https://en.wiki.polymerservice-merseburg.de/index.php?action=history&feed=atom&title=Melt_Mass-Flow_RateMelt Mass-Flow Rate - Revision history2026-04-22T18:28:54ZRevision history for this page on the wikiMediaWiki 1.43.1https://en.wiki.polymerservice-merseburg.de/index.php?title=Melt_Mass-Flow_Rate&diff=475&oldid=prevOluschinski: Created page with "{{Language_sel|LANG=ger|ARTIKEL=Schmelze-Massefließrate}} {{PSM_Infobox}} <span style="font-size:1.2em;font-weight:bold;">Melt mass-flow rate (MFR) (Author: Prof. Dr. H.-J. Radusch)</span> __FORCETOC__ ==Measure of the MFR== The melt index (MFR = Melt Mass-Flow Rate, the former MFI = Melt Flow Index) characterises the flow behaviour of a thermoplastic material. For measuring the MFR, melt index gauge systems, whic..."2025-12-03T12:06:18Z<p>Created page with "{{Language_sel|LANG=ger|ARTIKEL=Schmelze-Massefließrate}} {{PSM_Infobox}} <span style="font-size:1.2em;font-weight:bold;">Melt mass-flow rate (MFR) (Author: <a href="/index.php/Radusch,_Hans-Joachim" title="Radusch, Hans-Joachim">Prof. Dr. H.-J. Radusch</a>)</span> __FORCETOC__ ==Measure of the MFR== The melt index (MFR = Melt Mass-Flow Rate, the former MFI = Melt Flow Index) characterises the flow behaviour of a <a href="/index.php/Thermoplastic_Material" title="Thermoplastic Material"> thermoplastic material</a>. For measuring the MFR, melt index gauge systems, whic..."</p>
<p><b>New page</b></p><div>{{Language_sel|LANG=ger|ARTIKEL=Schmelze-Massefließrate}}<br />
{{PSM_Infobox}}<br />
<span style="font-size:1.2em;font-weight:bold;">Melt mass-flow rate (MFR) (Author: [[Radusch, Hans-Joachim|Prof. Dr. H.-J. Radusch]])</span><br />
__FORCETOC__<br />
<br />
==Measure of the MFR==<br />
<br />
The melt index (MFR = Melt Mass-Flow Rate, the former MFI = Melt Flow Index) characterises the flow behaviour of a [[Thermoplastic Material | thermoplastic material]]. For measuring the MFR, melt index gauge systems, which are a special type of [[Capillary Rheometer | capillary rheometer]] ('''Fig. 1'''), are used to measure the melt index [1].<br />
<br />
[[file:MFR1 (en).jpg|400px]]<br />
{| <br />
|- valign="top"<br />
|width="50px"|'''Fig. 1''': <br />
|width="600px"|Typical gauge system to measure the Melt index<br />
|}<br />
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==Melt mass-flow rate formula==<br />
<br />
The procedure for determining the melt flow index is standardised in ISO 1133 [2] and ASTM D 1238a [3]. The melt flow rate is defined as the MFR value, which indicates the amount of material in grams that flows through a capillary with defined dimensions in ten minutes at a certain pressure and temperature.<br />
<br />
{|<br />
|-<br />
|width="20px"|<br />
|width="500px" | <math> MFR = \frac {m \ t_{ref}}{t} = \frac {m \ 600}{t} </math><br />
|<br />
|}<br />
<br />
with<br />
{|<br />
|-<br />
|m<br />
|width="15px" | <br />
|average mass of the sections <br><br />
|-<br />
|t<br />
| <br />
|time interval for the cut-off <br><br />
|-<br />
|t<sub>ref</sub><br />
|<br />
|600 s<br><br />
|}<br />
<br />
The melt flow index is given in the unit g (10 min)<sup>-1</sup>.<br />
The melt index value only represents a single value proportional to the [[Viscosity | viscosity]] at a relatively low shear rate. Due to the simple measuring principle, there is no direct comparability with viscosity values measured on high-pressure [[Capillary Rheometer | capillary rheometers]].<br />
<br />
==Test conditions for measuring==<br />
<br />
The nozzle of the melt index tester is designed as a very short capillary, usually with an L/D ratio of 10/1. The pressure required to press the melt out of the temperature-controlled cylinder is realised by applying a defined load with support weights. The test conditions are specified in ISO 1133 [2]. Common test parameters for [[Thermoplastic Material | thermoplastics]] are summarised in the table. The respective test temperature is taken from the test standard, depending on the material and the load.<br />
<br />
{|border="1px" style="border-collapse:collapse"<br />
|+ style="margin-bottom:0.5em;"|'''Table''': Test conditions for measuring the melt mass-flow rate<br />
!! style="width: 290px; background:#DCDCDC"|Mass of the support weights (kg) <br />
!! style="width: 230px; background:#DCDCDC"|Piston force (N)<br />
!! style="width: 230px; background:#DCDCDC"|Piston pressure (bar)<br />
!! style="width: 250px; background:#DCDCDC"|Apparent shear stress (Pa)<br />
|-<br />
|style="text-align:center"| 0.325 <br />
|style="text-align:center"| 3.187 <br />
|style="text-align:center"| 0.4516 <br />
|style="text-align:center"| 2.956 ⋅ 10<sup>3</sup> <br />
|-<br />
|style="text-align:center"| 1.20 <br />
|style="text-align:center"| 11.77<br />
|style="text-align:center"| 1.6670 <br />
|style="text-align:center"| 1.092 ⋅ 10<sup>4</sup><br />
|-<br />
|style="text-align:center"| 2.16<br />
|style="text-align:center"| 21.18 <br />
|style="text-align:center"| 3.0010 <br />
|style="text-align:center"| 1.965 ⋅ 10<sup>4</sup><br />
|-<br />
|style="text-align:center"| 3.8 <br />
|style="text-align:center"| 37.27 <br />
|style="text-align:center"| 5.2800 <br />
|style="text-align:center"| 3.457 ⋅ 10<sup>4</sup><br />
|-<br />
|style="text-align:center"| 5.0 <br />
|style="text-align:center"| 49.03 <br />
|style="text-align:center"| 6.9470<br />
|style="text-align:center"| 4.548 ⋅ 10<sup>4</sup><br />
|-<br />
|style="text-align:center"| 10.0<br />
|style="text-align:center"| 98.07 <br />
|style="text-align:center"| 13.8900<br />
|style="text-align:center"| 9.096 ⋅ 10<sup>4</sup><br />
|-<br />
|style="text-align:center"| 15.0 <br />
|style="text-align:center"| 147.1 <br />
|style="text-align:center"| 20.8400 <br />
|style="text-align:center"| 1.364 ⋅ 10<sup>5</sup><br />
|-<br />
|style="text-align:center"| 21.6 <br />
|style="text-align:center"| 211.8 <br />
|style="text-align:center"| 30.0100 <br />
|style="text-align:center"| 1.965 ⋅ 10<sup>5</sup><br />
|}<br />
<br />
The melt flow index MFR is frequently used in testing practice as a simple and quick method of incoming goods or quality control, but is also important in damage analysis or customer complaints.<br />
<br />
'''Acknowledgement'''<br />
<br />
The editors of the encyclopaedia would like to thank Prof. Dr. H.-J. Radusch, [https://www.uni-halle.de Martin-Luther-Universität Halle-Wittenberg] and [https://www.polymerservice-merseburg.de Polymer Service GmbH Merseburg] for this guest article.<br />
<br />
==See also==<br />
<br />
*[[Melt Volume-Flow Rate|Melt volume-flow rate]]<br />
*[[Moulding Compound Test|Moulding compound test]]<br />
*[[Heat Resistance|Heat resistance]]<br />
*[[Glowing Hot-Wire Test|Glowing hot-wire test]]<br />
*[[Capillary Rheometer|Capillary rheometer]]<br />
<br />
'''References'''<br />
<br />
{|<br />
|-valign="top"<br />
|[1]<br />
|[[Radusch, Hans-Joachim | Radusch, H.-J.]]: Determining Process-Related Properties. In: [[Grellmann,_Wolfgang|Grellmann, W.]], [[Seidler,_Sabine|Seidler, S.]] (Eds.): Polymer Testing. Carl Hanser Munich (2022) 3rd. Edition, pp. 39–70, (ISBN 978-1-56990-806-8; E-Book ISBN 978-1-56990-807-5; see [[AMK-Büchersammlung|AMK-Library]] under A 22) <br />
|-valign="top"<br />
|[2]<br />
|ISO 1133: Plastics – Determination of the Melt Mass-flow Rate (MFR) and Melt Volume-flow Rate (MVR) of Thermoplastics<br />
|}<br />
*Part 1 (2022-06): Standard Method<br />
*Part 2 (2011-12): Method for Materials Sensitive to Time-temperature History and/or Moisture<br />
{|<br />
|-valign="top"<br />
|[3]<br />
|ASTM D 1238a (2023): Standard Test Method for Melt Flow Rates of Thermoplastics by Extrusion Plastometer<br />
<br />
==Weblink==<br />
|-valign="top"<br />
|[4]<br />
|Wikipedia – The Free Encyclopedia: Melt flow rate (MFR). https://en.wikipedia.org/wiki/Melt_flow_index<br />
|}<br />
<br />
[[category:Guest Contributions]]<br />
[[Category:Process-related Properties]]</div>Oluschinski