNm}{m}}$
${\displaystyle m_{x,m}=2,1\frac{kNm}{m}+5,33\frac{kNm}{m}+1,16\frac{kNm}{m}}$
${\displaystyle m_{x,m}=8,59\frac{kNm}{m}}$

m_{y,m}

${\displaystyle m_i=m_{i,I}+m_{i,II}+m_{i,III}}$

${\displaystyle m_{y,m,I}=\frac{F_d\cdot t_P^2}{\chi }}$	${\displaystyle |mit:\chi =10,5}$
	${\displaystyle |mit:t_P=1,06m}$
	${\displaystyle |mit:F_d=15,0\frac{kN}{m^2}}$
${\displaystyle m_{y,m,I}=\frac{15,0\frac{kN}{m^2}\cdot (1,06m{)}^2}{10,5}}$
${\displaystyle m_{y,m,I}\approx 1,61\frac{kNm}{m}}$

${\displaystyle m_{y,m,II}=-\frac{F_0\cdot b_P}{\chi }}$	${\displaystyle |mit:\chi =91,0}$
	${\displaystyle |mit:b_P=2,45m}$
	${\displaystyle |mit:F_d=22.86\frac{kN}{m}}$
${\displaystyle m_{y,m,II}=-\frac{22.86\frac{kN}{m}\cdot 2,45m}{91,0}}$
${\displaystyle m_{y,m,II}\approx -0,62\frac{kNm}{m}}$

${\displaystyle m_{y,m,III}=-\frac{m_0}{\chi }}$	${\displaystyle |mit:\chi =2,20}$
	${\displaystyle |mit:m_0=6.63\frac{kNm}{m}}$
${\displaystyle m_{y,m,III}=-\frac{6.63\frac{kNm}{m}}{2,20}}$
${\displaystyle m_{y,m,III}\approx -3,01\frac{kNm}{m}}$

${\displaystyle m_{y,m}=m_{y,m,I}+m_{y,m,II}+m_{y,m,III}}$	${\displaystyle |mit:m_{y,m,I}=1,61\frac{kNm}{m}}$
	${\displaystyle |mit:m_{y,m,II}=-0,62\frac{kNm}{m}}$
	${\displaystyle |mit:m_{y,m,III}=-3,01\frac{kNm}{m}}$
${\displaystyle m_{y,m}=1,61\frac{kNm}{m}-0,62\frac{kNm}{m}-3,01\frac{kNm}{m}}$
${\displaystyle m_{y,m}=-2,02\frac{kNm}{m}}$

m_{x,r}

${\displaystyle m_{x,r}=\frac{F_d\cdot t_P^2}{\chi }}$	${\displaystyle |mit:\chi =4,41}$
	${\displaystyle |mit:t_P=1,06m}$
	${\displaystyle |mit:F_d=15,0\frac{kN}{m^2}}$
${\displaystyle m_{x,r}=\frac{15,0\frac{kN}{m^2}\cdot (1,06m{)}^2}{4,41}}$
${\displaystyle m_{x,r}\approx 3,82\frac{kNm}{m}}$

${\displaystyle m_{x,r,II}=\frac{F_0\cdot b_P}{\chi }}$	${\displaystyle |mit:\chi =5,60}$
	${\displaystyle |mit:b_P=2,45m}$
	${\displaystyle |mit:F_d=22.86\frac{kN}{m}}$
${\displaystyle m_{x,r,II}=\frac{22.86\frac{kN}{m}\cdot 2,45m}{5,60}}$
${\displaystyle m_{x,r,II}\approx 10,0\frac{kNm}{m}}$

${\displaystyle m_{x,r,III}=\frac{m_0}{\chi }}$	${\displaystyle |mit:\chi =2,35}$
	${\displaystyle |mit:m_0=6.63\frac{kNm}{m}}$
${\displaystyle m_{x,r,III}=\frac{6.63\frac{kNm}{m}}{2,35}}$
${\displaystyle m_{x,r,III}\approx 2,82\frac{kNm}{m}}$

${\displaystyle m_{x,r}=m_{x,r,I}+m_{x,r,II}+m_{x,r,III}}$	${\displaystyle |mit:m_{x,r,I}=3,82\frac{kNm}{m}}$
	${\displaystyle |mit:m_{x,r,II}=10,0\frac{kNm}{m}}$
	${\displaystyle |mit:m_{x,r,III}=2,82\frac{kNm}{m}}$
${\displaystyle m_{x,r}=3,82\frac{kNm}{m}+10,0\frac{kNm}{m}+2,82\frac{kNm}{m}}$
${\displaystyle m_{x,r}=16,64\frac{kNm}{m}}$

Ermittnlung der maximalen Querkraft

${\displaystyle V_{Ed}=\frac{F_d\cdot b_P}{2}+\frac{F_0\cdot 2\cdot t_P}{2}}$	${\displaystyle |mit:F_d=15,0\frac{kN}{m^2}}$
	${\displaystyle |mit:b_P=2,45m}$
	${\displaystyle |mit:F_0=22.86\frac{kN}{m}}$
	${\displaystyle |mit:t_P=1,06m}$
${\displaystyle V_{Ed}=\frac{15,0\frac{kN}{m^2}\cdot 2,45m}{2}+\frac{22.86\frac{kN}{m}\cdot 2\cdot 1,06m}{2}}$
${\displaystyle V_{Ed}=42,61\frac{kN}{m^2}}$

Bemessung im Grenzzustand der Tragfähigkeit

Materialparameter

${\displaystyle f_{cd}=\frac{{\alpha }_{cc}\cdot f_{ck}}{{\gamma }_C}}$	${\displaystyle |mit:{\gamma }_C=1.5}$
	${\displaystyle |mit:{\alpha }_{cc}=0.85}$
	${\displaystyle |mit:f_{ck}=25\frac{kN}{c{m}^2}}$
${\displaystyle f_{cd}=\frac{0.85\cdot 25\frac{kN}{c{m}^2}}{1.5}}$
${\displaystyle f_{cd}=14,2\frac{kN}{c{m}^2}}$

${\displaystyle f_{yd}=\frac{f_{yk}}{{\gamma }_s}}$	${\displaystyle |mit:f_{yk}=500\frac{N}{m{m}^2}}$
	${\displaystyle |mit:{\gamma }_s=1.15}$
${\displaystyle f_{yd}=\frac{50\frac{kN}{c{m}^2}}{1,15}}$
${\displaystyle f_{yd}=43,5\frac{kN}{c{m}^2}}$

Biegebemessung m_{x,m}

Vorbemessung m_{x,m}

${\displaystyle z_{est}=0,75\cdot h}$	${\displaystyle |mit:h=h_p=20cm}$
${\displaystyle z_{est}=0,75\cdot 20cm}$
${\displaystyle z_{est}=15cm}$

${\displaystyle M_{Ed,est}=M_{Ed}-N_{Ed}\cdot z_{s1,est}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:N_{Ed}=0\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed}=m_{x,m}=8,59\frac{kNm}{m}}$
${\displaystyle M_{Ed,est}=8,59\frac{kNm}{m}-0\frac{kN}{m}\cdot 0,15m}$
${\displaystyle M_{Ed,est}=8,59\frac{kNm}{m}}$

${\displaystyle a_{s,est}=\frac{M_{Ed,est}}{z_{s1,est}\cdot f_{yd}}+\frac{N_{Ed}}{f_{yd}}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:f_{yd}=43,5\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:N_{Ed}=0}$
	${\displaystyle |mit:M_{Ed,est}=8,59\frac{kNm}{m}}$
${\displaystyle a_{s,est}=\frac{859\frac{kNcm}{m}}{15cm\cdot 43,5\frac{kN}{c{m}^2}}+\frac{0}{43,5\frac{kN}{c{m}^2}}}$
${\displaystyle a_{s,est}\approx 1,32\frac{kNcm}{m}}$

gewählt: R188 ø6/15cm, ${\displaystyle a_s}=1,88\frac{c{m}^2}{m}$

Querschnittsgeometrie m_{x,m}

Fehler beim Parsen (Unbekannte Funktion „\begin{cases}“): {\displaystyle c_{v}=\mathrm{max}\begin{cases} C_{nom,dur} \\ C_{nom,b,Bü} \\ C_{nom,b,L} \end{cases}}

${\displaystyle C_{nom,dur}=C_{min,dur}+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,dur}=10mm}$ für XC1
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
${\displaystyle C_{nom,dur}=10mm+10mm}$
${\displaystyle C_{nom,dur}=20mm}$

Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = C_{min,b,Bü} + \Delta C_{dev} }	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: C_{min,b,Bü} = 0 mm }
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 0 mm + 10 mm }
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 10 mm }

${\displaystyle C_{nom,b,L}=C_{min,b,L}-\varnothing bue+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,b,L}=7mm}$
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
${\displaystyle C_{nom,b,L}=6mm-0mm+\mathrm{\Delta }10mm}$
${\displaystyle C_{nom,b,L}=16mm}$

${\displaystyle c_v=\mathrm{m}\mathrm{a}\mathrm{x}\{\begin{array}{l}20mm\\ 10mm\\ 16mm\end{array}}$

${\displaystyle d_1=c_v+\varnothing bue+\frac{\varnothing L}{2}}$	${\displaystyle |mit:c_v=20mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
	${\displaystyle |mit:\varnothing L=6mm}$
${\displaystyle d_1=20mm+0mm+\frac{6mm}{2}}$
${\displaystyle d_1=23,0mm}$

${\displaystyle d=h_L-d_1}$	${\displaystyle |mit:d_1=23mm}$
	${\displaystyle |mit:h_L=200mm}$
${\displaystyle d=200mm-23,0mm}$
${\displaystyle d=177mm=17,7cm}$

Bemessung mit dem ω-Verfahren m_{x,m}

${\displaystyle z_s=d-\frac{h_L}{2}}$	${\displaystyle |mit:d=17,7cm}$
	${\displaystyle |mit:h_L=20cm}$
${\displaystyle z_s=17,7cm-\frac{20cm}{2}}$
${\displaystyle z_s=7,7cm}$

${\displaystyle M_{Eds}=M_{Ed,S}-extrn\cdot z_s}$	${\displaystyle |mit:z_s=7,7cm}$
	${\displaystyle |extrn=0}$
	${\displaystyle |mit:M_{Ed,S}=m_{x,m}=859\frac{kNcm}{m}}$
${\displaystyle M_{Eds}=859\frac{kNcm}{m}-0\frac{kN}{m}\cdot 7,7cm}$
${\displaystyle M_{Eds}=859\frac{kNcm}{m}}$

${\displaystyle {\mu }_{Eds}=\frac{M_{Eds}}{b\cdot d^2\cdot f_{cd}}}$	${\displaystyle |mit:d=17,7cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:M_{Eds}=m_{x,m}=859,0\frac{kNcm}{m}}$
${\displaystyle {\mu }_{Eds}=\frac{859,0\frac{kNcm}{m}}{100cm\cdot (17,7cm{)}^2\cdot 1,42\frac{kN}{c{m}^2}}}$
${\displaystyle {\mu }_{Eds}=0,0193}$

${\displaystyle \omega ={\omega }_1+\frac{{\omega }_2-{\omega }_1}{{\mu }_{Eds,2}-{\mu }_{Eds,1}}\cdot ({\mu }_{Eds}-{\mu }_{Eds,1})}$	${\displaystyle |mit:{\omega }_1=0,0101}$
	${\displaystyle |mit:{\omega }_2=0,0203}$
	${\displaystyle |mit:{\mu }_{Eds}=0,0193}$
	${\displaystyle |mit:{\mu }_{Eds,1}=0,01}$
	${\displaystyle |mit:{\mu }_{Eds,2}=0,02}$
${\displaystyle \omega =0,0101+\frac{0,0203-0,0101}{0,02-0,01}\cdot (0,0193-0,01)}$
${\displaystyle \omega =0,0196}$

${\displaystyle a_{s,1}=\frac{1}{{\sigma }_{sd}}\cdot (\omega \cdot b\cdot d\cdot f_{cd}+N_{Ed})}$	${\displaystyle |mit:\omega =0,0196}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:d=17,7cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:N_{Ed}=0}$
${\displaystyle a_{s,1}=\frac{1}{43,5\frac{kN}{c{m}^2}}\cdot (0,0196\cdot 100cm\cdot 17,7cm\cdot 1,42\frac{kN}{c{m}^2}+0\frac{kN}{m})}$
${\displaystyle a_{s,1}=1,13\frac{c{m}^2}{m}}$

gewählt: R188 ø6/15cm, ${\displaystyle a_s}=1,88\frac{c{m}^2}{m}$

Biegebemessung m_{y,m}

${\displaystyle a_{s,est,m_{y,m}}=0,2\cdot a_{s,est,m_{x,m}}}$

gewählt:R188 ø6/25cm, ${\displaystyle a_s}=1,88\frac{c{m}^2}{m}$

Biegebemessung m_{x,r}

Vorbemessung m_{x,r}

${\displaystyle z_{est}=0,75\cdot h}$	${\displaystyle |mit:h=h_p=20cm}$
${\displaystyle z_{est}=0,75\cdot 20cm}$
${\displaystyle z_{est}=15cm}$

${\displaystyle M_{Ed,est}=M_{Ed}-N_{Ed}\cdot z_{s1,est}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:N_{Ed}=0\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed}=m_{x,m}=16,64\frac{kNm}{m}}$
${\displaystyle M_{Ed,est}=16,64\frac{kNm}{m}-0\frac{kN}{m}\cdot 0,15m}$
${\displaystyle M_{Ed,est}=16,64\frac{kNm}{m}}$

${\displaystyle a_{s,est}=\frac{M_{Ed,est}}{z_{s1,est}\cdot f_{yd}}+\frac{N_{Ed}}{f_{yd}}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:f_{yd}=43,5\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:N_{Ed}=0}$
	${\displaystyle |mit:M_{Ed,est}=16,64\frac{kNm}{m}}$
${\displaystyle a_{s,est}=\frac{1664\frac{kNcm}{m}}{15cm\cdot 43,5\frac{kN}{c{m}^2}}+\frac{0}{43,5\frac{kN}{c{m}^2}}}$
${\displaystyle a_{s,est}\approx 2,55\frac{kNcm}{m}}$

gewählt: ø 8/15cm, ${\displaystyle a_s}=3,35\frac{c{m}^2}{m}$

Querschnittsgeometrie m_{x,r}

Fehler beim Parsen (Unbekannte Funktion „\begin{cases}“): {\displaystyle c_{v}=\mathrm{max}\begin{cases} C_{nom,dur} \\ C_{nom,b,Bü} \\ C_{nom,b,L} \end{cases}}

${\displaystyle C_{nom,dur}=C_{min,dur}+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,dur}=10mm}$ für XC1
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
${\displaystyle C_{nom,dur}=10mm+10mm}$
${\displaystyle C_{nom,dur}=20mm}$

Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = C_{min,b,Bü} + \Delta C_{dev} }	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: C_{min,b,Bü} = 0 mm }
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 0 mm + 10 mm }
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 10 mm }

${\displaystyle C_{nom,b,L}=C_{min,b,L}-\varnothing bue+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,b,L}=7mm}$
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
${\displaystyle C_{nom,b,L}=8mm-0mm+\mathrm{\Delta }10mm}$
${\displaystyle C_{nom,b,L}=18mm}$

${\displaystyle c_v=\mathrm{m}\mathrm{a}\mathrm{x}\{\begin{array}{l}20mm\\ 10mm\\ 16mm\end{array}}$

${\displaystyle d_1=c_v+\varnothing bue+\frac{\varnothing L}{2}}$	${\displaystyle |mit:c_v=20mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
	${\displaystyle |mit:\varnothing L=8mm}$
${\displaystyle d_1=20mm+0mm+\frac{8mm}{2}}$
${\displaystyle d_1=24,0mm}$

${\displaystyle d=h_L-d_1}$	${\displaystyle |mit:d_1=24mm}$
	${\displaystyle |mit:h_L=200mm}$
${\displaystyle d=200mm-24,0mm}$
${\displaystyle d=176mm=17,6cm}$

Bemessung mit dem ω-Verfahren m_{x,r}

${\displaystyle z_s=d-\frac{h_L}{2}}$	${\displaystyle |mit:d=17,6cm}$
	${\displaystyle |mit:h_L=20cm}$
${\displaystyle z_s=17,6cm-\frac{20cm}{2}}$
${\displaystyle z_s=7,6cm}$

${\displaystyle M_{Eds}=M_{Ed}-extrn\cdot z_s}$	${\displaystyle |mit:z_s=7,7cm}$
	${\displaystyle |extrn=0}$
	${\displaystyle |mit:M_{Ed,S}=m_{x,m}=1664\frac{kNcm}{m}}$
${\displaystyle M_{Eds}=1664\frac{kNcm}{m}-0\frac{kN}{m}\cdot 7,7cm}$
${\displaystyle M_{Eds}=1664\frac{kNcm}{m}}$

${\displaystyle {\mu }_{Eds}=\frac{M_{Eds}}{b\cdot d^2\cdot f_{cd}}}$	${\displaystyle |mit:d=17,7cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:M_{Eds}=1664\frac{kNcm}{m}}$
${\displaystyle {\mu }_{Eds}=\frac{1664\frac{kNcm}{m}}{100cm\cdot (17,7cm{)}^2\cdot 1,42\frac{kN}{c{m}^2}}}$
${\displaystyle {\mu }_{Eds}=0,0378}$

${\displaystyle \omega ={\omega }_1+\frac{{\omega }_2-{\omega }_1}{{\mu }_{Eds,2}-{\mu }_{Eds,1}}\cdot ({\mu }_{Eds}-{\mu }_{Eds,1})}$	${\displaystyle |mit:{\omega }_1=0,0306}$
	${\displaystyle |mit:{\omega }_2=0,0410}$
	${\displaystyle |mit:{\mu }_{Eds}=0,0378}$
	${\displaystyle |mit:{\mu }_{Eds,1}=0,03}$
	${\displaystyle |mit:{\mu }_{Eds,2}=0,04}$
${\displaystyle \omega =0,0306+\frac{0,0410-0,0306}{0,04-0,03}\cdot (0,0378-0,03)}$
${\displaystyle \omega =0,0387}$

${\displaystyle a_{sx,r}=\frac{1}{{\sigma }_{sd}}\cdot (\omega \cdot b\cdot d\cdot f_{cd}+N_{Ed})}$	${\displaystyle |mit:\omega =0,0306}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:d=17,6cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:N_{Ed}=0}$
${\displaystyle a_{sx,r}=\frac{1}{43,5\frac{kN}{c{m}^2}}\cdot (0,0387\cdot 100cm\cdot 17,6cm\cdot 1,42\frac{kN}{c{m}^2}+0\frac{kN}{m})}$
${\displaystyle a_{sx,r}=2,20\frac{c{m}^2}{m}}$

gewählt: ø8 / 20cm, ${\displaystyle a_{sx,r}=2,51\frac{c{m}^2}{m}}$

${\displaystyle a_{sy,r}=0,2\cdot a_{sx,r}}$	${\displaystyle |mit:a_{sx,r}=2,20\frac{c{m}^2}{m}}$
${\displaystyle a_{sy,r}=0,2\cdot 2,20\frac{c{m}^2}{m}}$
${\displaystyle a_{sy,r}=0,44\frac{c{m}^2}{m}}$

gewählt: ø6 / 25cm, ${\displaystyle a_{sy,r}=1,13\frac{c{m}^2}{m}}$

Querkraftbemessung

Bauteile ohne Querkraftbewehrung

${\displaystyle V_{Ed}=42,61\frac{kN}{m^2}}$

${\displaystyle C_{Rdc}=\frac{0,15}{{\gamma }_c}}$	${\displaystyle |mit:{\gamma }_c=1,5}$
${\displaystyle C_{Rdc}=\frac{0,15}{1,5}}$
${\displaystyle C_{Rdc}=0,1}$

${\displaystyle k=1+\sqrt{\frac{200}{d}}}$	${\displaystyle \{\begin{array}{l}\ge 1,0\\ \le 2,0\end{array}}$
	${\displaystyle |mit:d=176mm}$
${\displaystyle k=1+\sqrt{\frac{200}{176}}}$
${\displaystyle k=2,07}$	${\displaystyle \{\begin{array}{l}\ge 1,0\\ \ge 2,0\end{array}}$
${\displaystyle k=2}$

${\displaystyle {\rho }_l=\frac{A_{sl}}{b_w\cdot d}}$	${\displaystyle \le 0,02}$
	${\displaystyle |mit:A_{sl}=a_{sx,r}=2,51\frac{c{m}^2}{m}}$
	${\displaystyle |mit:b_w=100cm}$
	${\displaystyle |mit:d=17,6cm}$
${\displaystyle {\rho }_l=\frac{2,51\frac{c{m}^2}{m}}{100cm\cdot 17,6cm}}$
${\displaystyle {\rho }_l=1,43\cdot 10^{-3}}$	${\displaystyle \le 0,02}$

${\displaystyle A_c=A-A_s}$	${\displaystyle |mit:A=b_w\cdot h_L=b_w\cdot h_L=1000mm\cdot 200mm=200000}$
	${\displaystyle |mit:A_{s,a_{sx,r},a_{sy,r}}=251\frac{m{m}^2}{m}+113\frac{m{m}^2}{m}=364\frac{m{m}^2}{m}}$
${\displaystyle A_c=200000m{m}^2-364m{m}^2}$
${\displaystyle A_c=199636m{m}^2}$

${\displaystyle {\sigma }_{cp}=\frac{N_{Ed}}{A_c}}$	${\displaystyle |mit:N_{Ed}=0\frac{N}{m}}$
	${\displaystyle |mit:A_c=199636m{m}^2}$
${\displaystyle {\sigma }_{cp}=\frac{0\frac{N}{m}}{199636m{m}^2}}$
${\displaystyle {\sigma }_{cp}=0\frac{N}{m\cdot m{m}^2}}$

${\displaystyle V_{Rd,c}=[C_{Rdc}\cdot k\cdot {(100\cdot {\rho }_l\cdot f_{ck})}^{\frac{1}{3}}+0,12\cdot {\sigma }_{cp}]\cdot b_w\cdot d}$	${\displaystyle |mit:{\sigma }_{cp}=0\frac{N}{m{m}^2}}$
	${\displaystyle |mit:{\rho }_l=1,43\cdot 10^{-3}}$
	${\displaystyle |mit:k=2}$
	${\displaystyle |mit:C_{Rdc}=0,1}$
	${\displaystyle |mit:f_{ck}=25\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:b_w=1000mm}$
	${\displaystyle |mit:d=176mm}$
${\displaystyle V_{Rd,c}=[0,1\cdot 2\cdot {(100\cdot 1,43\cdot 10^{-3}\cdot 25\frac{N}{m{m}^2})}^{\frac{1}{3}}+0,12\cdot 0\frac{N}{m{m}^2}]\cdot 1000mm\cdot 176mm}$
${\displaystyle V_{Rd,c}=53823N}$	${\displaystyle \ge V_{Ed}}$
${\displaystyle V_{Rd,c}=53,82kN}$	${\displaystyle \ge 42,61\frac{kN}{m^2}}$

Weitere Bemessung Hinsichtlich der Querkraft für dieses Bauteil nicht erforderlich da der Nachweis erfüllt ist .

Bemessung im Grenzzustand der Gebrauchs

Begrenzung der Biegeschlankheit des Treppenlauf

${\displaystyle \frac{l}{d}\le K[11+1,5\cdot \sqrt{f_{ck}}\cdot \frac{{\rho }_0}{\rho }+3,2\cdot \sqrt{f_{ck}}\cdot (\frac{{\rho }_0}{\rho }-1{)}^{3/2}]\le {\left(\frac{l}{d}\right)}_{max}}$		für: ${\displaystyle \rho \le {\rho }_0}$
${\displaystyle \frac{l}{d}\le K[11+1,5\sqrt{f_{ck}}\cdot \frac{{\rho }_0}{\rho -{\rho }_{\text{'}}}+\frac{1}{12}\cdot \sqrt{f_{ck}}\cdot (\frac{{\rho }_{\text{'}}}{{\rho }_0}{)}^{1/2}]\le {\left(\frac{l}{d}\right)}_{max}}$		für: ${\displaystyle \rho >{\rho }_0}$

${\displaystyle {\rho }_0=10^{-3}\cdot \sqrt{f_{ck}}}$	${\displaystyle |mit:f_{ck}=25\frac{N}{m{m}^2}}$
${\displaystyle {\rho }_0=10^{-3}\cdot \sqrt{25\frac{N}{m{m}^2}}}$
${\displaystyle {\rho }_0=5\cdot 10^{-3}}$

${\displaystyle \rho =\frac{A_s}{b\cdot d}}$	${\displaystyle |mit:A_s=a_{sx,r}=2,51\frac{c{m}^2}{m}}$
	${\displaystyle |mit:d=17,6cm}$
	${\displaystyle |mit:b=100cm}$
${\displaystyle \rho =\frac{2,51\frac{c{m}^2}{m}}{100cm\cdot 17,6cm}}$
${\displaystyle \rho =1,43\cdot 10^{-3}}$	${\displaystyle \le {\rho }_0}$

${\displaystyle \frac{l}{d}\le K[11+1,5\cdot \sqrt{f_{ck}}\cdot \frac{{\rho }_0}{\rho }+3,2\cdot \sqrt{f_{ck}}\cdot (\frac{{\rho }_0}{\rho }-1{)}^{3/2}]\le {\left(\frac{l}{d}\right)}_{max}}$

${\displaystyle {\left(\frac{l}{d}\right)}_{vorh}=\frac{l}{d}}$	${\displaystyle |mit:d=0,176m}$
	${\displaystyle |mit:l=b_P=2,45m}$
${\displaystyle {\left(\frac{l}{d}\right)}_{vorh}=\frac{2,45m}{0,176m}}$
${\displaystyle {\left(\frac{l}{d}\right)}_{vorh}=13,92}$

${\displaystyle {\frac{l}{d}}_{zul}=K[11+1,5\cdot \sqrt{f_{ck}}\cdot \frac{{\rho }_0}{\rho }+3,2\cdot \sqrt{f_{ck}}\cdot (\frac{{\rho }_0}{\rho }-1{)}^{3/2}]}$	${\displaystyle |mit:K_{Einfeldplatte}=1}$
	${\displaystyle |mit:f_{ck}=25\frac{N}{m{m}^2}}$
	${\displaystyle |mit:\rho =1,43\cdot 10^{-3}}$
	${\displaystyle |mit:{\rho }_0=5\cdot 10^{-3}}$
${\displaystyle {\frac{l}{d}}_{zul}=1[11+1,5\cdot \sqrt{25\frac{N}{m{m}^2}}\cdot \frac{5\cdot 10^{-3}}{1,43\cdot 10^{-3}}+3,2\cdot \sqrt{25\frac{N}{m{m}^2}}\cdot (\frac{5\cdot 10^{-3}}{1,43\cdot 10^{-3}}-1{)}^{3/2}]}$
${\displaystyle {\frac{l}{d}}_{zul}=100.34}$	${\displaystyle \ge {\left(\frac{l}{d}\right)}_{vorh}}$

${\displaystyle {\left(\frac{l}{d}\right)}_{max}\le \{\begin{array}{l}K\cdot 35\\ K^2\cdot \frac{150}{l}\end{array}}$

${\displaystyle {\left(\frac{l}{d}\right)}_{max}K\cdot 35}$	${\displaystyle |mit:K_{Einfeldplatte}=1}$
${\displaystyle {\left(\frac{l}{d}\right)}_{max}=1\cdot 35}$
${\displaystyle {\left(\frac{l}{d}\right)}_{max}=35}$	${\displaystyle \ge {\left(\frac{l}{d}\right)}_{vorh}}$

${\displaystyle {\left(\frac{l}{d}\right)}_{max}=K^2\cdot \frac{150}{l}}$	${\displaystyle |mit:K_{Einfeldplatte}=1}$
	${\displaystyle |mit:l=b_P=2,45m}$
${\displaystyle {\left(\frac{l}{d}\right)}_{max}=1^2\cdot \frac{150}{2,45m}}$
${\displaystyle {\left(\frac{l}{d}\right)}_{max}=61,22}$	${\displaystyle \ge {\left(\frac{l}{d}\right)}_{vorh}}$

Lösung für das Hauptpodest

Das Hauptpodest wird als zweiseitig gelagert also einachsig gespannt

Das Zwischenpodest wird in diesem Beispiel anders als das Hauptpodest als Dreiseitig gelagert und somit zweiseitig gespannt betrachtet

Einwirkungen

Teilsicherheiten

${\displaystyle {\gamma }_{\mathrm{Q}}=1,50}$
${\displaystyle {\gamma }_{\mathrm{G}}=1,35}$

Ständige

${\displaystyle g_d=g_k\cdot {\gamma }_{\mathrm{G}}}$

${\displaystyle g_k=h\cdot {\gamma }_1+{\gamma }_{G_s=1,5cm}+N_s\cdot {\gamma }_{Naturstein}+{\gamma }_{Estrich}\cdot d_{Estrich}}$	${\displaystyle |mit:h_P=20cm}$
	${\displaystyle |mit:{\gamma }_1=25\frac{kN}{m^3}}$
	${\displaystyle |mit:{\gamma }_{G_s=1,5cm}=0,18\frac{kN}{m^2}}$
	${\displaystyle |mit:{\gamma }_{Naturstein}=0,3\frac{\frac{kN}{m^2}}{cm}}$
	${\displaystyle |mit:N_s=3cm}$
	${\displaystyle |mit:{\gamma }_{Estrich}=22\frac{\frac{kN}{m^2}}{cm}}$
	${\displaystyle |mit:d_{Estrich}=4cm}$
	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: \gamma_{Trittschalldämmung} = 0,01 \frac{\frac{kN}{m^{2}}}{cm} }
	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: d_{Trittschalldämmung} = 4 cm }
${\displaystyle g_k=0,20m\cdot 25\frac{kN}{m^3}+0,18\frac{kN}{m^2}+3cm\cdot 0,3\frac{\frac{kN}{m^2}}{cm}+0,01\frac{\frac{kN}{m^2}}{cm}\cdot 4cm+0,22\frac{\frac{kN}{m^2}}{cm}\cdot 4cm}$
${\displaystyle g_k=7\frac{kN}{m^2}}$

${\displaystyle g_d=g_k\cdot {\gamma }_{\mathrm{G}}}$	${\displaystyle |mit:{\gamma }_{\mathrm{G}}=1,5}$
	${\displaystyle |mit:g_k=7\frac{kN}{m^2}}$
${\displaystyle g_d=7\frac{kN}{m^2}\cdot 1,5}$
${\displaystyle g_d=10,5\frac{kN}{m^2}}$

Veränderliche

Lotrechte Nutzlasten für Treppen ^{[F 1]}

	1		2	3	4	5
	Kategorie		Nutzung	Beispiele	${\displaystyle q_k[\frac{kN}{m^2}]}$	${\displaystyle Q_k[kN]}$
19	T	T1	Treppen und Treppenpodeste	Treppen und Treppenpodeste in Wohngebäuden, Bürogebäuden und von Arztpraxen ohne schweres Gerät	3,0	2,0
20		T2		alle Treppen und Treppenpodeste, die nicht in TI oder T3 eingeordnet werden können	5,0	2,0
21		T3		Zugänge und Treppen von Tribünen ohne feste Sitzplätze, die als Fluchtwege dienen	7,5	3,0

${\displaystyle \underset{\_}{q_k=3,0\frac{kN}{m^2}}}$

${\displaystyle q_d=q_k\cdot {\gamma }_{\mathrm{Q}}}$	${\displaystyle |mit:q_k=3,0\frac{kN}{m^2}}$
	${\displaystyle |mit:{\gamma }_{\mathrm{Q}}=1,5}$
${\displaystyle q_d=3,0\frac{kN}{m^2}\cdot 1,5}$
${\displaystyle q_d=4,5\frac{kN}{m^2}}$

Gesamt Einwirkungen

${\displaystyle F_d=g_d+q_d}$	${\displaystyle |mit:q_d=4,5\frac{kN}{m^2}}$
	${\displaystyle |mit:g_d=10,5\frac{kN}{m^2}}$
${\displaystyle F_d=10,5\frac{kN}{m^2}+4,5\frac{kN}{m^2}}$
${\displaystyle F_d=15,0\frac{kN}{m^2}}$

${\displaystyle F_0=C_{Ed}}$	${\displaystyle |mit:C_{Ed}=22.86\frac{kN}{m}}$
${\displaystyle F_0=22.86\frac{kN}{m}}$

${\displaystyle m_0=M_{Ed,S}}$	${\displaystyle |mit:M_{Ed,S}=6.63\frac{kNm}{m}}$
${\displaystyle m_0=6.63\frac{kNm}{m}}$

Statisches System

${\displaystyle a_1=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}\frac{h_P}{2}\\ \frac{t}{2}\end{array}}$
	${\displaystyle |mit:h_P=20cm}$
	${\displaystyle |mit:t_1=18cm}$
${\displaystyle a_1=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}\frac{20cm}{2}\\ \frac{18cm}{2}\end{array}}$
${\displaystyle a_1=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}10cm\\ 9cm\end{array}}$
${\displaystyle a_1=9cm}$

${\displaystyle a_2=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}\frac{h_P}{2}\\ \frac{t}{2}\end{array}}$
	${\displaystyle |mit:h_P=20cm}$
	${\displaystyle |mit:t_2=24cm}$
${\displaystyle a_2=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}\frac{20cm}{2}\\ \frac{24cm}{2}\end{array}}$
${\displaystyle a_2=\mathrm{m}\mathrm{i}\mathrm{n}\{\begin{array}{l}10cm\\ 12cm\end{array}}$
${\displaystyle a_2=10cm}$

${\displaystyle b_P=2\cdot b+b^{\text{'}}+a_2+a_2}$	${\displaystyle |mit:b=1,0m}$
	${\displaystyle |mit:a_1=0,09m}$
	${\displaystyle |mit:a_2=0,1m}$
	${\displaystyle |mit:b^{\text{'}}=0,25m}$
${\displaystyle b_P=2\cdot 1,0m+0,25m+0,09m+0,1m}$
${\displaystyle b_P=2,44m}$

${\displaystyle t_P=ln+a_1+a_2}$	${\displaystyle |mit:ln=1,5m}$
	${\displaystyle |mit:a_1=0m}$
	${\displaystyle |mit:a_2=0m}$
${\displaystyle t_P=1,50m+0m+0m}$
${\displaystyle t_P=1,50m}$

Schnittgrößen

Verhältnis Podesttiefe zu Podestbreite feststellen

${\displaystyle \frac{t_P}{b_P}}$	${\displaystyle |mit:b_P=2,44m}$
	${\displaystyle |mit:t_P=1,50m}$
${\displaystyle \frac{t_P}{b_P}=\frac{1,50m}{2,44m}}$
${\displaystyle \frac{t_P}{b_P}\approx 0,6}$

Ermittnlung der Momente über Tabelle

Tafel zur Schnittgrößen Ermittlung von Podestplatten mit gegenüberliegenden frei drehbar gelagerten Rändern ^{[F 2] [F 3]}

	1	2	6
	Belastungsvariante	${\displaystyle \frac{t_P}{b_P}}$	0,6
			${\displaystyle \chi }$
1	I	${\displaystyle m_{x,m}=\frac{F_d\cdot b_P^2}{8}}$
2		${\displaystyle m_{y,m}=0,2\cdot m_{x,m}}$
3	II	${\displaystyle m_{x,m}=\frac{F_0\cdot b_P}{\chi }}$	4,88
4		${\displaystyle m_{y,m}=-\frac{F_0\cdot b_P}{\chi }}$	26,4
5		${\displaystyle m_{x,r1}=\frac{F_0\cdot b_P}{\chi }}$	3,45
6		${\displaystyle m_{x,r2}=\frac{F_0\cdot b_P}{\chi }}$	6,85
7	III	${\displaystyle m_{x,m}=-\frac{m_0}{\chi }}$	26,4
8		${\displaystyle m_{y,m}=-\frac{m_0}{\chi }}$	3,00
9		${\displaystyle m_{x,r1}=\frac{m_0}{\chi }}$	3,34
10		${\displaystyle m_{x,r2}=-\frac{m_0}{\chi }}$	5,96
${\displaystyle \chi }$ = Wert in der Tabelle in Belastungsvariante I wird eine Podestplatte betrachtet die ausschließlich durch eine Gleichflächenlast ${\displaystyle F_d}$ belastet ist in Belastungsvariante II wird eine Podestplatte betrachtet die ausschließlich Streckenlast ${\displaystyle F_0}$ am Rand aus der Auflagerkraft des Treppenlaufs belastet ist in Belastungsvariante III wird eine Podestplatte betrachtet die ausschließlich Streckenmoment ${\displaystyle m_0}$ aus der elastischen Einspannung des Treppenlaufs belastet ist

m_{x,m}

${\displaystyle m_i=m_{i,I}+m_{i,II}+m_{i,III}}$

${\displaystyle m_{x,m,I}=\frac{F_d\cdot b_P^2}{8}}$	${\displaystyle |mit:b_P=2,44m}$
	${\displaystyle |mit:F_d=15,0\frac{kN}{m^2}}$
${\displaystyle m_{x,m,I}=\frac{15,0\frac{kN}{m^2}\cdot (2,44m{)}^2}{8}}$
${\displaystyle m_{x,m,I}\approx 11,16\frac{kNm}{m}}$

${\displaystyle m_{x,m,II}=\frac{F_0\cdot b_P}{\chi }}$	${\displaystyle |mit:\chi =4,88}$
	${\displaystyle |mit:b_P=2,44m}$
	${\displaystyle |mit:F_d=22.86\frac{kN}{m}}$
${\displaystyle m_{x,m,II}=\frac{22.86\frac{kN}{m}\cdot 2,44m}{4,88}}$
${\displaystyle m_{x,m,II}=11,43\frac{kNm}{m}}$

${\displaystyle m_{x,m,III}=-\frac{m_0}{\chi }}$	${\displaystyle |mit:\chi =26,4}$
	${\displaystyle |mit:m_0=6.63\frac{kNm}{m}}$
${\displaystyle m_{x,m,III}=-\frac{6.63\frac{kNm}{m}}{26,4}}$
${\displaystyle m_{x,m,III}\approx -0,25\frac{kNm}{m}}$

${\displaystyle m_{x,m}=m_{x,m,I}+m_{x,m,II}+m_{x,m,III}}$	${\displaystyle |mit:m_{x,m,I}=11,16\frac{kNm}{m}}$
	${\displaystyle |mit:m_{x,m,II}=11,43\frac{kNm}{m}}$
	${\displaystyle |mit:m_{x,m,III}=-0,25\frac{kNm}{m}}$
${\displaystyle m_{x,m}=11,16\frac{kNm}{m}+11,43\frac{kNm}{m}-0,25\frac{kNm}{m}}$
${\displaystyle m_{x,m}=22,34\frac{kNm}{m}}$

m_{y,m}

${\displaystyle m_i=m_{i,I}+m_{i,II}+m_{i,III}}$

${\displaystyle m_{y,m,I}=0,2\cdot m_{x,m,I}}$	${\displaystyle |mit:m_{x,m}=22,34\frac{kNm}{m}}$
${\displaystyle m_{y,m,I}=0,2\cdot 22,34}$
${\displaystyle m_{y,m,I}\approx 4,47\frac{kNm}{m}}$

${\displaystyle m_{y,m,II}=-\frac{F_0\cdot b_P}{\chi }}$	${\displaystyle |mit:\chi =26,4}$
	${\displaystyle |mit:b_P=2,44m}$
	${\displaystyle |mit:F_d=22.86\frac{kN}{m}}$
${\displaystyle m_{y,m,II}=-\frac{22.86\frac{kN}{m}\cdot 2,44m}{26,4}}$
${\displaystyle m_{y,m,II}\approx -2,11\frac{kNm}{m}}$

${\displaystyle m_{y,m,III}=-\frac{m_0}{\chi }}$	${\displaystyle |mit:\chi =3,00}$
	${\displaystyle |mit:m_0=6.63\frac{kNm}{m}}$
${\displaystyle m_{y,m,III}=-\frac{6.63\frac{kNm}{m}}{3,00}}$
${\displaystyle m_{y,m,III}\approx -2,21\frac{kNm}{m}}$

${\displaystyle m_{y,m}=m_{y,m,I}+m_{y,m,II}+m_{y,m,III}}$	${\displaystyle |mit:m_{y,m,I}=4,47\frac{kNm}{m}}$
	${\displaystyle |mit:m_{y,m,II}=-2,11\frac{kNm}{m}}$
	${\displaystyle |mit:m_{y,m,III}=-2,21\frac{kNm}{m}}$
${\displaystyle m_{y,m}=4,47\frac{kNm}{m}-2,11\frac{kNm}{m}-2,21\frac{kNm}{m}}$
${\displaystyle m_{y,m}=0,15\frac{kNm}{m}}$

m_{x,r1}

${\displaystyle m_{x,r1,II}=\frac{F_0\cdot b_P}{\chi }}$	${\displaystyle |mit:\chi =3,45}$
	${\displaystyle |mit:b_P=2,44m}$
	${\displaystyle |mit:F_d=22.86\frac{kN}{m}}$
${\displaystyle m_{x,r1,II}=\frac{22.86\frac{kN}{m}\cdot 2,44m}{3,45}}$
${\displaystyle m_{x,r1,II}\approx 16,17\frac{kNm}{m}}$

${\displaystyle m_{x,r1,III}=\frac{m_0}{\chi }}$	${\displaystyle |mit:\chi =3,34}$
	${\displaystyle |mit:m_0=6.63\frac{kNm}{m}}$
${\displaystyle m_{x,r1,III}=\frac{6.63\frac{kNm}{m}}{3,34}}$
${\displaystyle m_{x,r1,III}\approx 1,99\frac{kNm}{m}}$

${\displaystyle m_{x,r1}=m_{x,r1,II}+m_{x,r1,III}}$	${\displaystyle |mit:m_{x,r1,II}=16,17\frac{kNm}{m}}$
	${\displaystyle |mit:m_{x,r1,III}=1,99\frac{kNm}{m}}$
${\displaystyle m_{x,r1}=16,17\frac{kNm}{m}+1,99\frac{kNm}{m}}$
${\displaystyle m_{x,r1}=18,16\frac{kNm}{m}}$

m_{x,r2}

${\displaystyle m_{x,r2,II}=\frac{F_0\cdot b_P}{\chi }}$	${\displaystyle |mit:\chi =6,85}$
	${\displaystyle |mit:b_P=2,44m}$
	${\displaystyle |mit:F_d=22.86\frac{kN}{m}}$
${\displaystyle m_{x,r2,II}=\frac{22.86\frac{kN}{m}\cdot 2,44m}{6,85}}$
${\displaystyle m_{x,r2,II}\approx 8,14\frac{kNm}{m}}$

${\displaystyle m_{x,r2,III}=\frac{m_0}{\chi }}$	${\displaystyle |mit:\chi =5,96}$
	${\displaystyle |mit:m_0=6.63\frac{kNm}{m}}$
${\displaystyle m_{x,r2,III}=\frac{6.63\frac{kNm}{m}}{5,96}}$
${\displaystyle m_{x,r2,III}\approx 1,11\frac{kNm}{m}}$

${\displaystyle m_{x,r2}=m_{x,r1,II}+m_{x,r1,III}}$	${\displaystyle |mit:m_{x,r1,II}=8,14\frac{kNm}{m}}$
	${\displaystyle |mit:m_{x,r1,III}=1,11\frac{kNm}{m}}$
${\displaystyle m_{x,r2}=8,14\frac{kNm}{m}+1,11\frac{kNm}{m}}$
${\displaystyle m_{x,r2}=9,25\frac{kNm}{m}}$

Ermittnlung der maximalen Querkraft

${\displaystyle V_{Ed}=\frac{F_d\cdot b_P}{2}+\frac{F_0\cdot 2\cdot t_P}{2}}$	${\displaystyle |mit:F_d=15,0\frac{kN}{m^2}}$
	${\displaystyle |mit:b_P=2,45m}$
	${\displaystyle |mit:F_0=22.86\frac{kN}{m}}$
	${\displaystyle |mit:t_P=1,06m}$
${\displaystyle V_{Ed}=\frac{15,0\frac{kN}{m^2}\cdot 2,45m}{2}+\frac{22.86\frac{kN}{m}\cdot 2\cdot 1,06m}{2}}$
${\displaystyle V_{Ed}=42,61\frac{kN}{m^2}}$

Bemessung im Grenzzustand der Tragfähigkeit

Materialparameter

${\displaystyle f_{cd}=\frac{{\alpha }_{cc}\cdot f_{ck}}{{\gamma }_C}}$	${\displaystyle |mit:{\gamma }_C=1.5}$
	${\displaystyle |mit:{\alpha }_{cc}=0.85}$
	${\displaystyle |mit:f_{ck}=25\frac{kN}{c{m}^2}}$
${\displaystyle f_{cd}=\frac{0.85\cdot 25\frac{kN}{c{m}^2}}{1.5}}$
${\displaystyle f_{cd}=14,2\frac{kN}{c{m}^2}}$

${\displaystyle f_{yd}=\frac{f_{yk}}{{\gamma }_s}}$	${\displaystyle |mit:f_{yk}=500\frac{N}{m{m}^2}}$
	${\displaystyle |mit:{\gamma }_s=1.15}$
${\displaystyle f_{yd}=\frac{50\frac{kN}{c{m}^2}}{1,15}}$
${\displaystyle f_{yd}=43,5\frac{kN}{c{m}^2}}$

Biegebemessung m_{x,m}

Vorbemessung m_{x,m}

${\displaystyle z_{est}=0,75\cdot h}$	${\displaystyle |mit:h=h_p=20cm}$
${\displaystyle z_{est}=0,75\cdot 20cm}$
${\displaystyle z_{est}=15cm}$

${\displaystyle M_{Ed,est}=M_{Ed}-N_{Ed}\cdot z_{s1,est}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:N_{Ed}=0\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed}=m_{x,m}=22,34\frac{kNm}{m}}$
${\displaystyle M_{Ed,est}=22,34\frac{kNm}{m}-0\frac{kN}{m}\cdot 0,15m}$
${\displaystyle M_{Ed,est}=22,34\frac{kNm}{m}}$

${\displaystyle a_{s,est}=\frac{M_{Ed,est}}{z_{s1,est}\cdot f_{yd}}+\frac{N_{Ed}}{f_{yd}}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:f_{yd}=43,5\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:N_{Ed}=0}$
	${\displaystyle |mit:M_{Ed,est}=22,34\frac{kNm}{m}}$
${\displaystyle a_{s,est}=\frac{2234\frac{kNcm}{m}}{15cm\cdot 43,5\frac{kN}{c{m}^2}}+\frac{0}{43,5\frac{kN}{c{m}^2}}}$
${\displaystyle a_{s,est}\approx 3,42\frac{kNcm}{m}}$

gewählt: ø10/20cm, ${\displaystyle a_s}=3,93\frac{c{m}^2}{m}$

Querschnittsgeometrie m_{x,m}

Fehler beim Parsen (Unbekannte Funktion „\begin{cases}“): {\displaystyle c_{v}=\mathrm{max}\begin{cases} C_{nom,dur} \\ C_{nom,b,Bü} \\ C_{nom,b,L} \end{cases}}

${\displaystyle C_{nom,dur}=C_{min,dur}+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,dur}=10mm}$ für XC1
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
${\displaystyle C_{nom,dur}=10mm+10mm}$
${\displaystyle C_{nom,dur}=20mm}$

Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = C_{min,b,Bü} + \Delta C_{dev} }	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: C_{min,b,Bü} = 0 mm }
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 0 mm + 10 mm }
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 10 mm }

${\displaystyle C_{nom,b,L}=C_{min,b,L}-\varnothing bue+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,b,L}=10mm}$
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
${\displaystyle C_{nom,b,L}=10mm-0mm+\mathrm{\Delta }10mm}$
${\displaystyle C_{nom,b,L}=20mm}$

${\displaystyle c_v=\mathrm{m}\mathrm{a}\mathrm{x}\{\begin{array}{l}20mm\\ 10mm\\ 20mm\end{array}}$

${\displaystyle d_1=c_v+\varnothing bue+\frac{\varnothing L}{2}}$	${\displaystyle |mit:c_v=20mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
	${\displaystyle |mit:\varnothing L=10mm}$
${\displaystyle d_1=20mm+0mm+\frac{10mm}{2}}$
${\displaystyle d_1=25,0mm}$

${\displaystyle d=h_L-d_1}$	${\displaystyle |mit:d_1=25mm}$
	${\displaystyle |mit:h_L=200mm}$
${\displaystyle d=200mm-25,0mm}$
${\displaystyle d=175mm=17,5cm}$

Bemessung mit dem ω-Verfahren m_{x,m}

${\displaystyle z_s=d-\frac{h_L}{2}}$	${\displaystyle |mit:d=17,5cm}$
	${\displaystyle |mit:h_L=20cm}$
${\displaystyle z_s=17,5cm-\frac{20cm}{2}}$
${\displaystyle z_s=7,5cm}$

${\displaystyle M_{Eds}=M_{Ed,S}-extrn\cdot z_s}$	${\displaystyle |mit:z_s=7,5cm}$
	${\displaystyle |extrn=0}$
	${\displaystyle |mit:M_{Ed,S}=m_{x,m}=22,34\frac{kNm}{m}}$
${\displaystyle M_{Eds}=2234\frac{kNcm}{m}-0\frac{kN}{m}\cdot 7,7cm}$
${\displaystyle M_{Eds}=2234\frac{kNcm}{m}}$

${\displaystyle {\mu }_{Eds}=\frac{M_{Eds}}{b\cdot d^2\cdot f_{cd}}}$	${\displaystyle |mit:d=17,5cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:M_{Eds}=m_{x,m}=2234\frac{kNcm}{m}}$
${\displaystyle {\mu }_{Eds}=\frac{2234\frac{kNcm}{m}}{100cm\cdot (17,5cm{)}^2\cdot 1,42\frac{kN}{c{m}^2}}}$
${\displaystyle {\mu }_{Eds}=0,0514}$

${\displaystyle \omega ={\omega }_1+\frac{{\omega }_2-{\omega }_1}{{\mu }_{Eds,2}-{\mu }_{Eds,1}}\cdot ({\mu }_{Eds}-{\mu }_{Eds,1})}$	${\displaystyle |mit:{\omega }_1=0,0515}$
	${\displaystyle |mit:{\omega }_2=0,0621}$
	${\displaystyle |mit:{\mu }_{Eds}=0,0514}$
	${\displaystyle |mit:{\mu }_{Eds,1}=0,05}$
	${\displaystyle |mit:{\mu }_{Eds,2}=0,06}$
${\displaystyle \omega =0,0515+\frac{0,0621-0,0515}{0,06-0,05}\cdot (0,0514-0,05)}$
${\displaystyle \omega =0,0530}$

${\displaystyle a_{s,1,m_{x,m}}=\frac{1}{{\sigma }_{sd}}\cdot (\omega \cdot b\cdot d\cdot f_{cd}+N_{Ed})}$	${\displaystyle |mit:\omega =0,0530}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:d=17,5cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:N_{Ed}=0}$
${\displaystyle a_{s,1,m_{x,m}}=\frac{1}{43,5\frac{kN}{c{m}^2}}\cdot (0,0530\cdot 100cm\cdot 17,5cm\cdot 1,42\frac{kN}{c{m}^2}+0\frac{kN}{m})}$
${\displaystyle a_{s,1,m_{x,m}}=3,02\frac{c{m}^2}{m}}$

gewählt: ø10/25cm, ${\displaystyle a_s}=3,14\frac{c{m}^2}{m}$

Biegebemessung m_{y,m}

Vorbemessung m_{y,m}

${\displaystyle z_{est}=0,75\cdot h}$	${\displaystyle |mit:h=h_p=20cm}$
${\displaystyle z_{est}=0,75\cdot 20cm}$
${\displaystyle z_{est}=15cm}$

${\displaystyle M_{Ed,est}=M_{Ed}-N_{Ed}\cdot z_{s1,est}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:N_{Ed}=0\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed}=m_{y,m}=0,15\frac{kNm}{m}}$
${\displaystyle M_{Ed,est}=15\frac{kNcm}{m}-0\frac{kN}{m}\cdot 0,15m}$
${\displaystyle M_{Ed,est}=15\frac{kNcm}{m}}$

${\displaystyle a_{s,est}=\frac{M_{Ed,est}}{z_{s1,est}\cdot f_{yd}}+\frac{N_{Ed}}{f_{yd}}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:f_{yd}=43,5\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:N_{Ed}=0}$
	${\displaystyle |mit:M_{Ed,est}=15\frac{kNcm}{m}}$
${\displaystyle a_{s,est}=\frac{15\frac{kNcm}{m}}{15cm\cdot 43,5\frac{kN}{c{m}^2}}+\frac{0}{43,5\frac{kN}{c{m}^2}}}$	${\displaystyle \ge 0,2\cdot a_{s,est,m_{x,m}}}$
${\displaystyle a_{s,est}\approx 0,023\frac{kNcm}{m}}$	${\displaystyle <0,2\cdot 3,14\frac{kNcm}{m}=0,628\frac{kNcm}{m}}$

gewählt: ø8/25cm, ${\displaystyle a_s}=2,01\frac{c{m}^2}{m}$

Biegebemessung m_{x,r1}

Vorbemessung m_{x,r1}

${\displaystyle z_{est}=0,75\cdot h}$	${\displaystyle |mit:h=h_p=20cm}$
${\displaystyle z_{est}=0,75\cdot 20cm}$
${\displaystyle z_{est}=15cm}$

${\displaystyle M_{Ed,est}=M_{Ed}-N_{Ed}\cdot z_{s1,est}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:N_{Ed}=0\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed}=m_{x,r1}=18,16\frac{kNm}{m}}$
${\displaystyle M_{Ed,est}=18,16\frac{kNm}{m}-0\frac{kN}{m}\cdot 0,15m}$
${\displaystyle M_{Ed,est}=18,16\frac{kNm}{m}}$

${\displaystyle a_{s,est}=\frac{M_{Ed,est}}{z_{s1,est}\cdot f_{yd}}+\frac{N_{Ed}}{f_{yd}}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:f_{yd}=43,5\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:N_{Ed}=0}$
	${\displaystyle |mit:M_{Ed,est}=18,16\frac{kNm}{m}}$
${\displaystyle a_{s,est}=\frac{1816\frac{kNcm}{m}}{15cm\cdot 43,5\frac{kN}{c{m}^2}}+\frac{0}{43,5\frac{kN}{c{m}^2}}}$
${\displaystyle a_{s,est}\approx 2,78\frac{kNcm}{m}}$

gewählt: ø 10/25cm, ${\displaystyle a_s}=3,14\frac{c{m}^2}{m}$

Querschnittsgeometrie m_{x,r1}

Fehler beim Parsen (Unbekannte Funktion „\begin{cases}“): {\displaystyle c_{v}=\mathrm{max}\begin{cases} C_{nom,dur} \\ C_{nom,b,Bü} \\ C_{nom,b,L} \end{cases}}

${\displaystyle C_{nom,dur}=C_{min,dur}+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,dur}=10mm}$ für XC1
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
${\displaystyle C_{nom,dur}=10mm+10mm}$
${\displaystyle C_{nom,dur}=20mm}$

Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = C_{min,b,Bü} + \Delta C_{dev} }	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: C_{min,b,Bü} = 0 mm }
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 0 mm + 10 mm }
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 10 mm }

${\displaystyle C_{nom,b,L}=C_{min,b,L}-\varnothing bue+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,b,L}=7mm}$
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
${\displaystyle C_{nom,b,L}=10mm-0mm+\mathrm{\Delta }10mm}$
${\displaystyle C_{nom,b,L}=20mm}$

${\displaystyle c_v=\mathrm{m}\mathrm{a}\mathrm{x}\{\begin{array}{l}20mm\\ 10mm\\ 20mm\end{array}}$

${\displaystyle d_1=c_v+\varnothing bue+\frac{\varnothing L}{2}}$	${\displaystyle |mit:c_v=20mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
	${\displaystyle |mit:\varnothing L=10mm}$
${\displaystyle d_1=20mm+0mm+\frac{10mm}{2}}$
${\displaystyle d_1=25,0mm}$

${\displaystyle d=h_L-d_1}$	${\displaystyle |mit:d_1=25mm}$
	${\displaystyle |mit:h_L=200mm}$
${\displaystyle d=200mm-25,0mm}$
${\displaystyle d=175mm=17,5cm}$

Bemessung mit dem ω-Verfahren m_{x,r1}

${\displaystyle z_s=d-\frac{h_L}{2}}$	${\displaystyle |mit:d=17,5cm}$
	${\displaystyle |mit:h_L=20cm}$
${\displaystyle z_s=17,5cm-\frac{20cm}{2}}$
${\displaystyle z_s=7,5cm}$

${\displaystyle M_{Eds}=M_{Ed}-extrn\cdot z_s}$	${\displaystyle |mit:z_s=7,5cm}$
	${\displaystyle |extrn=0}$
	${\displaystyle |mit:M_{Ed,S}=m_{x,r1}=1816\frac{kNcm}{m}}$
${\displaystyle M_{Eds}=1816\frac{kNcm}{m}-0\frac{kN}{m}\cdot 7,7cm}$
${\displaystyle M_{Eds}=1816\frac{kNcm}{m}}$

${\displaystyle {\mu }_{Eds}=\frac{M_{Eds}}{b\cdot d^2\cdot f_{cd}}}$	${\displaystyle |mit:d=17,5cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:M_{Eds}=1816\frac{kNcm}{m}}$
${\displaystyle {\mu }_{Eds}=\frac{1816\frac{kNcm}{m}}{100cm\cdot (17,5cm{)}^2\cdot 1,42\frac{kN}{c{m}^2}}}$
${\displaystyle {\mu }_{Eds}=0,0418}$

${\displaystyle \omega ={\omega }_1+\frac{{\omega }_2-{\omega }_1}{{\mu }_{Eds,2}-{\mu }_{Eds,1}}\cdot ({\mu }_{Eds}-{\mu }_{Eds,1})}$	${\displaystyle |mit:{\omega }_1=0,0410}$
	${\displaystyle |mit:{\omega }_2=0,0515}$
	${\displaystyle |mit:{\mu }_{Eds}=0,0418}$
	${\displaystyle |mit:{\mu }_{Eds,1}=0,04}$
	${\displaystyle |mit:{\mu }_{Eds,2}=0,05}$
${\displaystyle \omega =0,0410+\frac{0,0410-0,0306}{0,05-0,04}\cdot (0,0418-0,04)}$
${\displaystyle \omega =0,0387}$

${\displaystyle a_{sx,r1}=\frac{1}{{\sigma }_{sd}}\cdot (\omega \cdot b\cdot d\cdot f_{cd}+N_{Ed})}$	${\displaystyle |mit:\omega =0,0429}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:d=17,5cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:N_{Ed}=0}$
${\displaystyle a_{sx,r1}=\frac{1}{43,5\frac{kN}{c{m}^2}}\cdot (0,0429\cdot 100cm\cdot 17,5cm\cdot 1,42\frac{kN}{c{m}^2}+0\frac{kN}{m})}$
${\displaystyle a_{sx,r1}=2,45\frac{c{m}^2}{m}}$

gewählt: ø8 / 20cm, ${\displaystyle a_{sx,r1}=2,51\frac{c{m}^2}{m}}$

Biegebemessung m_{x,r1}

Vorbemessung m_{x,r1}

${\displaystyle z_{est}=0,75\cdot h}$	${\displaystyle |mit:h=h_p=20cm}$
${\displaystyle z_{est}=0,75\cdot 20cm}$
${\displaystyle z_{est}=15cm}$

${\displaystyle M_{Ed,est}=M_{Ed}-N_{Ed}\cdot z_{s1,est}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:N_{Ed}=0\frac{kN}{m}}$
	${\displaystyle |mit:M_{Ed}=m_{x,r1}=18,16\frac{kNm}{m}}$
${\displaystyle M_{Ed,est}=18,16\frac{kNm}{m}-0\frac{kN}{m}\cdot 0,15m}$
${\displaystyle M_{Ed,est}=18,16\frac{kNm}{m}}$

${\displaystyle a_{s,est}=\frac{M_{Ed,est}}{z_{s1,est}\cdot f_{yd}}+\frac{N_{Ed}}{f_{yd}}}$	${\displaystyle |mit:z_{s1,est}=15cm}$
	${\displaystyle |mit:f_{yd}=43,5\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:N_{Ed}=0}$
	${\displaystyle |mit:M_{Ed,est}=18,16\frac{kNm}{m}}$
${\displaystyle a_{s,est}=\frac{1816\frac{kNcm}{m}}{15cm\cdot 43,5\frac{kN}{c{m}^2}}+\frac{0}{43,5\frac{kN}{c{m}^2}}}$
${\displaystyle a_{s,est}\approx 2,78\frac{kNcm}{m}}$

gewählt: ø 10/25cm, ${\displaystyle a_s}=3,14\frac{c{m}^2}{m}$

Querschnittsgeometrie m_{x,r1}

Fehler beim Parsen (Unbekannte Funktion „\begin{cases}“): {\displaystyle c_{v}=\mathrm{max}\begin{cases} C_{nom,dur} \\ C_{nom,b,Bü} \\ C_{nom,b,L} \end{cases}}

${\displaystyle C_{nom,dur}=C_{min,dur}+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,dur}=10mm}$ für XC1
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
${\displaystyle C_{nom,dur}=10mm+10mm}$
${\displaystyle C_{nom,dur}=20mm}$

Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = C_{min,b,Bü} + \Delta C_{dev} }	Fehler beim Parsen (Syntaxfehler): {\displaystyle | mit: C_{min,b,Bü} = 0 mm }
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 0 mm + 10 mm }
Fehler beim Parsen (Syntaxfehler): {\displaystyle C_{nom,b,Bü} = 10 mm }

${\displaystyle C_{nom,b,L}=C_{min,b,L}-\varnothing bue+\mathrm{\Delta }{C}_{dev}}$	${\displaystyle |mit:C_{min,b,L}=7mm}$
	${\displaystyle |mit:\mathrm{\Delta }{C}_{dev}=10mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
${\displaystyle C_{nom,b,L}=10mm-0mm+\mathrm{\Delta }10mm}$
${\displaystyle C_{nom,b,L}=20mm}$

${\displaystyle c_v=\mathrm{m}\mathrm{a}\mathrm{x}\{\begin{array}{l}20mm\\ 10mm\\ 20mm\end{array}}$

${\displaystyle d_1=c_v+\varnothing bue+\frac{\varnothing L}{2}}$	${\displaystyle |mit:c_v=20mm}$
	${\displaystyle |mit:\varnothing bue=0mm}$
	${\displaystyle |mit:\varnothing L=10mm}$
${\displaystyle d_1=20mm+0mm+\frac{10mm}{2}}$
${\displaystyle d_1=25,0mm}$

${\displaystyle d=h_L-d_1}$	${\displaystyle |mit:d_1=25mm}$
	${\displaystyle |mit:h_L=200mm}$
${\displaystyle d=200mm-25,0mm}$
${\displaystyle d=175mm=17,5cm}$

Bemessung mit dem ω-Verfahren m_{x,r1}

${\displaystyle z_s=d-\frac{h_L}{2}}$	${\displaystyle |mit:d=17,5cm}$
	${\displaystyle |mit:h_L=20cm}$
${\displaystyle z_s=17,5cm-\frac{20cm}{2}}$
${\displaystyle z_s=7,5cm}$

${\displaystyle M_{Eds}=M_{Ed}-extrn\cdot z_s}$	${\displaystyle |mit:z_s=7,5cm}$
	${\displaystyle |extrn=0}$
	${\displaystyle |mit:M_{Ed,S}=m_{x,r1}=1816\frac{kNcm}{m}}$
${\displaystyle M_{Eds}=1816\frac{kNcm}{m}-0\frac{kN}{m}\cdot 7,7cm}$
${\displaystyle M_{Eds}=1816\frac{kNcm}{m}}$

${\displaystyle {\mu }_{Eds}=\frac{M_{Eds}}{b\cdot d^2\cdot f_{cd}}}$	${\displaystyle |mit:d=17,5cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:M_{Eds}=1816\frac{kNcm}{m}}$
${\displaystyle {\mu }_{Eds}=\frac{1816\frac{kNcm}{m}}{100cm\cdot (17,5cm{)}^2\cdot 1,42\frac{kN}{c{m}^2}}}$
${\displaystyle {\mu }_{Eds}=0,0418}$

${\displaystyle \omega ={\omega }_1+\frac{{\omega }_2-{\omega }_1}{{\mu }_{Eds,2}-{\mu }_{Eds,1}}\cdot ({\mu }_{Eds}-{\mu }_{Eds,1})}$	${\displaystyle |mit:{\omega }_1=0,0410}$
	${\displaystyle |mit:{\omega }_2=0,0515}$
	${\displaystyle |mit:{\mu }_{Eds}=0,0418}$
	${\displaystyle |mit:{\mu }_{Eds,1}=0,04}$
	${\displaystyle |mit:{\mu }_{Eds,2}=0,05}$
${\displaystyle \omega =0,0410+\frac{0,0410-0,0306}{0,05-0,04}\cdot (0,0418-0,04)}$
${\displaystyle \omega =0,0387}$

${\displaystyle a_{sx,r1}=\frac{1}{{\sigma }_{sd}}\cdot (\omega \cdot b\cdot d\cdot f_{cd}+N_{Ed})}$	${\displaystyle |mit:\omega =0,0429}$
	${\displaystyle |mit:f_{cd}=1,42\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:d=17,5cm}$
	${\displaystyle |mit:b=100cm}$
	${\displaystyle |mit:N_{Ed}=0}$
${\displaystyle a_{sx,r1}=\frac{1}{43,5\frac{kN}{c{m}^2}}\cdot (0,0429\cdot 100cm\cdot 17,5cm\cdot 1,42\frac{kN}{c{m}^2}+0\frac{kN}{m})}$
${\displaystyle a_{sx,r1}=2,45\frac{c{m}^2}{m}}$

gewählt: ø8 / 20cm, ${\displaystyle a_{sx,r1}=2,51\frac{c{m}^2}{m}}$

Querkraftbemessung

Bauteile ohne Querkraftbewehrung

${\displaystyle V_{Ed}=42,61\frac{kN}{m^2}}$

${\displaystyle C_{Rdc}=\frac{0,15}{{\gamma }_c}}$	${\displaystyle |mit:{\gamma }_c=1,5}$
${\displaystyle C_{Rdc}=\frac{0,15}{1,5}}$
${\displaystyle C_{Rdc}=0,1}$

${\displaystyle k=1+\sqrt{\frac{200}{d}}}$	${\displaystyle \{\begin{array}{l}\ge 1,0\\ \le 2,0\end{array}}$
	${\displaystyle |mit:d=176mm}$
${\displaystyle k=1+\sqrt{\frac{200}{176}}}$
${\displaystyle k=2,07}$	${\displaystyle \{\begin{array}{l}\ge 1,0\\ \ge 2,0\end{array}}$
${\displaystyle k=2}$

${\displaystyle {\rho }_l=\frac{A_{sl}}{b_w\cdot d}}$	${\displaystyle \le 0,02}$
	${\displaystyle |mit:A_{sl}=a_{sx,r}=2,51\frac{c{m}^2}{m}}$
	${\displaystyle |mit:b_w=100cm}$
	${\displaystyle |mit:d=17,6cm}$
${\displaystyle {\rho }_l=\frac{2,51\frac{c{m}^2}{m}}{100cm\cdot 17,6cm}}$
${\displaystyle {\rho }_l=1,43\cdot 10^{-3}}$	${\displaystyle \le 0,02}$

${\displaystyle A_c=A-A_s}$	${\displaystyle |mit:A=b_w\cdot h_L=b_w\cdot h_L=1000mm\cdot 200mm=200000}$
	${\displaystyle |mit:A_{s,a_{sx,r},a_{sy,r}}=251\frac{m{m}^2}{m}+113\frac{m{m}^2}{m}=364\frac{m{m}^2}{m}}$
${\displaystyle A_c=200000m{m}^2-364m{m}^2}$
${\displaystyle A_c=199636m{m}^2}$

${\displaystyle {\sigma }_{cp}=\frac{N_{Ed}}{A_c}}$	${\displaystyle |mit:N_{Ed}=0\frac{N}{m}}$
	${\displaystyle |mit:A_c=199636m{m}^2}$
${\displaystyle {\sigma }_{cp}=\frac{0\frac{N}{m}}{199636m{m}^2}}$
${\displaystyle {\sigma }_{cp}=0\frac{N}{m\cdot m{m}^2}}$

${\displaystyle V_{Rd,c}=[C_{Rdc}\cdot k\cdot {(100\cdot {\rho }_l\cdot f_{ck})}^{\frac{1}{3}}+0,12\cdot {\sigma }_{cp}]\cdot b_w\cdot d}$	${\displaystyle |mit:{\sigma }_{cp}=0\frac{N}{m{m}^2}}$
	${\displaystyle |mit:{\rho }_l=1,43\cdot 10^{-3}}$
	${\displaystyle |mit:k=2}$
	${\displaystyle |mit:C_{Rdc}=0,1}$
	${\displaystyle |mit:f_{ck}=25\frac{kN}{c{m}^2}}$
	${\displaystyle |mit:b_w=1000mm}$
	${\displaystyle |mit:d=176mm}$
${\displaystyle V_{Rd,c}=[0,1\cdot 2\cdot {(100\cdot 1,43\cdot 10^{-3}\cdot 25\frac{N}{m{m}^2})}^{\frac{1}{3}}+0,12\cdot 0\frac{N}{m{m}^2}]\cdot 1000mm\cdot 176mm}$
${\displaystyle V_{Rd,c}=53823N}$	${\displaystyle \ge V_{Ed}}$
${\displaystyle V_{Rd,c}=53,82kN}$	${\displaystyle \ge 42,61\frac{kN}{m^2}}$

Weitere Bemessung Hinsichtlich der Querkraft für dieses Bauteil nicht erforderlich da der Nachweis erfüllt ist .

Quellen

Normen

Fachliteratur

Links

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