Material Hub > Materialien

zur erweiterten Suche
SLUB Dresden (Datenanbieter)

INCONEL alloy 718

The elastic properties (Young's modulus, shear modulus) of Ni-based alloy Inconel IN718 were investigated between room temperature and 800 °C in an additively manufactured variant (laser powder bed fusion, PBF‑LB/M) and from a conventional process route (hot rolled bar). The moduli were determined using the dynamic resonance method. The data set includes information on processing parameters, heat treatments, grain size, specimen dimensions and weight, Young’s and shear modulus as well as their measurement uncertainty.

The dataset was generated in an accredited testing lab using calibrated measuring equipment. The calibrations meet the requirements of the test procedure and are metrologically traceable. The dataset was audited as BAM reference data. The dataset was made available under the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode).

Further information on data and data acquisition, analysis, and experimental details are given in “Elastic modulus data for additively and conventionally manufactured variants of Ti‑6Al‑4V, IN718 and AISI 316L” published in Scientific Data.

Symbolbild

Kategorie Metalle > Nichteisenmetalle > Schwermetalle > Nickel > Nickel based alloy
Art der Datenquelle Forschungsergebnis
Anwendungsgebiete aerospace; energy; medical; automotive; high temperature application
Schlagwörter
BAM reference data
Young's modulus
Shear modulus
Zenodo
Data set
alternative Namen
  • Werkstoffnummer: 2.4668
  • Kurzname: IN718

Daten bereitgestellt von

SLUB Dresden

Team Material Hub
Anfrage per E-Mail

Webseite | Mehr Details | Zu den Materialien von SLUB Dresden

Quelle
Ansprechpartner für diese Materialdaten

Material Hub-Team
Anfrage per E-Mail

Ergänzende Materialdaten

INCONEL alloy 718, additively manufactured, PBF-LB (IN_A_D_1)

The elastic properties (Young's modulus, shear modulus) of Ni-based alloy Inconel IN718 were investigated between room temperature and 800 °C in an additively manufactured variant (laser powder bed fusion, PBF‑LB/M) and from a conventional process route (hot rolled bar). The moduli were determined using the dynamic resonance method. The data set includes information on processing parameters, heat treatments, grain size, specimen dimensions and weight, Young’s and shear modulus as well as their measurement uncertainty.

The dataset was generated in an accredited testing lab using calibrated measuring equipment. The calibrations meet the requirements of the test procedure and are metrologically traceable. The dataset was audited as BAM reference data. The dataset was made available under the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode).

Further information on data and data acquisition, analysis, and experimental details are given in “Elastic modulus data for additively and conventionally manufactured variants of Ti‑6Al‑4V, IN718 and AISI 316L” published in Scientific Data.

Schlagwörter
BAM reference data
Young's modulus
Shear modulus
Zenodo
Data set
Art der Datenquelle Forschungsergebnis
Anwendungsgebiete aerospace; energy; medical; automotive; high temperature application
Bauform blank type: tower; Inclination of specimen (L-direction) relative to building direction = 45°; layer thickness = 60 µm; m = 22.254 g
Versuchsaufbau
  • Measurement of Young´s modulus and shear modulus: Elastotron 2000 (HTM Reetz, Berlin, Germany)

Herstellungsverfahren und Ausgangsmaterialien

Name additively manufactured, PBF-LB
Beschreibung machine: SLM Solutions 280HL (SLM Solutions Group AG, Germany); heat treatment: 1065°C/1.5h + air cooling to 50°C, 965°C/1h + forced air cooling to 50°C, 720°C/8h + controlled cooling to 620°C/8h + air cooling
Ausgangsmaterial

Physikalische Eigenschaften

Name Wert Bemerkung Messverfahren und -bedingungen
(mittlere) Korngröße 0.064 mm EBSD, section parallel to building direction
Abmessung (Länge) 100 mm T = 24 °C
Abmessung (Länge) 100.09 mm T = 100 °C
Abmessung (Länge) 100.21 mm T = 200 °C
Abmessung (Länge) 100.33 mm T = 300 °C
Abmessung (Länge) 100.45 mm T = 400 °C
Abmessung (Länge) 100.57 mm T = 500 °C
Abmessung (Länge) 100.69 mm T = 600 °C
Abmessung (Länge) 100.74 mm T = 650 °C
Abmessung (Länge) 100.8 mm T = 700 °C
Abmessung (Länge) 100.86 mm T = 750 °C
Abmessung (Länge) 100.92 mm T = 800 °C
Abmessung (Breite) 9.004 mm T = 24 °C
Abmessung (Breite) 9.012 mm T = 100 °C
Abmessung (Breite) 9.023 mm T = 200 °C
Abmessung (Breite) 9.034 mm T = 300 °C
Abmessung (Breite) 9.044 mm T = 400 °C
Abmessung (Breite) 9.055 mm T = 500 °C
Abmessung (Breite) 9.066 mm T = 600 °C
Abmessung (Breite) 9.071 mm T = 650 °C
Abmessung (Breite) 9.076 mm T = 700 °C
Abmessung (Breite) 9.082 mm T = 750 °C
Abmessung (Breite) 9.087 mm T = 800 °C
Abmessung (Tiefe) 3.002 mm T = 24 °C
Abmessung (Tiefe) 3.005 mm T = 100 °C
Abmessung (Tiefe) 3.008 mm T = 200 °C
Abmessung (Tiefe) 3.012 mm T = 300 °C
Abmessung (Tiefe) 3.015 mm T = 400 °C
Abmessung (Tiefe) 3.019 mm T = 500 °C
Abmessung (Tiefe) 3.023 mm T = 600 °C
Abmessung (Tiefe) 3.024 mm T = 650 °C
Abmessung (Tiefe) 3.026 mm T = 700 °C
Abmessung (Tiefe) 3.028 mm T = 750 °C
Abmessung (Tiefe) 3.03 mm T = 800 °C
Dichte 8.233 g/cm³ T = 24 °C
8.211 g/cm³ T = 100 °C
8.182 g/cm³ T = 200 °C
8.152 g/cm³ T = 300 °C
8.124 g/cm³ T = 400 °C
8.095 g/cm³ T = 500 °C
8.066 g/cm³ T = 600 °C
8.052 g/cm³ T = 650 °C
8.038 g/cm³ T = 700 °C
8.023 g/cm³ T = 750 °C
8.009 g/cm³ T = 800 °C
Mechanische Eigenschaften
 
Schubmodul 86 GPa ft = 9104.0 Hz ASTM E 1875, T = 24 °C
84 GPa ft = 8987.0 Hz ASTM E 1875, T = 100 °C
81 GPa ft = 8831.0 Hz ASTM E 1875, T = 200 °C
78 GPa ft = 8685.0 Hz ASTM E 1875, T = 300 °C
75 GPa ft = 8548.0 Hz ASTM E 1875, T = 400 °C
73 GPa ft = 8417.0 Hz ASTM E 1875, T = 500 °C
70 GPa ft = 8238.0 Hz ASTM E 1875, T = 600 °C
68 GPa ft = 8140.0 Hz ASTM E 1875, T = 650 °C
66 GPa ft = 8032.0 Hz ASTM E 1875, T = 700 °C
64 GPa ft = 7902.0 Hz ASTM E 1875, T = 750 °C
62 GPa ft = 7758.0 Hz ASTM E 1875, T = 800 °C
Zug-Elastizitätsmodul 210 GPa mean ASTM E 1875, T = 24 °C
210 GPa flat-wise in the thickness direction, ff(f) = 1555.0 Hz ASTM E 1875, T = 24 °C
209 GPa edge-wise in the width direction, ff(e) = 4540.0 Hz ASTM E 1875, T = 24 °C
205 GPa mean ASTM E 1875, T = 100 °C
206 GPa flat-wise in the thickness direction, ff(f) = 1538.0 Hz ASTM E 1875, T = 100 °C
204 GPa edge-wise in the width direction, ff(e) = 4487.0 Hz ASTM E 1875, T = 100 °C
198 GPa mean ASTM E 1875, T = 200 °C
199 GPa flat-wise in the thickness direction, ff(f) = 1513.0 Hz ASTM E 1875, T = 200 °C
197 GPa edge-wise in the width direction, ff(e) = 4413.0 Hz ASTM E 1875, T = 200 °C
192 GPa mean ASTM E 1875, T = 300 °C
193 GPa flat-wise in the thickness direction, ff(f) = 1490.0 Hz ASTM E 1875, T = 300 °C
191 GPa edge-wise in the width direction, ff(e) = 4347.0 Hz ASTM E 1875, T = 300 °C
186 GPa mean ASTM E 1875, T = 400 °C
187 GPa flat-wise in the thickness direction, ff(f) = 1468.0 Hz ASTM E 1875, T = 400 °C
185 GPa edge-wise in the width direction, ff(e) = 4281.0 Hz ASTM E 1875, T = 400 °C
180 GPa mean ASTM E 1875, T = 500 °C
181 GPa flat-wise in the thickness direction, ff(f) = 1445.0 Hz ASTM E 1875, T = 500 °C
179 GPa edge-wise in the width direction, ff(e) = 4216.0 Hz ASTM E 1875, T = 500 °C
173 GPa mean ASTM E 1875, T = 600 °C
173 GPa flat-wise in the thickness direction, ff(f) = 1417.0 Hz ASTM E 1875, T = 600 °C
172 GPa edge-wise in the width direction, ff(e) = 4132.0 Hz ASTM E 1875, T = 600 °C
169 GPa mean ASTM E 1875, T = 650 °C
169 GPa flat-wise in the thickness direction, ff(f) = 1401.0 Hz ASTM E 1875, T = 650 °C
168 GPa edge-wise in the width direction, ff(e) = 4087.0 Hz ASTM E 1875, T = 650 °C
164 GPa mean ASTM E 1875, T = 700 °C
165 GPa flat-wise in the thickness direction, ff(f) = 1382.0 Hz ASTM E 1875, T = 700 °C
164 GPa edge-wise in the width direction, ff(e) = 4033.0 Hz ASTM E 1875, T = 700 °C
159 GPa mean ASTM E 1875, T = 750 °C
160 GPa flat-wise in the thickness direction, ff(f) = 1361.0 Hz ASTM E 1875, T = 750 °C
159 GPa edge-wise in the width direction, ff(e) = 3970.0 Hz ASTM E 1875, T = 750 °C
154 GPa mean ASTM E 1875, T = 800 °C
154 GPa flat-wise in the thickness direction, ff(f) = 1338.0 Hz ASTM E 1875, T = 800 °C
153 GPa edge-wise in the width direction, ff(e) = 3901.0 Hz ASTM E 1875, T = 800 °C
Thermische Eigenschaften
 
linearer Längenausdehnungskoeffizient 11.9 10⁻⁶/K T = 100 °C
11.9 10⁻⁶/K T = 200 °C
11.9 10⁻⁶/K T = 300 °C
11.9 10⁻⁶/K T = 400 °C
11.9 10⁻⁶/K T = 500 °C
11.9 10⁻⁶/K T = 600 °C
11.9 10⁻⁶/K T = 650 °C
11.9 10⁻⁶/K T = 700 °C
11.9 10⁻⁶/K T = 750 °C
11.9 10⁻⁶/K T = 800 °C

Chemische Eigenschaften

chemische Zusammensetzung, elementar (Gewichtsprozent)
Ni

54.3 

Cr

17.82 

Fe

18.36 

Nb

4.38 

Mo

3.46 

Ti

0.92 

Al

0.48 

Co

0.07 

Mn

0.09 

Si

0.05 

Cu

0.03 

Abbildungen und Diagramme

Tensile Modulus of Elasticity at different Temperatures
Tensile Modulus of Elasticity at different Temperatures
Change of Dimensions at different Temperatures compared to 24 °C
Change of Dimensions at different Temperatures compared to 24 °C
Density at different Temperatures
Density at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Shear Modulus at different Temperatures
Shear Modulus at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
weitere Angaben
  • T = temperature
  • m = mass
  • ff(e) = fundamental resonance frequency of the bar in flexure (edge wise)
  • ff(f) = fundamental resonance frequency of the bar in flexure (flat wise)
  • ft = fundamental resonance frequency of the bar in torsion
zugehörige wissenschaftliche Publikation

Beteiligte

Daten bereitgestellt von

SLUB Dresden

Team Material Hub
Anfrage per E-Mail

Webseite | Mehr Details

Ansprechpartner für diese Materialdaten

Material Hub-Team
Anfrage per E-Mail

Haftungsausschluss

Die BAM Referenzdaten wurden von der Bundesanstalt für Materialforschung und -prüfung (BAM) unter der Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode) auf Zenodo bereitgestellt.Die SLUB hat die bereitgestellten Inhalte einer Normalisierung unterzogen, die notwendig ist, um eine umfassende Recherche und die Vergleichbarkeit der Materialien zu ermöglichen. Trotz größter zumutbarer Sorgfalt können bei diesem Normalisierungsprozess Fehler auftreten, weshalb ausdrücklich darauf hingewiesen wird, dass auf Grundlage der im Material Hub vorhandenen Daten keine Entscheidungen zur Verwendung oder Anschaffung eines Materials getroffen werden dürfen. Vielmehr ist es notwendig den Datenerzeuger im Vorfeld einer solchen Entscheidung direkt zu kontaktieren, um die Korrektheit der Daten zu verifizieren.

INCONEL alloy 718, additively manufactured, PBF-LB (IN_A_D_2)

The elastic properties (Young's modulus, shear modulus) of Ni-based alloy Inconel IN718 were investigated between room temperature and 800 °C in an additively manufactured variant (laser powder bed fusion, PBF‑LB/M) and from a conventional process route (hot rolled bar). The moduli were determined using the dynamic resonance method. The data set includes information on processing parameters, heat treatments, grain size, specimen dimensions and weight, Young’s and shear modulus as well as their measurement uncertainty.

The dataset was generated in an accredited testing lab using calibrated measuring equipment. The calibrations meet the requirements of the test procedure and are metrologically traceable. The dataset was audited as BAM reference data. The dataset was made available under the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode).

Further information on data and data acquisition, analysis, and experimental details are given in “Elastic modulus data for additively and conventionally manufactured variants of Ti‑6Al‑4V, IN718 and AISI 316L” published in Scientific Data.

Schlagwörter
BAM reference data
Young's modulus
Shear modulus
Zenodo
Data set
Art der Datenquelle Forschungsergebnis
Anwendungsgebiete aerospace; energy; medical; automotive; high temperature application
Bauform blank type: tower; Inclination of specimen (L-direction) relative to building direction = 45°; layer thickness = 60 µm; m = 22.215 g
Versuchsaufbau
  • Measurement of Young´s modulus and shear modulus: Elastotron 2000 (HTM Reetz, Berlin, Germany)

Herstellungsverfahren und Ausgangsmaterialien

Name additively manufactured, PBF-LB
Beschreibung machine: SLM Solutions 280HL (SLM Solutions Group AG, Germany); heat treatment: 1065°C/1.5h + air cooling to 50°C, 965°C/1h + forced air cooling to 50°C, 720°C/8h + controlled cooling to 620°C/8h + air cooling
Ausgangsmaterial

Physikalische Eigenschaften

Name Wert Bemerkung Messverfahren und -bedingungen
(mittlere) Korngröße 0.064 mm EBSD, section parallel to building direction
Abmessung (Länge) 100 mm T = 24 °C
Abmessung (Länge) 100.09 mm T = 100 °C
Abmessung (Länge) 100.21 mm T = 200 °C
Abmessung (Länge) 100.33 mm T = 300 °C
Abmessung (Länge) 100.45 mm T = 400 °C
Abmessung (Länge) 100.57 mm T = 500 °C
Abmessung (Länge) 100.69 mm T = 600 °C
Abmessung (Länge) 100.74 mm T = 650 °C
Abmessung (Länge) 100.8 mm T = 700 °C
Abmessung (Länge) 100.86 mm T = 750 °C
Abmessung (Länge) 100.92 mm T = 800 °C
Abmessung (Breite) 8.995 mm T = 24 °C
Abmessung (Breite) 9.003 mm T = 100 °C
Abmessung (Breite) 9.014 mm T = 200 °C
Abmessung (Breite) 9.025 mm T = 300 °C
Abmessung (Breite) 9.035 mm T = 400 °C
Abmessung (Breite) 9.046 mm T = 500 °C
Abmessung (Breite) 9.057 mm T = 600 °C
Abmessung (Breite) 9.062 mm T = 650 °C
Abmessung (Breite) 9.067 mm T = 700 °C
Abmessung (Breite) 9.073 mm T = 750 °C
Abmessung (Breite) 9.078 mm T = 800 °C
Abmessung (Tiefe) 2.998 mm T = 24 °C
Abmessung (Tiefe) 3.001 mm T = 100 °C
Abmessung (Tiefe) 3.004 mm T = 200 °C
Abmessung (Tiefe) 3.008 mm T = 300 °C
Abmessung (Tiefe) 3.011 mm T = 400 °C
Abmessung (Tiefe) 3.015 mm T = 500 °C
Abmessung (Tiefe) 3.019 mm T = 600 °C
Abmessung (Tiefe) 3.02 mm T = 650 °C
Abmessung (Tiefe) 3.022 mm T = 700 °C
Abmessung (Tiefe) 3.024 mm T = 750 °C
Abmessung (Tiefe) 3.026 mm T = 800 °C
Dichte 8.238 g/cm³ T = 24 °C
8.216 g/cm³ T = 100 °C
8.186 g/cm³ T = 200 °C
8.157 g/cm³ T = 300 °C
8.128 g/cm³ T = 400 °C
8.099 g/cm³ T = 500 °C
8.071 g/cm³ T = 600 °C
8.056 g/cm³ T = 650 °C
8.042 g/cm³ T = 700 °C
8.028 g/cm³ T = 750 °C
8.014 g/cm³ T = 800 °C
Mechanische Eigenschaften
 
Schubmodul 84 GPa ft = 8989.0 Hz ASTM E 1875, T = 24 °C
81 GPa ft = 8856.0 Hz ASTM E 1875, T = 100 °C
78 GPa ft = 8704.0 Hz ASTM E 1875, T = 200 °C
76 GPa ft = 8560.0 Hz ASTM E 1875, T = 300 °C
73 GPa ft = 8433.0 Hz ASTM E 1875, T = 400 °C
71 GPa ft = 8299.0 Hz ASTM E 1875, T = 500 °C
68 GPa ft = 8116.0 Hz ASTM E 1875, T = 600 °C
66 GPa ft = 8024.0 Hz ASTM E 1875, T = 650 °C
64 GPa ft = 7913.0 Hz ASTM E 1875, T = 700 °C
62 GPa ft = 7786.0 Hz ASTM E 1875, T = 750 °C
60 GPa ft = 7650.0 Hz ASTM E 1875, T = 800 °C
Zug-Elastizitätsmodul 212 GPa mean ASTM E 1875, T = 24 °C
213 GPa flat-wise in the thickness direction, ff(f) = 1563.0 Hz ASTM E 1875, T = 24 °C
211 GPa edge-wise in the width direction, ff(e) = 4556.0 Hz ASTM E 1875, T = 24 °C
206 GPa mean ASTM E 1875, T = 100 °C
207 GPa flat-wise in the thickness direction, ff(f) = 1542.0 Hz ASTM E 1875, T = 100 °C
206 GPa edge-wise in the width direction, ff(e) = 4495.0 Hz ASTM E 1875, T = 100 °C
200 GPa mean ASTM E 1875, T = 200 °C
201 GPa flat-wise in the thickness direction, ff(f) = 1518.0 Hz ASTM E 1875, T = 200 °C
199 GPa edge-wise in the width direction, ff(e) = 4424.0 Hz ASTM E 1875, T = 200 °C
193 GPa mean ASTM E 1875, T = 300 °C
194 GPa flat-wise in the thickness direction, ff(f) = 1495.0 Hz ASTM E 1875, T = 300 °C
193 GPa edge-wise in the width direction, ff(e) = 4355.0 Hz ASTM E 1875, T = 300 °C
188 GPa mean ASTM E 1875, T = 400 °C
189 GPa flat-wise in the thickness direction, ff(f) = 1474.0 Hz ASTM E 1875, T = 400 °C
187 GPa edge-wise in the width direction, ff(e) = 4293.0 Hz ASTM E 1875, T = 400 °C
182 GPa mean ASTM E 1875, T = 500 °C
183 GPa flat-wise in the thickness direction, ff(f) = 1451.0 Hz ASTM E 1875, T = 500 °C
181 GPa edge-wise in the width direction, ff(e) = 4226.0 Hz ASTM E 1875, T = 500 °C
175 GPa mean ASTM E 1875, T = 600 °C
176 GPa flat-wise in the thickness direction, ff(f) = 1423.0 Hz ASTM E 1875, T = 600 °C
174 GPa edge-wise in the width direction, ff(e) = 4143.0 Hz ASTM E 1875, T = 600 °C
171 GPa mean ASTM E 1875, T = 650 °C
172 GPa flat-wise in the thickness direction, ff(f) = 1408.0 Hz ASTM E 1875, T = 650 °C
170 GPa edge-wise in the width direction, ff(e) = 4097.0 Hz ASTM E 1875, T = 650 °C
166 GPa mean ASTM E 1875, T = 700 °C
167 GPa flat-wise in the thickness direction, ff(f) = 1390.0 Hz ASTM E 1875, T = 700 °C
165 GPa edge-wise in the width direction, ff(e) = 4043.0 Hz ASTM E 1875, T = 700 °C
161 GPa mean ASTM E 1875, T = 750 °C
162 GPa flat-wise in the thickness direction, ff(f) = 1369.0 Hz ASTM E 1875, T = 750 °C
160 GPa edge-wise in the width direction, ff(e) = 3982.0 Hz ASTM E 1875, T = 750 °C
156 GPa mean ASTM E 1875, T = 800 °C
157 GPa flat-wise in the thickness direction, ff(f) = 1346.0 Hz ASTM E 1875, T = 800 °C
155 GPa edge-wise in the width direction, ff(e) = 3915.0 Hz ASTM E 1875, T = 800 °C
Thermische Eigenschaften
 
linearer Längenausdehnungskoeffizient 11.9 10⁻⁶/K T = 100 °C
11.9 10⁻⁶/K T = 200 °C
11.9 10⁻⁶/K T = 300 °C
11.9 10⁻⁶/K T = 400 °C
11.9 10⁻⁶/K T = 500 °C
11.9 10⁻⁶/K T = 600 °C
11.9 10⁻⁶/K T = 650 °C
11.9 10⁻⁶/K T = 700 °C
11.9 10⁻⁶/K T = 750 °C
11.9 10⁻⁶/K T = 800 °C

Chemische Eigenschaften

chemische Zusammensetzung, elementar (Gewichtsprozent)
Ni

54.3 

Cr

17.82 

Fe

18.36 

Nb

4.38 

Mo

3.46 

Ti

0.92 

Al

0.48 

Co

0.07 

Mn

0.09 

Si

0.05 

Cu

0.03 

Abbildungen und Diagramme

Tensile Modulus of Elasticity at different Temperatures
Tensile Modulus of Elasticity at different Temperatures
Change of Dimensions at different Temperatures compared to 24 °C
Change of Dimensions at different Temperatures compared to 24 °C
Density at different Temperatures
Density at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Shear Modulus at different Temperatures
Shear Modulus at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
weitere Angaben
  • T = temperature
  • m = mass
  • ff(e) = fundamental resonance frequency of the bar in flexure (edge wise)
  • ff(f) = fundamental resonance frequency of the bar in flexure (flat wise)
  • ft = fundamental resonance frequency of the bar in torsion
zugehörige wissenschaftliche Publikation

Beteiligte

Daten bereitgestellt von

SLUB Dresden

Team Material Hub
Anfrage per E-Mail

Webseite | Mehr Details

Ansprechpartner für diese Materialdaten

Material Hub-Team
Anfrage per E-Mail

Haftungsausschluss

Die BAM Referenzdaten wurden von der Bundesanstalt für Materialforschung und -prüfung (BAM) unter der Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode) auf Zenodo bereitgestellt.Die SLUB hat die bereitgestellten Inhalte einer Normalisierung unterzogen, die notwendig ist, um eine umfassende Recherche und die Vergleichbarkeit der Materialien zu ermöglichen. Trotz größter zumutbarer Sorgfalt können bei diesem Normalisierungsprozess Fehler auftreten, weshalb ausdrücklich darauf hingewiesen wird, dass auf Grundlage der im Material Hub vorhandenen Daten keine Entscheidungen zur Verwendung oder Anschaffung eines Materials getroffen werden dürfen. Vielmehr ist es notwendig den Datenerzeuger im Vorfeld einer solchen Entscheidung direkt zu kontaktieren, um die Korrektheit der Daten zu verifizieren.

INCONEL alloy 718, additively manufactured, PBF-LB (IN_A_H_1)

The elastic properties (Young's modulus, shear modulus) of Ni-based alloy Inconel IN718 were investigated between room temperature and 800 °C in an additively manufactured variant (laser powder bed fusion, PBF‑LB/M) and from a conventional process route (hot rolled bar). The moduli were determined using the dynamic resonance method. The data set includes information on processing parameters, heat treatments, grain size, specimen dimensions and weight, Young’s and shear modulus as well as their measurement uncertainty.

The dataset was generated in an accredited testing lab using calibrated measuring equipment. The calibrations meet the requirements of the test procedure and are metrologically traceable. The dataset was audited as BAM reference data. The dataset was made available under the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode).

Further information on data and data acquisition, analysis, and experimental details are given in “Elastic modulus data for additively and conventionally manufactured variants of Ti‑6Al‑4V, IN718 and AISI 316L” published in Scientific Data.

Schlagwörter
BAM reference data
Young's modulus
Shear modulus
Zenodo
Data set
Art der Datenquelle Forschungsergebnis
Anwendungsgebiete aerospace; energy; medical; automotive; high temperature application
Bauform blank type: tower; Inclination of specimen (L-direction) relative to building direction = 90°; layer thickness = 60 µm; m = 22.21 g
Versuchsaufbau
  • Measurement of Young´s modulus and shear modulus: Elastotron 2000 (HTM Reetz, Berlin, Germany)

Herstellungsverfahren und Ausgangsmaterialien

Name additively manufactured, PBF-LB
Beschreibung machine: SLM Solutions 280HL (SLM Solutions Group AG, Germany); heat treatment: 1065°C/1.5h + air cooling to 50°C, 965°C/1h + forced air cooling to 50°C, 720°C/8h + controlled cooling to 620°C/8h + air cooling
Ausgangsmaterial

Physikalische Eigenschaften

Name Wert Bemerkung Messverfahren und -bedingungen
(mittlere) Korngröße 0.064 mm EBSD, section parallel to building direction
Abmessung (Länge) 100.01 mm T = 24 °C
Abmessung (Länge) 100.1 mm T = 100 °C
Abmessung (Länge) 100.22 mm T = 200 °C
Abmessung (Länge) 100.34 mm T = 300 °C
Abmessung (Länge) 100.46 mm T = 400 °C
Abmessung (Länge) 100.58 mm T = 500 °C
Abmessung (Länge) 100.7 mm T = 600 °C
Abmessung (Länge) 100.76 mm T = 650 °C
Abmessung (Länge) 100.81 mm T = 700 °C
Abmessung (Länge) 100.87 mm T = 750 °C
Abmessung (Länge) 100.93 mm T = 800 °C
Abmessung (Breite) 9 mm T = 24 °C
Abmessung (Breite) 9.008 mm T = 100 °C
Abmessung (Breite) 9.019 mm T = 200 °C
Abmessung (Breite) 9.03 mm T = 300 °C
Abmessung (Breite) 9.04 mm T = 400 °C
Abmessung (Breite) 9.051 mm T = 500 °C
Abmessung (Breite) 9.062 mm T = 600 °C
Abmessung (Breite) 9.067 mm T = 650 °C
Abmessung (Breite) 9.072 mm T = 700 °C
Abmessung (Breite) 9.078 mm T = 750 °C
Abmessung (Breite) 9.083 mm T = 800 °C
Abmessung (Tiefe) 2.999 mm T = 24 °C
Abmessung (Tiefe) 3.002 mm T = 100 °C
Abmessung (Tiefe) 3.005 mm T = 200 °C
Abmessung (Tiefe) 3.009 mm T = 300 °C
Abmessung (Tiefe) 3.012 mm T = 400 °C
Abmessung (Tiefe) 3.016 mm T = 500 °C
Abmessung (Tiefe) 3.02 mm T = 600 °C
Abmessung (Tiefe) 3.021 mm T = 650 °C
Abmessung (Tiefe) 3.023 mm T = 700 °C
Abmessung (Tiefe) 3.025 mm T = 750 °C
Abmessung (Tiefe) 3.027 mm T = 800 °C
Dichte 8.228 g/cm³ T = 24 °C
8.206 g/cm³ T = 100 °C
8.176 g/cm³ T = 200 °C
8.147 g/cm³ T = 300 °C
8.118 g/cm³ T = 400 °C
8.09 g/cm³ T = 500 °C
8.061 g/cm³ T = 600 °C
8.047 g/cm³ T = 650 °C
8.032 g/cm³ T = 700 °C
8.018 g/cm³ T = 750 °C
8.004 g/cm³ T = 800 °C
Mechanische Eigenschaften
 
Schubmodul 77 GPa ft = 8641.0 Hz ASTM E 1875, T = 24 °C
75 GPa ft = 8524.0 Hz ASTM E 1875, T = 100 °C
72 GPa ft = 8377.0 Hz ASTM E 1875, T = 200 °C
70 GPa ft = 8235.0 Hz ASTM E 1875, T = 300 °C
68 GPa ft = 8098.0 Hz ASTM E 1875, T = 400 °C
65 GPa ft = 7954.0 Hz ASTM E 1875, T = 500 °C
62 GPa ft = 7779.0 Hz ASTM E 1875, T = 600 °C
61 GPa ft = 7689.0 Hz ASTM E 1875, T = 650 °C
59 GPa ft = 7574.0 Hz ASTM E 1875, T = 700 °C
57 GPa ft = 7457.0 Hz ASTM E 1875, T = 750 °C
55 GPa ft = 7316.0 Hz ASTM E 1875, T = 800 °C
Zug-Elastizitätsmodul 236 GPa mean ASTM E 1875, T = 24 °C
235 GPa flat-wise in the thickness direction, ff(f) = 1643.0 Hz ASTM E 1875, T = 24 °C
236 GPa edge-wise in the width direction, ff(e) = 4799.0 Hz ASTM E 1875, T = 24 °C
230 GPa mean ASTM E 1875, T = 100 °C
230 GPa flat-wise in the thickness direction, ff(f) = 1625.0 Hz ASTM E 1875, T = 100 °C
231 GPa edge-wise in the width direction, ff(e) = 4744.0 Hz ASTM E 1875, T = 100 °C
223 GPa mean ASTM E 1875, T = 200 °C
223 GPa flat-wise in the thickness direction, ff(f) = 1601.0 Hz ASTM E 1875, T = 200 °C
224 GPa edge-wise in the width direction, ff(e) = 4672.0 Hz ASTM E 1875, T = 200 °C
216 GPa mean ASTM E 1875, T = 300 °C
216 GPa flat-wise in the thickness direction, ff(f) = 1577.0 Hz ASTM E 1875, T = 300 °C
217 GPa edge-wise in the width direction, ff(e) = 4603.0 Hz ASTM E 1875, T = 300 °C
210 GPa mean ASTM E 1875, T = 400 °C
210 GPa flat-wise in the thickness direction, ff(f) = 1554.0 Hz ASTM E 1875, T = 400 °C
210 GPa edge-wise in the width direction, ff(e) = 4536.0 Hz ASTM E 1875, T = 400 °C
204 GPa mean ASTM E 1875, T = 500 °C
203 GPa flat-wise in the thickness direction, ff(f) = 1531.0 Hz ASTM E 1875, T = 500 °C
204 GPa edge-wise in the width direction, ff(e) = 4472.0 Hz ASTM E 1875, T = 500 °C
196 GPa mean ASTM E 1875, T = 600 °C
196 GPa flat-wise in the thickness direction, ff(f) = 1503.0 Hz ASTM E 1875, T = 600 °C
196 GPa edge-wise in the width direction, ff(e) = 4384.0 Hz ASTM E 1875, T = 600 °C
192 GPa mean ASTM E 1875, T = 650 °C
191 GPa flat-wise in the thickness direction, ff(f) = 1487.0 Hz ASTM E 1875, T = 650 °C
192 GPa edge-wise in the width direction, ff(e) = 4342.0 Hz ASTM E 1875, T = 650 °C
187 GPa mean ASTM E 1875, T = 700 °C
187 GPa flat-wise in the thickness direction, ff(f) = 1469.0 Hz ASTM E 1875, T = 700 °C
188 GPa edge-wise in the width direction, ff(e) = 4287.0 Hz ASTM E 1875, T = 700 °C
182 GPa mean ASTM E 1875, T = 750 °C
181 GPa flat-wise in the thickness direction, ff(f) = 1449.0 Hz ASTM E 1875, T = 750 °C
182 GPa edge-wise in the width direction, ff(e) = 4228.0 Hz ASTM E 1875, T = 750 °C
176 GPa mean ASTM E 1875, T = 800 °C
176 GPa flat-wise in the thickness direction, ff(f) = 1427.0 Hz ASTM E 1875, T = 800 °C
177 GPa edge-wise in the width direction, ff(e) = 4160.0 Hz ASTM E 1875, T = 800 °C
Thermische Eigenschaften
 
linearer Längenausdehnungskoeffizient 11.9 10⁻⁶/K T = 100 °C
11.9 10⁻⁶/K T = 200 °C
11.9 10⁻⁶/K T = 300 °C
11.9 10⁻⁶/K T = 400 °C
11.9 10⁻⁶/K T = 500 °C
11.9 10⁻⁶/K T = 600 °C
11.9 10⁻⁶/K T = 650 °C
11.9 10⁻⁶/K T = 700 °C
11.9 10⁻⁶/K T = 750 °C
11.9 10⁻⁶/K T = 800 °C

Chemische Eigenschaften

chemische Zusammensetzung, elementar (Gewichtsprozent)
Ni

54.3 

Cr

17.82 

Fe

18.36 

Nb

4.38 

Mo

3.46 

Ti

0.92 

Al

0.48 

Co

0.07 

Mn

0.09 

Si

0.05 

Cu

0.03 

Abbildungen und Diagramme

Tensile Modulus of Elasticity at different Temperatures
Tensile Modulus of Elasticity at different Temperatures
Change of Dimensions at different Temperatures compared to 24 °C
Change of Dimensions at different Temperatures compared to 24 °C
Density at different Temperatures
Density at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Shear Modulus at different Temperatures
Shear Modulus at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
weitere Angaben
  • T = temperature
  • m = mass
  • ff(e) = fundamental resonance frequency of the bar in flexure (edge wise)
  • ff(f) = fundamental resonance frequency of the bar in flexure (flat wise)
  • ft = fundamental resonance frequency of the bar in torsion
zugehörige wissenschaftliche Publikation

Beteiligte

Daten bereitgestellt von

SLUB Dresden

Team Material Hub
Anfrage per E-Mail

Webseite | Mehr Details

Ansprechpartner für diese Materialdaten

Material Hub-Team
Anfrage per E-Mail

Haftungsausschluss

Die BAM Referenzdaten wurden von der Bundesanstalt für Materialforschung und -prüfung (BAM) unter der Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode) auf Zenodo bereitgestellt.Die SLUB hat die bereitgestellten Inhalte einer Normalisierung unterzogen, die notwendig ist, um eine umfassende Recherche und die Vergleichbarkeit der Materialien zu ermöglichen. Trotz größter zumutbarer Sorgfalt können bei diesem Normalisierungsprozess Fehler auftreten, weshalb ausdrücklich darauf hingewiesen wird, dass auf Grundlage der im Material Hub vorhandenen Daten keine Entscheidungen zur Verwendung oder Anschaffung eines Materials getroffen werden dürfen. Vielmehr ist es notwendig den Datenerzeuger im Vorfeld einer solchen Entscheidung direkt zu kontaktieren, um die Korrektheit der Daten zu verifizieren.

INCONEL alloy 718, additively manufactured, PBF-LB (IN_A_H_2)

The elastic properties (Young's modulus, shear modulus) of Ni-based alloy Inconel IN718 were investigated between room temperature and 800 °C in an additively manufactured variant (laser powder bed fusion, PBF‑LB/M) and from a conventional process route (hot rolled bar). The moduli were determined using the dynamic resonance method. The data set includes information on processing parameters, heat treatments, grain size, specimen dimensions and weight, Young’s and shear modulus as well as their measurement uncertainty.

The dataset was generated in an accredited testing lab using calibrated measuring equipment. The calibrations meet the requirements of the test procedure and are metrologically traceable. The dataset was audited as BAM reference data. The dataset was made available under the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode).

Further information on data and data acquisition, analysis, and experimental details are given in “Elastic modulus data for additively and conventionally manufactured variants of Ti‑6Al‑4V, IN718 and AISI 316L” published in Scientific Data.

Schlagwörter
BAM reference data
Young's modulus
Shear modulus
Zenodo
Data set
Art der Datenquelle Forschungsergebnis
Anwendungsgebiete aerospace; energy; medical; automotive; high temperature application
Bauform blank type: tower; Inclination of specimen (L-direction) relative to building direction = 90°; layer thickness = 60 µm; m = 22.202 g
Versuchsaufbau
  • Measurement of Young´s modulus and shear modulus: Elastotron 2000 (HTM Reetz, Berlin, Germany)

Herstellungsverfahren und Ausgangsmaterialien

Name additively manufactured, PBF-LB
Beschreibung machine: SLM Solutions 280HL (SLM Solutions Group AG, Germany); heat treatment: 1065°C/1.5h + air cooling to 50°C, 965°C/1h + forced air cooling to 50°C, 720°C/8h + controlled cooling to 620°C/8h + air cooling
Ausgangsmaterial

Physikalische Eigenschaften

Name Wert Bemerkung Messverfahren und -bedingungen
(mittlere) Korngröße 0.064 mm EBSD, section parallel to building direction
Abmessung (Länge) 100 mm T = 24 °C
Abmessung (Länge) 100.09 mm T = 100 °C
Abmessung (Länge) 100.21 mm T = 200 °C
Abmessung (Länge) 100.33 mm T = 300 °C
Abmessung (Länge) 100.45 mm T = 400 °C
Abmessung (Länge) 100.57 mm T = 500 °C
Abmessung (Länge) 100.69 mm T = 600 °C
Abmessung (Länge) 100.74 mm T = 650 °C
Abmessung (Länge) 100.8 mm T = 700 °C
Abmessung (Länge) 100.86 mm T = 750 °C
Abmessung (Länge) 100.92 mm T = 800 °C
Abmessung (Breite) 9.001 mm T = 24 °C
Abmessung (Breite) 9.009 mm T = 100 °C
Abmessung (Breite) 9.02 mm T = 200 °C
Abmessung (Breite) 9.031 mm T = 300 °C
Abmessung (Breite) 9.041 mm T = 400 °C
Abmessung (Breite) 9.052 mm T = 500 °C
Abmessung (Breite) 9.063 mm T = 600 °C
Abmessung (Breite) 9.068 mm T = 650 °C
Abmessung (Breite) 9.073 mm T = 700 °C
Abmessung (Breite) 9.079 mm T = 750 °C
Abmessung (Breite) 9.084 mm T = 800 °C
Abmessung (Tiefe) 3 mm T = 24 °C
Abmessung (Tiefe) 3.003 mm T = 100 °C
Abmessung (Tiefe) 3.006 mm T = 200 °C
Abmessung (Tiefe) 3.01 mm T = 300 °C
Abmessung (Tiefe) 3.013 mm T = 400 °C
Abmessung (Tiefe) 3.017 mm T = 500 °C
Abmessung (Tiefe) 3.021 mm T = 600 °C
Abmessung (Tiefe) 3.022 mm T = 650 °C
Abmessung (Tiefe) 3.024 mm T = 700 °C
Abmessung (Tiefe) 3.026 mm T = 750 °C
Abmessung (Tiefe) 3.028 mm T = 800 °C
Dichte 8.222 g/cm³ T = 24 °C
8.2 g/cm³ T = 100 °C
8.171 g/cm³ T = 200 °C
8.142 g/cm³ T = 300 °C
8.113 g/cm³ T = 400 °C
8.084 g/cm³ T = 500 °C
8.055 g/cm³ T = 600 °C
8.041 g/cm³ T = 650 °C
8.027 g/cm³ T = 700 °C
8.013 g/cm³ T = 750 °C
7.998 g/cm³ T = 800 °C
Mechanische Eigenschaften
 
Schubmodul 77 GPa ft = 8652.0 Hz ASTM E 1875, T = 24 °C
75 GPa ft = 8546.0 Hz ASTM E 1875, T = 100 °C
73 GPa ft = 8390.0 Hz ASTM E 1875, T = 200 °C
70 GPa ft = 8255.0 Hz ASTM E 1875, T = 300 °C
68 GPa ft = 8115.0 Hz ASTM E 1875, T = 400 °C
65 GPa ft = 7977.0 Hz ASTM E 1875, T = 500 °C
63 GPa ft = 7804.0 Hz ASTM E 1875, T = 600 °C
61 GPa ft = 7710.0 Hz ASTM E 1875, T = 650 °C
59 GPa ft = 7597.0 Hz ASTM E 1875, T = 700 °C
57 GPa ft = 7465.0 Hz ASTM E 1875, T = 750 °C
55 GPa ft = 7333.0 Hz ASTM E 1875, T = 800 °C
Zug-Elastizitätsmodul 235 GPa mean ASTM E 1875, T = 24 °C
235 GPa flat-wise in the thickness direction, ff(f) = 1644.0 Hz ASTM E 1875, T = 24 °C
236 GPa edge-wise in the width direction, ff(e) = 4797.0 Hz ASTM E 1875, T = 24 °C
230 GPa mean ASTM E 1875, T = 100 °C
230 GPa flat-wise in the thickness direction, ff(f) = 1626.0 Hz ASTM E 1875, T = 100 °C
231 GPa edge-wise in the width direction, ff(e) = 4746.0 Hz ASTM E 1875, T = 100 °C
223 GPa mean ASTM E 1875, T = 200 °C
222 GPa flat-wise in the thickness direction, ff(f) = 1601.0 Hz ASTM E 1875, T = 200 °C
223 GPa edge-wise in the width direction, ff(e) = 4672.0 Hz ASTM E 1875, T = 200 °C
216 GPa mean ASTM E 1875, T = 300 °C
216 GPa flat-wise in the thickness direction, ff(f) = 1578.0 Hz ASTM E 1875, T = 300 °C
217 GPa edge-wise in the width direction, ff(e) = 4606.0 Hz ASTM E 1875, T = 300 °C
210 GPa mean ASTM E 1875, T = 400 °C
210 GPa flat-wise in the thickness direction, ff(f) = 1556.0 Hz ASTM E 1875, T = 400 °C
210 GPa edge-wise in the width direction, ff(e) = 4540.0 Hz ASTM E 1875, T = 400 °C
204 GPa mean ASTM E 1875, T = 500 °C
203 GPa flat-wise in the thickness direction, ff(f) = 1533.0 Hz ASTM E 1875, T = 500 °C
204 GPa edge-wise in the width direction, ff(e) = 4472.0 Hz ASTM E 1875, T = 500 °C
196 GPa mean ASTM E 1875, T = 600 °C
195 GPa flat-wise in the thickness direction, ff(f) = 1504.0 Hz ASTM E 1875, T = 600 °C
196 GPa edge-wise in the width direction, ff(e) = 4388.0 Hz ASTM E 1875, T = 600 °C
192 GPa mean ASTM E 1875, T = 650 °C
191 GPa flat-wise in the thickness direction, ff(f) = 1489.0 Hz ASTM E 1875, T = 650 °C
192 GPa edge-wise in the width direction, ff(e) = 4342.0 Hz ASTM E 1875, T = 650 °C
187 GPa mean ASTM E 1875, T = 700 °C
187 GPa flat-wise in the thickness direction, ff(f) = 1471.0 Hz ASTM E 1875, T = 700 °C
187 GPa edge-wise in the width direction, ff(e) = 4290.0 Hz ASTM E 1875, T = 700 °C
182 GPa mean ASTM E 1875, T = 750 °C
181 GPa flat-wise in the thickness direction, ff(f) = 1450.0 Hz ASTM E 1875, T = 750 °C
182 GPa edge-wise in the width direction, ff(e) = 4230.0 Hz ASTM E 1875, T = 750 °C
176 GPa mean ASTM E 1875, T = 800 °C
176 GPa flat-wise in the thickness direction, ff(f) = 1427.0 Hz ASTM E 1875, T = 800 °C
177 GPa edge-wise in the width direction, ff(e) = 4165.0 Hz ASTM E 1875, T = 800 °C
Thermische Eigenschaften
 
linearer Längenausdehnungskoeffizient 11.9 10⁻⁶/K T = 100 °C
11.9 10⁻⁶/K T = 200 °C
11.9 10⁻⁶/K T = 300 °C
11.9 10⁻⁶/K T = 400 °C
11.9 10⁻⁶/K T = 500 °C
11.9 10⁻⁶/K T = 600 °C
11.9 10⁻⁶/K T = 650 °C
11.9 10⁻⁶/K T = 700 °C
11.9 10⁻⁶/K T = 750 °C
11.9 10⁻⁶/K T = 800 °C

Chemische Eigenschaften

chemische Zusammensetzung, elementar (Gewichtsprozent)
Ni

54.3 

Cr

17.82 

Fe

18.36 

Nb

4.38 

Mo

3.46 

Ti

0.92 

Al

0.48 

Co

0.07 

Mn

0.09 

Si

0.05 

Cu

0.03 

Abbildungen und Diagramme

Tensile Modulus of Elasticity at different Temperatures
Tensile Modulus of Elasticity at different Temperatures
Change of Dimensions at different Temperatures compared to 24 °C
Change of Dimensions at different Temperatures compared to 24 °C
Density at different Temperatures
Density at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Shear Modulus at different Temperatures
Shear Modulus at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
weitere Angaben
  • T = temperature
  • m = mass
  • ff(e) = fundamental resonance frequency of the bar in flexure (edge wise)
  • ff(f) = fundamental resonance frequency of the bar in flexure (flat wise)
  • ft = fundamental resonance frequency of the bar in torsion
zugehörige wissenschaftliche Publikation

Beteiligte

Daten bereitgestellt von

SLUB Dresden

Team Material Hub
Anfrage per E-Mail

Webseite | Mehr Details

Ansprechpartner für diese Materialdaten

Material Hub-Team
Anfrage per E-Mail

Haftungsausschluss

Die BAM Referenzdaten wurden von der Bundesanstalt für Materialforschung und -prüfung (BAM) unter der Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode) auf Zenodo bereitgestellt.Die SLUB hat die bereitgestellten Inhalte einer Normalisierung unterzogen, die notwendig ist, um eine umfassende Recherche und die Vergleichbarkeit der Materialien zu ermöglichen. Trotz größter zumutbarer Sorgfalt können bei diesem Normalisierungsprozess Fehler auftreten, weshalb ausdrücklich darauf hingewiesen wird, dass auf Grundlage der im Material Hub vorhandenen Daten keine Entscheidungen zur Verwendung oder Anschaffung eines Materials getroffen werden dürfen. Vielmehr ist es notwendig den Datenerzeuger im Vorfeld einer solchen Entscheidung direkt zu kontaktieren, um die Korrektheit der Daten zu verifizieren.

INCONEL alloy 718, additively manufactured, PBF-LB (IN_A_V_1)

The elastic properties (Young's modulus, shear modulus) of Ni-based alloy Inconel IN718 were investigated between room temperature and 800 °C in an additively manufactured variant (laser powder bed fusion, PBF‑LB/M) and from a conventional process route (hot rolled bar). The moduli were determined using the dynamic resonance method. The data set includes information on processing parameters, heat treatments, grain size, specimen dimensions and weight, Young’s and shear modulus as well as their measurement uncertainty.

The dataset was generated in an accredited testing lab using calibrated measuring equipment. The calibrations meet the requirements of the test procedure and are metrologically traceable. The dataset was audited as BAM reference data. The dataset was made available under the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode).

Further information on data and data acquisition, analysis, and experimental details are given in “Elastic modulus data for additively and conventionally manufactured variants of Ti‑6Al‑4V, IN718 and AISI 316L” published in Scientific Data.

Schlagwörter
BAM reference data
Young's modulus
Shear modulus
Zenodo
Data set
Art der Datenquelle Forschungsergebnis
Anwendungsgebiete aerospace; energy; medical; automotive; high temperature application
Bauform blank type: tower; Inclination of specimen (L-direction) relative to building direction = 0°; layer thickness = 60 µm; m = 22.251 g
Versuchsaufbau
  • Measurement of Young´s modulus and shear modulus: Elastotron 2000 (HTM Reetz, Berlin, Germany)

Herstellungsverfahren und Ausgangsmaterialien

Name additively manufactured, PBF-LB
Beschreibung machine: SLM Solutions 280HL (SLM Solutions Group AG, Germany); heat treatment: 1065°C/1.5h + air cooling to 50°C, 965°C/1h + forced air cooling to 50°C, 720°C/8h + controlled cooling to 620°C/8h + air cooling
Ausgangsmaterial

Physikalische Eigenschaften

Name Wert Bemerkung Messverfahren und -bedingungen
(mittlere) Korngröße 0.064 mm EBSD, section parallel to building direction
Abmessung (Länge) 100 mm T = 24 °C
Abmessung (Länge) 100.09 mm T = 100 °C
Abmessung (Länge) 100.21 mm T = 200 °C
Abmessung (Länge) 100.33 mm T = 300 °C
Abmessung (Länge) 100.45 mm T = 400 °C
Abmessung (Länge) 100.57 mm T = 500 °C
Abmessung (Länge) 100.69 mm T = 600 °C
Abmessung (Länge) 100.74 mm T = 650 °C
Abmessung (Länge) 100.8 mm T = 700 °C
Abmessung (Länge) 100.86 mm T = 750 °C
Abmessung (Länge) 100.92 mm T = 800 °C
Abmessung (Breite) 9.003 mm T = 24 °C
Abmessung (Breite) 9.011 mm T = 100 °C
Abmessung (Breite) 9.022 mm T = 200 °C
Abmessung (Breite) 9.033 mm T = 300 °C
Abmessung (Breite) 9.043 mm T = 400 °C
Abmessung (Breite) 9.054 mm T = 500 °C
Abmessung (Breite) 9.065 mm T = 600 °C
Abmessung (Breite) 9.07 mm T = 650 °C
Abmessung (Breite) 9.075 mm T = 700 °C
Abmessung (Breite) 9.081 mm T = 750 °C
Abmessung (Breite) 9.086 mm T = 800 °C
Abmessung (Tiefe) 2.999 mm T = 24 °C
Abmessung (Tiefe) 3.002 mm T = 100 °C
Abmessung (Tiefe) 3.005 mm T = 200 °C
Abmessung (Tiefe) 3.009 mm T = 300 °C
Abmessung (Tiefe) 3.012 mm T = 400 °C
Abmessung (Tiefe) 3.016 mm T = 500 °C
Abmessung (Tiefe) 3.02 mm T = 600 °C
Abmessung (Tiefe) 3.021 mm T = 650 °C
Abmessung (Tiefe) 3.023 mm T = 700 °C
Abmessung (Tiefe) 3.025 mm T = 750 °C
Abmessung (Tiefe) 3.027 mm T = 800 °C
Dichte 8.241 g/cm³ T = 24 °C
8.219 g/cm³ T = 100 °C
8.19 g/cm³ T = 200 °C
8.16 g/cm³ T = 300 °C
8.131 g/cm³ T = 400 °C
8.103 g/cm³ T = 500 °C
8.074 g/cm³ T = 600 °C
8.06 g/cm³ T = 650 °C
8.045 g/cm³ T = 700 °C
8.031 g/cm³ T = 750 °C
8.017 g/cm³ T = 800 °C
Mechanische Eigenschaften
 
Schubmodul 81 GPa ft = 8833.0 Hz ASTM E 1875, T = 24 °C
79 GPa ft = 8724.0 Hz ASTM E 1875, T = 100 °C
76 GPa ft = 8582.0 Hz ASTM E 1875, T = 200 °C
74 GPa ft = 8436.0 Hz ASTM E 1875, T = 300 °C
71 GPa ft = 8296.0 Hz ASTM E 1875, T = 400 °C
69 GPa ft = 8155.0 Hz ASTM E 1875, T = 500 °C
66 GPa ft = 7979.0 Hz ASTM E 1875, T = 600 °C
64 GPa ft = 7881.0 Hz ASTM E 1875, T = 650 °C
62 GPa ft = 7770.0 Hz ASTM E 1875, T = 700 °C
60 GPa ft = 7648.0 Hz ASTM E 1875, T = 750 °C
58 GPa ft = 7514.0 Hz ASTM E 1875, T = 800 °C
Zug-Elastizitätsmodul 194 GPa mean ASTM E 1875, T = 24 °C
194 GPa flat-wise in the thickness direction, ff(f) = 1491.0 Hz ASTM E 1875, T = 24 °C
194 GPa edge-wise in the width direction, ff(e) = 4371.0 Hz ASTM E 1875, T = 24 °C
189 GPa mean ASTM E 1875, T = 100 °C
189 GPa flat-wise in the thickness direction, ff(f) = 1474.0 Hz ASTM E 1875, T = 100 °C
189 GPa edge-wise in the width direction, ff(e) = 4321.0 Hz ASTM E 1875, T = 100 °C
183 GPa mean ASTM E 1875, T = 200 °C
183 GPa flat-wise in the thickness direction, ff(f) = 1451.0 Hz ASTM E 1875, T = 200 °C
183 GPa edge-wise in the width direction, ff(e) = 4253.0 Hz ASTM E 1875, T = 200 °C
177 GPa mean ASTM E 1875, T = 300 °C
177 GPa flat-wise in the thickness direction, ff(f) = 1429.0 Hz ASTM E 1875, T = 300 °C
177 GPa edge-wise in the width direction, ff(e) = 4183.0 Hz ASTM E 1875, T = 300 °C
172 GPa mean ASTM E 1875, T = 400 °C
172 GPa flat-wise in the thickness direction, ff(f) = 1407.0 Hz ASTM E 1875, T = 400 °C
171 GPa edge-wise in the width direction, ff(e) = 4117.0 Hz ASTM E 1875, T = 400 °C
166 GPa mean ASTM E 1875, T = 500 °C
166 GPa flat-wise in the thickness direction, ff(f) = 1383.0 Hz ASTM E 1875, T = 500 °C
166 GPa edge-wise in the width direction, ff(e) = 4051.0 Hz ASTM E 1875, T = 500 °C
159 GPa mean ASTM E 1875, T = 600 °C
159 GPa flat-wise in the thickness direction, ff(f) = 1353.0 Hz ASTM E 1875, T = 600 °C
159 GPa edge-wise in the width direction, ff(e) = 3966.0 Hz ASTM E 1875, T = 600 °C
155 GPa mean ASTM E 1875, T = 650 °C
155 GPa flat-wise in the thickness direction, ff(f) = 1338.0 Hz ASTM E 1875, T = 650 °C
155 GPa edge-wise in the width direction, ff(e) = 3921.0 Hz ASTM E 1875, T = 650 °C
151 GPa mean ASTM E 1875, T = 700 °C
151 GPa flat-wise in the thickness direction, ff(f) = 1320.0 Hz ASTM E 1875, T = 700 °C
151 GPa edge-wise in the width direction, ff(e) = 3867.0 Hz ASTM E 1875, T = 700 °C
146 GPa mean ASTM E 1875, T = 750 °C
146 GPa flat-wise in the thickness direction, ff(f) = 1300.0 Hz ASTM E 1875, T = 750 °C
146 GPa edge-wise in the width direction, ff(e) = 3807.0 Hz ASTM E 1875, T = 750 °C
142 GPa mean ASTM E 1875, T = 800 °C
143 GPa flat-wise in the thickness direction, ff(f) = 1288.0 Hz ASTM E 1875, T = 800 °C
141 GPa edge-wise in the width direction, ff(e) = 3747.0 Hz ASTM E 1875, T = 800 °C
Thermische Eigenschaften
 
linearer Längenausdehnungskoeffizient 11.9 10⁻⁶/K T = 100 °C
11.9 10⁻⁶/K T = 200 °C
11.9 10⁻⁶/K T = 300 °C
11.9 10⁻⁶/K T = 400 °C
11.9 10⁻⁶/K T = 500 °C
11.9 10⁻⁶/K T = 600 °C
11.9 10⁻⁶/K T = 650 °C
11.9 10⁻⁶/K T = 700 °C
11.9 10⁻⁶/K T = 750 °C
11.9 10⁻⁶/K T = 800 °C

Chemische Eigenschaften

chemische Zusammensetzung, elementar (Gewichtsprozent)
Ni

54.3 

Cr

17.82 

Fe

18.36 

Nb

4.38 

Mo

3.46 

Ti

0.92 

Al

0.48 

Co

0.07 

Mn

0.09 

Si

0.05 

Cu

0.03 

Abbildungen und Diagramme

Tensile Modulus of Elasticity at different Temperatures
Tensile Modulus of Elasticity at different Temperatures
Change of Dimensions at different Temperatures compared to 24 °C
Change of Dimensions at different Temperatures compared to 24 °C
Density at different Temperatures
Density at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Shear Modulus at different Temperatures
Shear Modulus at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
weitere Angaben
  • T = temperature
  • m = mass
  • ff(e) = fundamental resonance frequency of the bar in flexure (edge wise)
  • ff(f) = fundamental resonance frequency of the bar in flexure (flat wise)
  • ft = fundamental resonance frequency of the bar in torsion
zugehörige wissenschaftliche Publikation

Beteiligte

Daten bereitgestellt von

SLUB Dresden

Team Material Hub
Anfrage per E-Mail

Webseite | Mehr Details

Ansprechpartner für diese Materialdaten

Material Hub-Team
Anfrage per E-Mail

Haftungsausschluss

Die BAM Referenzdaten wurden von der Bundesanstalt für Materialforschung und -prüfung (BAM) unter der Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode) auf Zenodo bereitgestellt.Die SLUB hat die bereitgestellten Inhalte einer Normalisierung unterzogen, die notwendig ist, um eine umfassende Recherche und die Vergleichbarkeit der Materialien zu ermöglichen. Trotz größter zumutbarer Sorgfalt können bei diesem Normalisierungsprozess Fehler auftreten, weshalb ausdrücklich darauf hingewiesen wird, dass auf Grundlage der im Material Hub vorhandenen Daten keine Entscheidungen zur Verwendung oder Anschaffung eines Materials getroffen werden dürfen. Vielmehr ist es notwendig den Datenerzeuger im Vorfeld einer solchen Entscheidung direkt zu kontaktieren, um die Korrektheit der Daten zu verifizieren.

INCONEL alloy 718, additively manufactured, PBF-LB (IN_A_V_2)

The elastic properties (Young's modulus, shear modulus) of Ni-based alloy Inconel IN718 were investigated between room temperature and 800 °C in an additively manufactured variant (laser powder bed fusion, PBF‑LB/M) and from a conventional process route (hot rolled bar). The moduli were determined using the dynamic resonance method. The data set includes information on processing parameters, heat treatments, grain size, specimen dimensions and weight, Young’s and shear modulus as well as their measurement uncertainty.

The dataset was generated in an accredited testing lab using calibrated measuring equipment. The calibrations meet the requirements of the test procedure and are metrologically traceable. The dataset was audited as BAM reference data. The dataset was made available under the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode).

Further information on data and data acquisition, analysis, and experimental details are given in “Elastic modulus data for additively and conventionally manufactured variants of Ti‑6Al‑4V, IN718 and AISI 316L” published in Scientific Data.

Schlagwörter
BAM reference data
Young's modulus
Shear modulus
Zenodo
Data set
Art der Datenquelle Forschungsergebnis
Anwendungsgebiete aerospace; energy; medical; automotive; high temperature application
Bauform blank type: tower; Inclination of specimen (L-direction) relative to building direction = 0°; layer thickness = 60 µm; m = 22.236 g
Versuchsaufbau
  • Measurement of Young´s modulus and shear modulus: Elastotron 2000 (HTM Reetz, Berlin, Germany)

Herstellungsverfahren und Ausgangsmaterialien

Name additively manufactured, PBF-LB
Beschreibung machine: SLM Solutions 280HL (SLM Solutions Group AG, Germany); heat treatment: 1065°C/1.5h + air cooling to 50°C, 965°C/1h + forced air cooling to 50°C, 720°C/8h + controlled cooling to 620°C/8h + air cooling
Ausgangsmaterial

Physikalische Eigenschaften

Name Wert Bemerkung Messverfahren und -bedingungen
(mittlere) Korngröße 0.064 mm EBSD, section parallel to building direction
Abmessung (Länge) 100.01 mm T = 24 °C
Abmessung (Länge) 100.1 mm T = 100 °C
Abmessung (Länge) 100.22 mm T = 200 °C
Abmessung (Länge) 100.34 mm T = 300 °C
Abmessung (Länge) 100.46 mm T = 400 °C
Abmessung (Länge) 100.58 mm T = 500 °C
Abmessung (Länge) 100.7 mm T = 600 °C
Abmessung (Länge) 100.76 mm T = 650 °C
Abmessung (Länge) 100.81 mm T = 700 °C
Abmessung (Länge) 100.87 mm T = 750 °C
Abmessung (Länge) 100.93 mm T = 800 °C
Abmessung (Breite) 9.002 mm T = 24 °C
Abmessung (Breite) 9.01 mm T = 100 °C
Abmessung (Breite) 9.021 mm T = 200 °C
Abmessung (Breite) 9.032 mm T = 300 °C
Abmessung (Breite) 9.042 mm T = 400 °C
Abmessung (Breite) 9.053 mm T = 500 °C
Abmessung (Breite) 9.064 mm T = 600 °C
Abmessung (Breite) 9.069 mm T = 650 °C
Abmessung (Breite) 9.074 mm T = 700 °C
Abmessung (Breite) 9.08 mm T = 750 °C
Abmessung (Breite) 9.085 mm T = 800 °C
Abmessung (Tiefe) 3 mm T = 24 °C
Abmessung (Tiefe) 3.003 mm T = 100 °C
Abmessung (Tiefe) 3.006 mm T = 200 °C
Abmessung (Tiefe) 3.01 mm T = 300 °C
Abmessung (Tiefe) 3.013 mm T = 400 °C
Abmessung (Tiefe) 3.017 mm T = 500 °C
Abmessung (Tiefe) 3.021 mm T = 600 °C
Abmessung (Tiefe) 3.022 mm T = 650 °C
Abmessung (Tiefe) 3.024 mm T = 700 °C
Abmessung (Tiefe) 3.026 mm T = 750 °C
Abmessung (Tiefe) 3.028 mm T = 800 °C
Dichte 8.233 g/cm³ T = 24 °C
8.211 g/cm³ T = 100 °C
8.181 g/cm³ T = 200 °C
8.152 g/cm³ T = 300 °C
8.123 g/cm³ T = 400 °C
8.095 g/cm³ T = 500 °C
8.066 g/cm³ T = 600 °C
8.052 g/cm³ T = 650 °C
8.037 g/cm³ T = 700 °C
8.023 g/cm³ T = 750 °C
8.009 g/cm³ T = 800 °C
Mechanische Eigenschaften
 
Schubmodul 82 GPa ft = 8893.0 Hz ASTM E 1875, T = 24 °C
80 GPa ft = 8766.0 Hz ASTM E 1875, T = 100 °C
77 GPa ft = 8619.0 Hz ASTM E 1875, T = 200 °C
74 GPa ft = 8482.0 Hz ASTM E 1875, T = 300 °C
72 GPa ft = 8336.0 Hz ASTM E 1875, T = 400 °C
69 GPa ft = 8199.0 Hz ASTM E 1875, T = 500 °C
66 GPa ft = 8020.0 Hz ASTM E 1875, T = 600 °C
65 GPa ft = 7925.0 Hz ASTM E 1875, T = 650 °C
63 GPa ft = 7807.0 Hz ASTM E 1875, T = 700 °C
61 GPa ft = 7686.0 Hz ASTM E 1875, T = 750 °C
58 GPa ft = 7543.0 Hz ASTM E 1875, T = 800 °C
Zug-Elastizitätsmodul 194 GPa mean ASTM E 1875, T = 24 °C
193 GPa flat-wise in the thickness direction, ff(f) = 1490.0 Hz ASTM E 1875, T = 24 °C
194 GPa edge-wise in the width direction, ff(e) = 4369.0 Hz ASTM E 1875, T = 24 °C
188 GPa mean ASTM E 1875, T = 100 °C
188 GPa flat-wise in the thickness direction, ff(f) = 1471.0 Hz ASTM E 1875, T = 100 °C
188 GPa edge-wise in the width direction, ff(e) = 4311.0 Hz ASTM E 1875, T = 100 °C
183 GPa mean ASTM E 1875, T = 200 °C
183 GPa flat-wise in the thickness direction, ff(f) = 1450.0 Hz ASTM E 1875, T = 200 °C
183 GPa edge-wise in the width direction, ff(e) = 4246.0 Hz ASTM E 1875, T = 200 °C
176 GPa mean ASTM E 1875, T = 300 °C
176 GPa flat-wise in the thickness direction, ff(f) = 1425.0 Hz ASTM E 1875, T = 300 °C
176 GPa edge-wise in the width direction, ff(e) = 4175.0 Hz ASTM E 1875, T = 300 °C
171 GPa mean ASTM E 1875, T = 400 °C
170 GPa flat-wise in the thickness direction, ff(f) = 1402.0 Hz ASTM E 1875, T = 400 °C
171 GPa edge-wise in the width direction, ff(e) = 4110.0 Hz ASTM E 1875, T = 400 °C
165 GPa mean ASTM E 1875, T = 500 °C
165 GPa flat-wise in the thickness direction, ff(f) = 1379.0 Hz ASTM E 1875, T = 500 °C
165 GPa edge-wise in the width direction, ff(e) = 4043.0 Hz ASTM E 1875, T = 500 °C
158 GPa mean ASTM E 1875, T = 600 °C
158 GPa flat-wise in the thickness direction, ff(f) = 1351.0 Hz ASTM E 1875, T = 600 °C
158 GPa edge-wise in the width direction, ff(e) = 3960.0 Hz ASTM E 1875, T = 600 °C
154 GPa mean ASTM E 1875, T = 650 °C
154 GPa flat-wise in the thickness direction, ff(f) = 1335.0 Hz ASTM E 1875, T = 650 °C
154 GPa edge-wise in the width direction, ff(e) = 3914.0 Hz ASTM E 1875, T = 650 °C
150 GPa mean ASTM E 1875, T = 700 °C
150 GPa flat-wise in the thickness direction, ff(f) = 1316.0 Hz ASTM E 1875, T = 700 °C
150 GPa edge-wise in the width direction, ff(e) = 3859.0 Hz ASTM E 1875, T = 700 °C
145 GPa mean ASTM E 1875, T = 750 °C
145 GPa flat-wise in the thickness direction, ff(f) = 1294.0 Hz ASTM E 1875, T = 750 °C
145 GPa edge-wise in the width direction, ff(e) = 3797.0 Hz ASTM E 1875, T = 750 °C
140 GPa mean ASTM E 1875, T = 800 °C
139 GPa flat-wise in the thickness direction, ff(f) = 1271.0 Hz ASTM E 1875, T = 800 °C
140 GPa edge-wise in the width direction, ff(e) = 3728.0 Hz ASTM E 1875, T = 800 °C
Thermische Eigenschaften
 
linearer Längenausdehnungskoeffizient 11.9 10⁻⁶/K T = 100 °C
11.9 10⁻⁶/K T = 200 °C
11.9 10⁻⁶/K T = 300 °C
11.9 10⁻⁶/K T = 400 °C
11.9 10⁻⁶/K T = 500 °C
11.9 10⁻⁶/K T = 600 °C
11.9 10⁻⁶/K T = 650 °C
11.9 10⁻⁶/K T = 700 °C
11.9 10⁻⁶/K T = 750 °C
11.9 10⁻⁶/K T = 800 °C

Chemische Eigenschaften

chemische Zusammensetzung, elementar (Gewichtsprozent)
Ni

54.3 

Cr

17.82 

Fe

18.36 

Nb

4.38 

Mo

3.46 

Ti

0.92 

Al

0.48 

Co

0.07 

Mn

0.09 

Si

0.05 

Cu

0.03 

Abbildungen und Diagramme

Tensile Modulus of Elasticity at different Temperatures
Tensile Modulus of Elasticity at different Temperatures
Change of Dimensions at different Temperatures compared to 24 °C
Change of Dimensions at different Temperatures compared to 24 °C
Density at different Temperatures
Density at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Shear Modulus at different Temperatures
Shear Modulus at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
weitere Angaben
  • T = temperature
  • m = mass
  • ff(e) = fundamental resonance frequency of the bar in flexure (edge wise)
  • ff(f) = fundamental resonance frequency of the bar in flexure (flat wise)
  • ft = fundamental resonance frequency of the bar in torsion
zugehörige wissenschaftliche Publikation

Beteiligte

Daten bereitgestellt von

SLUB Dresden

Team Material Hub
Anfrage per E-Mail

Webseite | Mehr Details

Ansprechpartner für diese Materialdaten

Material Hub-Team
Anfrage per E-Mail

Haftungsausschluss

Die BAM Referenzdaten wurden von der Bundesanstalt für Materialforschung und -prüfung (BAM) unter der Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode) auf Zenodo bereitgestellt.Die SLUB hat die bereitgestellten Inhalte einer Normalisierung unterzogen, die notwendig ist, um eine umfassende Recherche und die Vergleichbarkeit der Materialien zu ermöglichen. Trotz größter zumutbarer Sorgfalt können bei diesem Normalisierungsprozess Fehler auftreten, weshalb ausdrücklich darauf hingewiesen wird, dass auf Grundlage der im Material Hub vorhandenen Daten keine Entscheidungen zur Verwendung oder Anschaffung eines Materials getroffen werden dürfen. Vielmehr ist es notwendig den Datenerzeuger im Vorfeld einer solchen Entscheidung direkt zu kontaktieren, um die Korrektheit der Daten zu verifizieren.

INCONEL alloy 718, conventionally hot-rolled (IN_C_1)

The elastic properties (Young's modulus, shear modulus) of Ni-based alloy Inconel IN718 were investigated between room temperature and 800 °C in an additively manufactured variant (laser powder bed fusion, PBF‑LB/M) and from a conventional process route (hot rolled bar). The moduli were determined using the dynamic resonance method. The data set includes information on processing parameters, heat treatments, grain size, specimen dimensions and weight, Young’s and shear modulus as well as their measurement uncertainty.

The dataset was generated in an accredited testing lab using calibrated measuring equipment. The calibrations meet the requirements of the test procedure and are metrologically traceable. The dataset was audited as BAM reference data. The dataset was made available under the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode).

Further information on data and data acquisition, analysis, and experimental details are given in “Elastic modulus data for additively and conventionally manufactured variants of Ti‑6Al‑4V, IN718 and AISI 316L” published in Scientific Data.

Schlagwörter
BAM reference data
Young's modulus
Shear modulus
Zenodo
Data set
Art der Datenquelle Forschungsergebnis
Anwendungsgebiete aerospace; energy; medical; automotive; high temperature application
Bauform blank type: bar; Inclination of specimen (L-direction) relative to rolling direction = 0°; m = 22.247 g
Versuchsaufbau
  • Measurement of Young´s modulus and shear modulus: Elastotron 2000 (HTM Reetz, Berlin, Germany)

Herstellungsverfahren und Ausgangsmaterialien

Name conventionally hot-rolled
Beschreibung heat treatment: 965°C/1h + air cooling to 20°C, 718°C/8h + controlled cooling to 621°C/8h + air cooling
Ausgangsmaterial

Physikalische Eigenschaften

Name Wert Bemerkung Messverfahren und -bedingungen
(mittlere) Korngröße 0.006 mm EBSD
Abmessung (Länge) 100.07 mm T = 24 °C
Abmessung (Länge) 100.18 mm T = 100 °C
Abmessung (Länge) 100.32 mm T = 200 °C
Abmessung (Länge) 100.46 mm T = 300 °C
Abmessung (Länge) 100.61 mm T = 400 °C
Abmessung (Länge) 100.77 mm T = 500 °C
Abmessung (Länge) 100.95 mm T = 600 °C
Abmessung (Länge) 101.06 mm T = 650 °C
Abmessung (Länge) 101.18 mm T = 700 °C
Abmessung (Länge) 101.28 mm T = 750 °C
Abmessung (Länge) 101.39 mm T = 800 °C
Abmessung (Breite) 8.999 mm T = 24 °C
Abmessung (Breite) 9.009 mm T = 100 °C
Abmessung (Breite) 9.021 mm T = 200 °C
Abmessung (Breite) 9.034 mm T = 300 °C
Abmessung (Breite) 9.048 mm T = 400 °C
Abmessung (Breite) 9.062 mm T = 500 °C
Abmessung (Breite) 9.078 mm T = 600 °C
Abmessung (Breite) 9.088 mm T = 650 °C
Abmessung (Breite) 9.099 mm T = 700 °C
Abmessung (Breite) 9.108 mm T = 750 °C
Abmessung (Breite) 9.118 mm T = 800 °C
Abmessung (Tiefe) 2.993 mm T = 24 °C
Abmessung (Tiefe) 2.996 mm T = 100 °C
Abmessung (Tiefe) 3 mm T = 200 °C
Abmessung (Tiefe) 3.005 mm T = 300 °C
Abmessung (Tiefe) 3.009 mm T = 400 °C
Abmessung (Tiefe) 3.014 mm T = 500 °C
Abmessung (Tiefe) 3.019 mm T = 600 °C
Abmessung (Tiefe) 3.023 mm T = 650 °C
Abmessung (Tiefe) 3.026 mm T = 700 °C
Abmessung (Tiefe) 3.029 mm T = 750 °C
Abmessung (Tiefe) 3.032 mm T = 800 °C
Dichte 8.254 g/cm³ T = 24 °C
8.228 g/cm³ T = 100 °C
8.193 g/cm³ T = 200 °C
8.158 g/cm³ T = 300 °C
8.121 g/cm³ T = 400 °C
8.082 g/cm³ T = 500 °C
8.04 g/cm³ T = 600 °C
8.013 g/cm³ T = 650 °C
7.985 g/cm³ T = 700 °C
7.961 g/cm³ T = 750 °C
7.936 g/cm³ T = 800 °C
Mechanische Eigenschaften
 
Schubmodul 78 GPa ft = 8673.0 Hz ASTM E 1875, T = 24 °C
76 GPa ft = 8564.0 Hz ASTM E 1875, T = 100 °C
74 GPa ft = 8418.0 Hz ASTM E 1875, T = 200 °C
71 GPa ft = 8278.0 Hz ASTM E 1875, T = 300 °C
69 GPa ft = 8131.0 Hz ASTM E 1875, T = 400 °C
66 GPa ft = 7982.0 Hz ASTM E 1875, T = 500 °C
63 GPa ft = 7795.0 Hz ASTM E 1875, T = 600 °C
61 GPa ft = 7685.0 Hz ASTM E 1875, T = 650 °C
59 GPa ft = 7561.0 Hz ASTM E 1875, T = 700 °C
57 GPa ft = 7428.0 Hz ASTM E 1875, T = 750 °C
54 GPa ft = 7265.0 Hz ASTM E 1875, T = 800 °C
Zug-Elastizitätsmodul 206 GPa mean ASTM E 1875, T = 24 °C
206 GPa flat-wise in the thickness direction, ff(f) = 1530.0 Hz ASTM E 1875, T = 24 °C
207 GPa edge-wise in the width direction, ff(e) = 4493.0 Hz ASTM E 1875, T = 24 °C
201 GPa mean ASTM E 1875, T = 100 °C
201 GPa flat-wise in the thickness direction, ff(f) = 1513.0 Hz ASTM E 1875, T = 100 °C
202 GPa edge-wise in the width direction, ff(e) = 4442.0 Hz ASTM E 1875, T = 100 °C
195 GPa mean ASTM E 1875, T = 200 °C
195 GPa flat-wise in the thickness direction, ff(f) = 1490.0 Hz ASTM E 1875, T = 200 °C
195 GPa edge-wise in the width direction, ff(e) = 4373.0 Hz ASTM E 1875, T = 200 °C
189 GPa mean ASTM E 1875, T = 300 °C
189 GPa flat-wise in the thickness direction, ff(f) = 1468.0 Hz ASTM E 1875, T = 300 °C
189 GPa edge-wise in the width direction, ff(e) = 4307.0 Hz ASTM E 1875, T = 300 °C
183 GPa mean ASTM E 1875, T = 400 °C
182 GPa flat-wise in the thickness direction, ff(f) = 1444.0 Hz ASTM E 1875, T = 400 °C
183 GPa edge-wise in the width direction, ff(e) = 4238.0 Hz ASTM E 1875, T = 400 °C
176 GPa mean ASTM E 1875, T = 500 °C
176 GPa flat-wise in the thickness direction, ff(f) = 1418.0 Hz ASTM E 1875, T = 500 °C
176 GPa edge-wise in the width direction, ff(e) = 4161.0 Hz ASTM E 1875, T = 500 °C
168 GPa mean ASTM E 1875, T = 600 °C
168 GPa flat-wise in the thickness direction, ff(f) = 1388.0 Hz ASTM E 1875, T = 600 °C
168 GPa edge-wise in the width direction, ff(e) = 4070.0 Hz ASTM E 1875, T = 600 °C
164 GPa mean ASTM E 1875, T = 650 °C
164 GPa flat-wise in the thickness direction, ff(f) = 1371.0 Hz ASTM E 1875, T = 650 °C
164 GPa edge-wise in the width direction, ff(e) = 4018.0 Hz ASTM E 1875, T = 650 °C
159 GPa mean ASTM E 1875, T = 700 °C
158 GPa flat-wise in the thickness direction, ff(f) = 1350.0 Hz ASTM E 1875, T = 700 °C
159 GPa edge-wise in the width direction, ff(e) = 3957.0 Hz ASTM E 1875, T = 700 °C
153 GPa mean ASTM E 1875, T = 750 °C
153 GPa flat-wise in the thickness direction, ff(f) = 1328.0 Hz ASTM E 1875, T = 750 °C
153 GPa edge-wise in the width direction, ff(e) = 3891.0 Hz ASTM E 1875, T = 750 °C
147 GPa mean ASTM E 1875, T = 800 °C
146 GPa flat-wise in the thickness direction, ff(f) = 1299.0 Hz ASTM E 1875, T = 800 °C
147 GPa edge-wise in the width direction, ff(e) = 3818.0 Hz ASTM E 1875, T = 800 °C
Thermische Eigenschaften
 
linearer Längenausdehnungskoeffizient 14.1 10⁻⁶/K T = 100 °C
14.1 10⁻⁶/K T = 200 °C
14.2 10⁻⁶/K T = 300 °C
14.4 10⁻⁶/K T = 400 °C
14.8 10⁻⁶/K T = 500 °C
15.3 10⁻⁶/K T = 600 °C
15.85 10⁻⁶/K T = 650 °C
16.4 10⁻⁶/K T = 700 °C
16.7 10⁻⁶/K T = 750 °C
17 10⁻⁶/K T = 800 °C

Chemische Eigenschaften

chemische Zusammensetzung, elementar (Gewichtsprozent)
Ni

53.7 

Cr

17.82 

Fe

18.26 

Nb

5.21 

Mo

3.02 

Ti

0.93 

Al

0.53 

Co

0.16 

Mn

0.14 

Si

0.08 

Cu

0.04 

Abbildungen und Diagramme

Tensile Modulus of Elasticity at different Temperatures
Tensile Modulus of Elasticity at different Temperatures
Change of Dimensions at different Temperatures compared to 24 °C
Change of Dimensions at different Temperatures compared to 24 °C
Density at different Temperatures
Density at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Shear Modulus at different Temperatures
Shear Modulus at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
weitere Angaben
  • T = temperature
  • m = mass
  • ff(e) = fundamental resonance frequency of the bar in flexure (edge wise)
  • ff(f) = fundamental resonance frequency of the bar in flexure (flat wise)
  • ft = fundamental resonance frequency of the bar in torsion
zugehörige wissenschaftliche Publikation

Beteiligte

Daten bereitgestellt von

SLUB Dresden

Team Material Hub
Anfrage per E-Mail

Webseite | Mehr Details

Ansprechpartner für diese Materialdaten

Material Hub-Team
Anfrage per E-Mail

Haftungsausschluss

Die BAM Referenzdaten wurden von der Bundesanstalt für Materialforschung und -prüfung (BAM) unter der Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode) auf Zenodo bereitgestellt.Die SLUB hat die bereitgestellten Inhalte einer Normalisierung unterzogen, die notwendig ist, um eine umfassende Recherche und die Vergleichbarkeit der Materialien zu ermöglichen. Trotz größter zumutbarer Sorgfalt können bei diesem Normalisierungsprozess Fehler auftreten, weshalb ausdrücklich darauf hingewiesen wird, dass auf Grundlage der im Material Hub vorhandenen Daten keine Entscheidungen zur Verwendung oder Anschaffung eines Materials getroffen werden dürfen. Vielmehr ist es notwendig den Datenerzeuger im Vorfeld einer solchen Entscheidung direkt zu kontaktieren, um die Korrektheit der Daten zu verifizieren.

INCONEL alloy 718, conventionally hot-rolled (IN_C_2)

The elastic properties (Young's modulus, shear modulus) of Ni-based alloy Inconel IN718 were investigated between room temperature and 800 °C in an additively manufactured variant (laser powder bed fusion, PBF‑LB/M) and from a conventional process route (hot rolled bar). The moduli were determined using the dynamic resonance method. The data set includes information on processing parameters, heat treatments, grain size, specimen dimensions and weight, Young’s and shear modulus as well as their measurement uncertainty.

The dataset was generated in an accredited testing lab using calibrated measuring equipment. The calibrations meet the requirements of the test procedure and are metrologically traceable. The dataset was audited as BAM reference data. The dataset was made available under the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode).

Further information on data and data acquisition, analysis, and experimental details are given in “Elastic modulus data for additively and conventionally manufactured variants of Ti‑6Al‑4V, IN718 and AISI 316L” published in Scientific Data.

Schlagwörter
BAM reference data
Young's modulus
Shear modulus
Zenodo
Data set
Art der Datenquelle Forschungsergebnis
Anwendungsgebiete aerospace; energy; medical; automotive; high temperature application
Bauform blank type: bar; Inclination of specimen (L-direction) relative to rolling direction = 0°; m = 22.278 g
Versuchsaufbau
  • Measurement of Young´s modulus and shear modulus: Elastotron 2000 (HTM Reetz, Berlin, Germany)

Herstellungsverfahren und Ausgangsmaterialien

Name conventionally hot-rolled
Beschreibung heat treatment: 965°C/1h + air cooling to 20°C, 718°C/8h + controlled cooling to 621°C/8h + air cooling
Ausgangsmaterial

Physikalische Eigenschaften

Name Wert Bemerkung Messverfahren und -bedingungen
(mittlere) Korngröße 0.006 mm EBSD
Abmessung (Länge) 99.92 mm T = 24 °C
Abmessung (Länge) 100.03 mm T = 100 °C
Abmessung (Länge) 100.17 mm T = 200 °C
Abmessung (Länge) 100.31 mm T = 300 °C
Abmessung (Länge) 100.46 mm T = 400 °C
Abmessung (Länge) 100.62 mm T = 500 °C
Abmessung (Länge) 100.8 mm T = 600 °C
Abmessung (Länge) 100.91 mm T = 650 °C
Abmessung (Länge) 101.03 mm T = 700 °C
Abmessung (Länge) 101.13 mm T = 750 °C
Abmessung (Länge) 101.24 mm T = 800 °C
Abmessung (Breite) 9.003 mm T = 24 °C
Abmessung (Breite) 9.013 mm T = 100 °C
Abmessung (Breite) 9.025 mm T = 200 °C
Abmessung (Breite) 9.038 mm T = 300 °C
Abmessung (Breite) 9.052 mm T = 400 °C
Abmessung (Breite) 9.066 mm T = 500 °C
Abmessung (Breite) 9.082 mm T = 600 °C
Abmessung (Breite) 9.092 mm T = 650 °C
Abmessung (Breite) 9.103 mm T = 700 °C
Abmessung (Breite) 9.112 mm T = 750 °C
Abmessung (Breite) 9.122 mm T = 800 °C
Abmessung (Tiefe) 3 mm T = 24 °C
Abmessung (Tiefe) 3.003 mm T = 100 °C
Abmessung (Tiefe) 3.007 mm T = 200 °C
Abmessung (Tiefe) 3.012 mm T = 300 °C
Abmessung (Tiefe) 3.016 mm T = 400 °C
Abmessung (Tiefe) 3.021 mm T = 500 °C
Abmessung (Tiefe) 3.026 mm T = 600 °C
Abmessung (Tiefe) 3.03 mm T = 650 °C
Abmessung (Tiefe) 3.033 mm T = 700 °C
Abmessung (Tiefe) 3.036 mm T = 750 °C
Abmessung (Tiefe) 3.04 mm T = 800 °C
Dichte 8.255 g/cm³ T = 24 °C
8.228 g/cm³ T = 100 °C
8.194 g/cm³ T = 200 °C
8.159 g/cm³ T = 300 °C
8.122 g/cm³ T = 400 °C
8.083 g/cm³ T = 500 °C
8.041 g/cm³ T = 600 °C
8.014 g/cm³ T = 650 °C
7.986 g/cm³ T = 700 °C
7.962 g/cm³ T = 750 °C
7.937 g/cm³ T = 800 °C
Mechanische Eigenschaften
 
Schubmodul 79 GPa ft = 8717.0 Hz ASTM E 1875, T = 24 °C
77 GPa ft = 8602.0 Hz ASTM E 1875, T = 100 °C
74 GPa ft = 8454.0 Hz ASTM E 1875, T = 200 °C
72 GPa ft = 8323.0 Hz ASTM E 1875, T = 300 °C
69 GPa ft = 8178.0 Hz ASTM E 1875, T = 400 °C
67 GPa ft = 8043.0 Hz ASTM E 1875, T = 500 °C
63 GPa ft = 7854.0 Hz ASTM E 1875, T = 600 °C
62 GPa ft = 7755.0 Hz ASTM E 1875, T = 650 °C
60 GPa ft = 7632.0 Hz ASTM E 1875, T = 700 °C
58 GPa ft = 7499.0 Hz ASTM E 1875, T = 750 °C
56 GPa ft = 7366.0 Hz ASTM E 1875, T = 800 °C
Zug-Elastizitätsmodul 207 GPa mean ASTM E 1875, T = 24 °C
207 GPa flat-wise in the thickness direction, ff(f) = 1543.0 Hz ASTM E 1875, T = 24 °C
207 GPa edge-wise in the width direction, ff(e) = 4512.0 Hz ASTM E 1875, T = 24 °C
202 GPa mean ASTM E 1875, T = 100 °C
202 GPa flat-wise in the thickness direction, ff(f) = 1525.0 Hz ASTM E 1875, T = 100 °C
202 GPa edge-wise in the width direction, ff(e) = 4459.0 Hz ASTM E 1875, T = 100 °C
195 GPa mean ASTM E 1875, T = 200 °C
196 GPa flat-wise in the thickness direction, ff(f) = 1501.0 Hz ASTM E 1875, T = 200 °C
195 GPa edge-wise in the width direction, ff(e) = 4388.0 Hz ASTM E 1875, T = 200 °C
190 GPa mean ASTM E 1875, T = 300 °C
190 GPa flat-wise in the thickness direction, ff(f) = 1480.0 Hz ASTM E 1875, T = 300 °C
189 GPa edge-wise in the width direction, ff(e) = 4323.0 Hz ASTM E 1875, T = 300 °C
183 GPa mean ASTM E 1875, T = 400 °C
184 GPa flat-wise in the thickness direction, ff(f) = 1456.0 Hz ASTM E 1875, T = 400 °C
183 GPa edge-wise in the width direction, ff(e) = 4255.0 Hz ASTM E 1875, T = 400 °C
177 GPa mean ASTM E 1875, T = 500 °C
178 GPa flat-wise in the thickness direction, ff(f) = 1433.0 Hz ASTM E 1875, T = 500 °C
177 GPa edge-wise in the width direction, ff(e) = 4189.0 Hz ASTM E 1875, T = 500 °C
170 GPa mean ASTM E 1875, T = 600 °C
170 GPa flat-wise in the thickness direction, ff(f) = 1403.0 Hz ASTM E 1875, T = 600 °C
170 GPa edge-wise in the width direction, ff(e) = 4099.0 Hz ASTM E 1875, T = 600 °C
165 GPa mean ASTM E 1875, T = 650 °C
165 GPa flat-wise in the thickness direction, ff(f) = 1385.0 Hz ASTM E 1875, T = 650 °C
165 GPa edge-wise in the width direction, ff(e) = 4052.0 Hz ASTM E 1875, T = 650 °C
161 GPa mean ASTM E 1875, T = 700 °C
161 GPa flat-wise in the thickness direction, ff(f) = 1367.0 Hz ASTM E 1875, T = 700 °C
161 GPa edge-wise in the width direction, ff(e) = 3994.0 Hz ASTM E 1875, T = 700 °C
156 GPa mean ASTM E 1875, T = 750 °C
156 GPa flat-wise in the thickness direction, ff(f) = 1346.0 Hz ASTM E 1875, T = 750 °C
156 GPa edge-wise in the width direction, ff(e) = 3932.0 Hz ASTM E 1875, T = 750 °C
150 GPa mean ASTM E 1875, T = 800 °C
150 GPa flat-wise in the thickness direction, ff(f) = 1322.0 Hz ASTM E 1875, T = 800 °C
150 GPa edge-wise in the width direction, ff(e) = 3863.0 Hz ASTM E 1875, T = 800 °C
Thermische Eigenschaften
 
linearer Längenausdehnungskoeffizient 14.1 10⁻⁶/K T = 100 °C
14.1 10⁻⁶/K T = 200 °C
14.2 10⁻⁶/K T = 300 °C
14.4 10⁻⁶/K T = 400 °C
14.8 10⁻⁶/K T = 500 °C
15.3 10⁻⁶/K T = 600 °C
15.85 10⁻⁶/K T = 650 °C
16.4 10⁻⁶/K T = 700 °C
16.7 10⁻⁶/K T = 750 °C
17 10⁻⁶/K T = 800 °C

Chemische Eigenschaften

chemische Zusammensetzung, elementar (Gewichtsprozent)
Ni

53.7 

Cr

17.82 

Fe

18.26 

Nb

5.21 

Mo

3.02 

Ti

0.93 

Al

0.53 

Co

0.16 

Mn

0.14 

Si

0.08 

Cu

0.04 

Abbildungen und Diagramme

Tensile Modulus of Elasticity at different Temperatures
Tensile Modulus of Elasticity at different Temperatures
Change of Dimensions at different Temperatures compared to 24 °C
Change of Dimensions at different Temperatures compared to 24 °C
Density at different Temperatures
Density at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Shear Modulus at different Temperatures
Shear Modulus at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
weitere Angaben
  • T = temperature
  • m = mass
  • ff(e) = fundamental resonance frequency of the bar in flexure (edge wise)
  • ff(f) = fundamental resonance frequency of the bar in flexure (flat wise)
  • ft = fundamental resonance frequency of the bar in torsion
zugehörige wissenschaftliche Publikation

Beteiligte

Daten bereitgestellt von

SLUB Dresden

Team Material Hub
Anfrage per E-Mail

Webseite | Mehr Details

Ansprechpartner für diese Materialdaten

Material Hub-Team
Anfrage per E-Mail

Haftungsausschluss

Die BAM Referenzdaten wurden von der Bundesanstalt für Materialforschung und -prüfung (BAM) unter der Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode) auf Zenodo bereitgestellt.Die SLUB hat die bereitgestellten Inhalte einer Normalisierung unterzogen, die notwendig ist, um eine umfassende Recherche und die Vergleichbarkeit der Materialien zu ermöglichen. Trotz größter zumutbarer Sorgfalt können bei diesem Normalisierungsprozess Fehler auftreten, weshalb ausdrücklich darauf hingewiesen wird, dass auf Grundlage der im Material Hub vorhandenen Daten keine Entscheidungen zur Verwendung oder Anschaffung eines Materials getroffen werden dürfen. Vielmehr ist es notwendig den Datenerzeuger im Vorfeld einer solchen Entscheidung direkt zu kontaktieren, um die Korrektheit der Daten zu verifizieren.

INCONEL alloy 718, conventionally hot-rolled (IN_C_3)

The elastic properties (Young's modulus, shear modulus) of Ni-based alloy Inconel IN718 were investigated between room temperature and 800 °C in an additively manufactured variant (laser powder bed fusion, PBF‑LB/M) and from a conventional process route (hot rolled bar). The moduli were determined using the dynamic resonance method. The data set includes information on processing parameters, heat treatments, grain size, specimen dimensions and weight, Young’s and shear modulus as well as their measurement uncertainty.

The dataset was generated in an accredited testing lab using calibrated measuring equipment. The calibrations meet the requirements of the test procedure and are metrologically traceable. The dataset was audited as BAM reference data. The dataset was made available under the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode).

Further information on data and data acquisition, analysis, and experimental details are given in “Elastic modulus data for additively and conventionally manufactured variants of Ti‑6Al‑4V, IN718 and AISI 316L” published in Scientific Data.

Schlagwörter
BAM reference data
Young's modulus
Shear modulus
Zenodo
Data set
Art der Datenquelle Forschungsergebnis
Anwendungsgebiete aerospace; energy; medical; automotive; high temperature application
Bauform blank type: bar; Inclination of specimen (L-direction) relative to rolling direction = 0°; m = 21.441 g
Versuchsaufbau
  • Measurement of Young´s modulus and shear modulus: Elastotron 2000 (HTM Reetz, Berlin, Germany)

Herstellungsverfahren und Ausgangsmaterialien

Name conventionally hot-rolled
Beschreibung heat treatment: 965°C/1h + air cooling to 20°C, 718°C/8h + controlled cooling to 621°C/8h + air cooling
Ausgangsmaterial

Physikalische Eigenschaften

Name Wert Bemerkung Messverfahren und -bedingungen
(mittlere) Korngröße 0.006 mm EBSD
Abmessung (Länge) 100.01 mm T = 24 °C
Abmessung (Länge) 100.12 mm T = 100 °C
Abmessung (Länge) 100.26 mm T = 200 °C
Abmessung (Länge) 100.4 mm T = 300 °C
Abmessung (Länge) 100.55 mm T = 400 °C
Abmessung (Länge) 100.71 mm T = 500 °C
Abmessung (Länge) 100.89 mm T = 600 °C
Abmessung (Länge) 101 mm T = 650 °C
Abmessung (Länge) 101.12 mm T = 700 °C
Abmessung (Länge) 101.22 mm T = 750 °C
Abmessung (Länge) 101.33 mm T = 800 °C
Abmessung (Breite) 8.992 mm T = 24 °C
Abmessung (Breite) 9.002 mm T = 100 °C
Abmessung (Breite) 9.014 mm T = 200 °C
Abmessung (Breite) 9.027 mm T = 300 °C
Abmessung (Breite) 9.041 mm T = 400 °C
Abmessung (Breite) 9.055 mm T = 500 °C
Abmessung (Breite) 9.071 mm T = 600 °C
Abmessung (Breite) 9.081 mm T = 650 °C
Abmessung (Breite) 9.092 mm T = 700 °C
Abmessung (Breite) 9.101 mm T = 750 °C
Abmessung (Breite) 9.111 mm T = 800 °C
Abmessung (Tiefe) 2.89 mm T = 24 °C
Abmessung (Tiefe) 2.893 mm T = 100 °C
Abmessung (Tiefe) 2.897 mm T = 200 °C
Abmessung (Tiefe) 2.901 mm T = 300 °C
Abmessung (Tiefe) 2.906 mm T = 400 °C
Abmessung (Tiefe) 2.91 mm T = 500 °C
Abmessung (Tiefe) 2.915 mm T = 600 °C
Abmessung (Tiefe) 2.919 mm T = 650 °C
Abmessung (Tiefe) 2.922 mm T = 700 °C
Abmessung (Tiefe) 2.925 mm T = 750 °C
Abmessung (Tiefe) 2.928 mm T = 800 °C
Dichte 8.25 g/cm³ T = 24 °C
8.223 g/cm³ T = 100 °C
8.189 g/cm³ T = 200 °C
8.154 g/cm³ T = 300 °C
8.117 g/cm³ T = 400 °C
8.078 g/cm³ T = 500 °C
8.036 g/cm³ T = 600 °C
8.009 g/cm³ T = 650 °C
7.981 g/cm³ T = 700 °C
7.957 g/cm³ T = 750 °C
7.932 g/cm³ T = 800 °C
Mechanische Eigenschaften
 
Schubmodul 79 GPa ft = 8464.0 Hz ASTM E 1875, T = 24 °C
77 GPa ft = 8362.0 Hz ASTM E 1875, T = 100 °C
74 GPa ft = 8206.0 Hz ASTM E 1875, T = 200 °C
71 GPa ft = 8069.0 Hz ASTM E 1875, T = 300 °C
69 GPa ft = 7933.0 Hz ASTM E 1875, T = 400 °C
66 GPa ft = 7800.0 Hz ASTM E 1875, T = 500 °C
63 GPa ft = 7624.0 Hz ASTM E 1875, T = 600 °C
62 GPa ft = 7529.0 Hz ASTM E 1875, T = 650 °C
60 GPa ft = 7412.0 Hz ASTM E 1875, T = 700 °C
58 GPa ft = 7289.0 Hz ASTM E 1875, T = 750 °C
56 GPa ft = 7161.0 Hz ASTM E 1875, T = 800 °C
Zug-Elastizitätsmodul 207 GPa mean ASTM E 1875, T = 24 °C
207 GPa flat-wise in the thickness direction, ff(f) = 1482.0 Hz ASTM E 1875, T = 24 °C
207 GPa edge-wise in the width direction, ff(e) = 4498.0 Hz ASTM E 1875, T = 24 °C
202 GPa mean ASTM E 1875, T = 100 °C
202 GPa flat-wise in the thickness direction, ff(f) = 1466.0 Hz ASTM E 1875, T = 100 °C
202 GPa edge-wise in the width direction, ff(e) = 4448.0 Hz ASTM E 1875, T = 100 °C
195 GPa mean ASTM E 1875, T = 200 °C
195 GPa flat-wise in the thickness direction, ff(f) = 1443.0 Hz ASTM E 1875, T = 200 °C
195 GPa edge-wise in the width direction, ff(e) = 4375.0 Hz ASTM E 1875, T = 200 °C
189 GPa mean ASTM E 1875, T = 300 °C
190 GPa flat-wise in the thickness direction, ff(f) = 1423.0 Hz ASTM E 1875, T = 300 °C
189 GPa edge-wise in the width direction, ff(e) = 4311.0 Hz ASTM E 1875, T = 300 °C
183 GPa mean ASTM E 1875, T = 400 °C
183 GPa flat-wise in the thickness direction, ff(f) = 1400.0 Hz ASTM E 1875, T = 400 °C
183 GPa edge-wise in the width direction, ff(e) = 4241.0 Hz ASTM E 1875, T = 400 °C
177 GPa mean ASTM E 1875, T = 500 °C
177 GPa flat-wise in the thickness direction, ff(f) = 1376.0 Hz ASTM E 1875, T = 500 °C
177 GPa edge-wise in the width direction, ff(e) = 4174.0 Hz ASTM E 1875, T = 500 °C
169 GPa mean ASTM E 1875, T = 600 °C
169 GPa flat-wise in the thickness direction, ff(f) = 1347.0 Hz ASTM E 1875, T = 600 °C
169 GPa edge-wise in the width direction, ff(e) = 4086.0 Hz ASTM E 1875, T = 600 °C
165 GPa mean ASTM E 1875, T = 650 °C
165 GPa flat-wise in the thickness direction, ff(f) = 1332.0 Hz ASTM E 1875, T = 650 °C
166 GPa edge-wise in the width direction, ff(e) = 4043.0 Hz ASTM E 1875, T = 650 °C
162 GPa mean ASTM E 1875, T = 700 °C
160 GPa flat-wise in the thickness direction, ff(f) = 1313.0 Hz ASTM E 1875, T = 700 °C
163 GPa edge-wise in the width direction, ff(e) = 4019.0 Hz ASTM E 1875, T = 700 °C
157 GPa mean ASTM E 1875, T = 750 °C
155 GPa flat-wise in the thickness direction, ff(f) = 1290.0 Hz ASTM E 1875, T = 750 °C
159 GPa edge-wise in the width direction, ff(e) = 3970.0 Hz ASTM E 1875, T = 750 °C
148 GPa mean ASTM E 1875, T = 800 °C
149 GPa flat-wise in the thickness direction, ff(f) = 1265.0 Hz ASTM E 1875, T = 800 °C
147 GPa edge-wise in the width direction, ff(e) = 3818.0 Hz ASTM E 1875, T = 800 °C
Thermische Eigenschaften
 
linearer Längenausdehnungskoeffizient 14.1 10⁻⁶/K T = 100 °C
14.1 10⁻⁶/K T = 200 °C
14.2 10⁻⁶/K T = 300 °C
14.4 10⁻⁶/K T = 400 °C
14.8 10⁻⁶/K T = 500 °C
15.3 10⁻⁶/K T = 600 °C
15.85 10⁻⁶/K T = 650 °C
16.4 10⁻⁶/K T = 700 °C
16.7 10⁻⁶/K T = 750 °C
17 10⁻⁶/K T = 800 °C

Chemische Eigenschaften

chemische Zusammensetzung, elementar (Gewichtsprozent)
Ni

53.7 

Cr

17.82 

Fe

18.26 

Nb

5.21 

Mo

3.02 

Ti

0.93 

Al

0.53 

Co

0.16 

Mn

0.14 

Si

0.08 

Cu

0.04 

Abbildungen und Diagramme

Tensile Modulus of Elasticity at different Temperatures
Tensile Modulus of Elasticity at different Temperatures
Change of Dimensions at different Temperatures compared to 24 °C
Change of Dimensions at different Temperatures compared to 24 °C
Density at different Temperatures
Density at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Shear Modulus at different Temperatures
Shear Modulus at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
weitere Angaben
  • T = temperature
  • m = mass
  • ff(e) = fundamental resonance frequency of the bar in flexure (edge wise)
  • ff(f) = fundamental resonance frequency of the bar in flexure (flat wise)
  • ft = fundamental resonance frequency of the bar in torsion
zugehörige wissenschaftliche Publikation

Beteiligte

Daten bereitgestellt von

SLUB Dresden

Team Material Hub
Anfrage per E-Mail

Webseite | Mehr Details

Ansprechpartner für diese Materialdaten

Material Hub-Team
Anfrage per E-Mail

Haftungsausschluss

Die BAM Referenzdaten wurden von der Bundesanstalt für Materialforschung und -prüfung (BAM) unter der Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode) auf Zenodo bereitgestellt.Die SLUB hat die bereitgestellten Inhalte einer Normalisierung unterzogen, die notwendig ist, um eine umfassende Recherche und die Vergleichbarkeit der Materialien zu ermöglichen. Trotz größter zumutbarer Sorgfalt können bei diesem Normalisierungsprozess Fehler auftreten, weshalb ausdrücklich darauf hingewiesen wird, dass auf Grundlage der im Material Hub vorhandenen Daten keine Entscheidungen zur Verwendung oder Anschaffung eines Materials getroffen werden dürfen. Vielmehr ist es notwendig den Datenerzeuger im Vorfeld einer solchen Entscheidung direkt zu kontaktieren, um die Korrektheit der Daten zu verifizieren.

INCONEL alloy 718, conventionally hot-rolled (IN_C_4)

The elastic properties (Young's modulus, shear modulus) of Ni-based alloy Inconel IN718 were investigated between room temperature and 800 °C in an additively manufactured variant (laser powder bed fusion, PBF‑LB/M) and from a conventional process route (hot rolled bar). The moduli were determined using the dynamic resonance method. The data set includes information on processing parameters, heat treatments, grain size, specimen dimensions and weight, Young’s and shear modulus as well as their measurement uncertainty.

The dataset was generated in an accredited testing lab using calibrated measuring equipment. The calibrations meet the requirements of the test procedure and are metrologically traceable. The dataset was audited as BAM reference data. The dataset was made available under the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode).

Further information on data and data acquisition, analysis, and experimental details are given in “Elastic modulus data for additively and conventionally manufactured variants of Ti‑6Al‑4V, IN718 and AISI 316L” published in Scientific Data.

Schlagwörter
BAM reference data
Young's modulus
Shear modulus
Zenodo
Data set
Art der Datenquelle Forschungsergebnis
Anwendungsgebiete aerospace; energy; medical; automotive; high temperature application
Bauform blank type: bar; Inclination of specimen (L-direction) relative to rolling direction = 0°; m = 21.437 g
Versuchsaufbau
  • Measurement of Young´s modulus and shear modulus: Elastotron 2000 (HTM Reetz, Berlin, Germany)

Herstellungsverfahren und Ausgangsmaterialien

Name conventionally hot-rolled
Beschreibung heat treatment: 965°C/1h + air cooling to 20°C, 718°C/8h + controlled cooling to 621°C/8h + air cooling
Ausgangsmaterial

Physikalische Eigenschaften

Name Wert Bemerkung Messverfahren und -bedingungen
(mittlere) Korngröße 0.006 mm EBSD
Abmessung (Länge) 100.01 mm T = 24 °C
Abmessung (Länge) 100.12 mm T = 100 °C
Abmessung (Länge) 100.26 mm T = 200 °C
Abmessung (Länge) 100.4 mm T = 300 °C
Abmessung (Länge) 100.55 mm T = 400 °C
Abmessung (Länge) 100.71 mm T = 500 °C
Abmessung (Länge) 100.89 mm T = 600 °C
Abmessung (Länge) 101 mm T = 650 °C
Abmessung (Länge) 101.12 mm T = 700 °C
Abmessung (Länge) 101.22 mm T = 750 °C
Abmessung (Länge) 101.33 mm T = 800 °C
Abmessung (Breite) 8.993 mm T = 24 °C
Abmessung (Breite) 9.003 mm T = 100 °C
Abmessung (Breite) 9.015 mm T = 200 °C
Abmessung (Breite) 9.028 mm T = 300 °C
Abmessung (Breite) 9.042 mm T = 400 °C
Abmessung (Breite) 9.056 mm T = 500 °C
Abmessung (Breite) 9.072 mm T = 600 °C
Abmessung (Breite) 9.082 mm T = 650 °C
Abmessung (Breite) 9.093 mm T = 700 °C
Abmessung (Breite) 9.102 mm T = 750 °C
Abmessung (Breite) 9.112 mm T = 800 °C
Abmessung (Tiefe) 2.887 mm T = 24 °C
Abmessung (Tiefe) 2.89 mm T = 100 °C
Abmessung (Tiefe) 2.894 mm T = 200 °C
Abmessung (Tiefe) 2.898 mm T = 300 °C
Abmessung (Tiefe) 2.903 mm T = 400 °C
Abmessung (Tiefe) 2.907 mm T = 500 °C
Abmessung (Tiefe) 2.912 mm T = 600 °C
Abmessung (Tiefe) 2.916 mm T = 650 °C
Abmessung (Tiefe) 2.919 mm T = 700 °C
Abmessung (Tiefe) 2.922 mm T = 750 °C
Abmessung (Tiefe) 2.925 mm T = 800 °C
Dichte 8.256 g/cm³ T = 24 °C
8.23 g/cm³ T = 100 °C
8.195 g/cm³ T = 200 °C
8.16 g/cm³ T = 300 °C
8.123 g/cm³ T = 400 °C
8.084 g/cm³ T = 500 °C
8.042 g/cm³ T = 600 °C
8.015 g/cm³ T = 650 °C
7.987 g/cm³ T = 700 °C
7.963 g/cm³ T = 750 °C
7.938 g/cm³ T = 800 °C
Mechanische Eigenschaften
 
Schubmodul 79 GPa ft = 8458.0 Hz ASTM E 1875, T = 24 °C
77 GPa ft = 8344.0 Hz ASTM E 1875, T = 100 °C
74 GPa ft = 8198.0 Hz ASTM E 1875, T = 200 °C
71 GPa ft = 8068.0 Hz ASTM E 1875, T = 300 °C
69 GPa ft = 7929.0 Hz ASTM E 1875, T = 400 °C
66 GPa ft = 7794.0 Hz ASTM E 1875, T = 500 °C
63 GPa ft = 7612.0 Hz ASTM E 1875, T = 600 °C
62 GPa ft = 7516.0 Hz ASTM E 1875, T = 650 °C
59 GPa ft = 7394.0 Hz ASTM E 1875, T = 700 °C
58 GPa ft = 7274.0 Hz ASTM E 1875, T = 750 °C
55 GPa ft = 7135.0 Hz ASTM E 1875, T = 800 °C
Zug-Elastizitätsmodul 207 GPa mean ASTM E 1875, T = 24 °C
207 GPa flat-wise in the thickness direction, ff(f) = 1482.0 Hz ASTM E 1875, T = 24 °C
207 GPa edge-wise in the width direction, ff(e) = 4494.0 Hz ASTM E 1875, T = 24 °C
202 GPa mean ASTM E 1875, T = 100 °C
202 GPa flat-wise in the thickness direction, ff(f) = 1465.0 Hz ASTM E 1875, T = 100 °C
201 GPa edge-wise in the width direction, ff(e) = 4438.0 Hz ASTM E 1875, T = 100 °C
195 GPa mean ASTM E 1875, T = 200 °C
195 GPa flat-wise in the thickness direction, ff(f) = 1441.0 Hz ASTM E 1875, T = 200 °C
195 GPa edge-wise in the width direction, ff(e) = 4366.0 Hz ASTM E 1875, T = 200 °C
189 GPa mean ASTM E 1875, T = 300 °C
189 GPa flat-wise in the thickness direction, ff(f) = 1420.0 Hz ASTM E 1875, T = 300 °C
189 GPa edge-wise in the width direction, ff(e) = 4301.0 Hz ASTM E 1875, T = 300 °C
183 GPa mean ASTM E 1875, T = 400 °C
183 GPa flat-wise in the thickness direction, ff(f) = 1399.0 Hz ASTM E 1875, T = 400 °C
183 GPa edge-wise in the width direction, ff(e) = 4237.0 Hz ASTM E 1875, T = 400 °C
177 GPa mean ASTM E 1875, T = 500 °C
177 GPa flat-wise in the thickness direction, ff(f) = 1375.0 Hz ASTM E 1875, T = 500 °C
176 GPa edge-wise in the width direction, ff(e) = 4167.0 Hz ASTM E 1875, T = 500 °C
169 GPa mean ASTM E 1875, T = 600 °C
169 GPa flat-wise in the thickness direction, ff(f) = 1346.0 Hz ASTM E 1875, T = 600 °C
169 GPa edge-wise in the width direction, ff(e) = 4079.0 Hz ASTM E 1875, T = 600 °C
165 GPa mean ASTM E 1875, T = 650 °C
165 GPa flat-wise in the thickness direction, ff(f) = 1330.0 Hz ASTM E 1875, T = 650 °C
165 GPa edge-wise in the width direction, ff(e) = 4030.0 Hz ASTM E 1875, T = 650 °C
160 GPa mean ASTM E 1875, T = 700 °C
160 GPa flat-wise in the thickness direction, ff(f) = 1310.0 Hz ASTM E 1875, T = 700 °C
160 GPa edge-wise in the width direction, ff(e) = 3971.0 Hz ASTM E 1875, T = 700 °C
155 GPa mean ASTM E 1875, T = 750 °C
155 GPa flat-wise in the thickness direction, ff(f) = 1290.0 Hz ASTM E 1875, T = 750 °C
154 GPa edge-wise in the width direction, ff(e) = 3905.0 Hz ASTM E 1875, T = 750 °C
149 GPa mean ASTM E 1875, T = 800 °C
149 GPa flat-wise in the thickness direction, ff(f) = 1267.0 Hz ASTM E 1875, T = 800 °C
149 GPa edge-wise in the width direction, ff(e) = 3835.0 Hz ASTM E 1875, T = 800 °C
Thermische Eigenschaften
 
linearer Längenausdehnungskoeffizient 14.1 10⁻⁶/K T = 100 °C
14.1 10⁻⁶/K T = 200 °C
14.2 10⁻⁶/K T = 300 °C
14.4 10⁻⁶/K T = 400 °C
14.8 10⁻⁶/K T = 500 °C
15.3 10⁻⁶/K T = 600 °C
15.85 10⁻⁶/K T = 650 °C
16.4 10⁻⁶/K T = 700 °C
16.7 10⁻⁶/K T = 750 °C
17 10⁻⁶/K T = 800 °C

Chemische Eigenschaften

chemische Zusammensetzung, elementar (Gewichtsprozent)
Ni

53.7 

Cr

17.82 

Fe

18.26 

Nb

5.21 

Mo

3.02 

Ti

0.93 

Al

0.53 

Co

0.16 

Mn

0.14 

Si

0.08 

Cu

0.04 

Abbildungen und Diagramme

Tensile Modulus of Elasticity at different Temperatures
Tensile Modulus of Elasticity at different Temperatures
Change of Dimensions at different Temperatures compared to 24 °C
Change of Dimensions at different Temperatures compared to 24 °C
Density at different Temperatures
Density at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Coefficient of Linear Thermal Expansion at different Temperatures
Shear Modulus at different Temperatures
Shear Modulus at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Torsion at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Edge-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
Fundamental Resonance Frequency of the Bar in Flat-Wise Flexure at different Temperatures
weitere Angaben
  • T = temperature
  • m = mass
  • ff(e) = fundamental resonance frequency of the bar in flexure (edge wise)
  • ff(f) = fundamental resonance frequency of the bar in flexure (flat wise)
  • ft = fundamental resonance frequency of the bar in torsion
zugehörige wissenschaftliche Publikation

Beteiligte

Daten bereitgestellt von

SLUB Dresden

Team Material Hub
Anfrage per E-Mail

Webseite | Mehr Details

Ansprechpartner für diese Materialdaten

Material Hub-Team
Anfrage per E-Mail

Haftungsausschluss

Die BAM Referenzdaten wurden von der Bundesanstalt für Materialforschung und -prüfung (BAM) unter der Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/legalcode) auf Zenodo bereitgestellt.Die SLUB hat die bereitgestellten Inhalte einer Normalisierung unterzogen, die notwendig ist, um eine umfassende Recherche und die Vergleichbarkeit der Materialien zu ermöglichen. Trotz größter zumutbarer Sorgfalt können bei diesem Normalisierungsprozess Fehler auftreten, weshalb ausdrücklich darauf hingewiesen wird, dass auf Grundlage der im Material Hub vorhandenen Daten keine Entscheidungen zur Verwendung oder Anschaffung eines Materials getroffen werden dürfen. Vielmehr ist es notwendig den Datenerzeuger im Vorfeld einer solchen Entscheidung direkt zu kontaktieren, um die Korrektheit der Daten zu verifizieren.

Letzte Aktualisierung: 29.07.2024
Projekt | Kontakt | Downloads | Datenschutz | Nutzungsbedingungen | Impressum
LinkedIn | Materials Science
Feedback

Geben Sie uns gern Feedback zum Material Hub.

Kontaktformular

Fragebogen zur Gebrauchstauglichkeit

QR Code