Document Actions
Citation and metadata
Recommended citation
Kanus M, Schmidt C, Overmeyer L (2021). Statistical analysis of the indentation rolling resistance measurement according to DIN EN 16 974 for the validation of simulation models. Logistics Journal : Proceedings, Vol. 2021. (urn:nbn:de:0009-14-54396)
Download Citation
Endnote
%0 Journal Article %T Statistical analysis of the indentation rolling resistance measurement according to DIN EN 16 974 for the validation of simulation models %A Kanus, Malte %A Schmidt, Carsten %A Overmeyer, Ludger %J Logistics Journal : Proceedings %D 2021 %V 2021 %N 17 %@ 2192-9084 %F kanus2021 %X The most significant challenges in belt conveyor technology are continuously increasing mass flows and conveying distances. The resulting increase in movement resistance is thus responsible for the necessary increase in drive power. For the design of belt conveyor systems, it is essential to gain knowledge of the movement resistances that occur. The main resistance comprises indentation rolling resistance (IRR), idler running resistance, vibration bending resistance, bulk material rolling resistance, and camber resistance. The IRR represents the most significant component of the movement resistance for horizontal belt conveyors. Due to the resulting particular importance for the design of belt conveyor systems, a test method for determining the IRR was developed at Iinstitute of Transport and Automation Technology (ITA) and standardized in DIN EN 16 974. This established measurement method is costly and time-consuming, which is why investigations are being carried out at ITA to determine the ERW by simulation. The material parameters required for the simulation are determined from small samples, which support the development of energy-optimized conveyor belts and make them more efficient. The validation of the simulation results bases on the previous metrological determination. Therefore, the statistical proof of the established measurement procedure is of particular interest. %L 620 %K CO2 emissions %K indentation rolling resistance (IRR) %K belt conveyor systems %K energy optimization %K CO2 reduction %K DIN22101 %K DIN EN 16 974 %R 10.2195/lj_Proc_kanus_en_202112_01 %U http://nbn-resolving.de/urn:nbn:de:0009-14-54396 %U http://dx.doi.org/10.2195/lj_Proc_kanus_en_202112_01Download
Bibtex
@Article{kanus2021,
author = "Kanus, Malte
and Schmidt, Carsten
and Overmeyer, Ludger",
title = "Statistical analysis of the indentation rolling resistance measurement according to DIN EN 16 974 for the validation of simulation models",
journal = "Logistics Journal : Proceedings",
year = "2021",
volume = "2021",
number = "17",
keywords = "CO2 emissions; indentation rolling resistance (IRR); belt conveyor systems; energy optimization; CO2 reduction; DIN22101; DIN EN 16 974",
abstract = "The most significant challenges in belt conveyor technology are continuously increasing mass flows and conveying distances. The resulting increase in movement resistance is thus responsible for the necessary increase in drive power. For the design of belt conveyor systems, it is essential to gain knowledge of the movement resistances that occur. The main resistance comprises indentation rolling resistance (IRR), idler running resistance, vibration bending resistance, bulk material rolling resistance, and camber resistance. The IRR represents the most significant component of the movement resistance for horizontal belt conveyors. Due to the resulting particular importance for the design of belt conveyor systems, a test method for determining the IRR was developed at Iinstitute of Transport and Automation Technology (ITA) and standardized in DIN EN 16 974. This established measurement method is costly and time-consuming, which is why investigations are being carried out at ITA to determine the ERW by simulation. The material parameters required for the simulation are determined from small samples, which support the development of energy-optimized conveyor belts and make them more efficient. The validation of the simulation results bases on the previous metrological determination. Therefore, the statistical proof of the established measurement procedure is of particular interest.",
issn = "2192-9084",
doi = "10.2195/lj_Proc_kanus_en_202112_01",
url = "http://nbn-resolving.de/urn:nbn:de:0009-14-54396"
}
Download
RIS
TY - JOUR AU - Kanus, Malte AU - Schmidt, Carsten AU - Overmeyer, Ludger PY - 2021 DA - 2021// TI - Statistical analysis of the indentation rolling resistance measurement according to DIN EN 16 974 for the validation of simulation models JO - Logistics Journal : Proceedings VL - 2021 IS - 17 KW - CO2 emissions KW - indentation rolling resistance (IRR) KW - belt conveyor systems KW - energy optimization KW - CO2 reduction KW - DIN22101 KW - DIN EN 16 974 AB - The most significant challenges in belt conveyor technology are continuously increasing mass flows and conveying distances. The resulting increase in movement resistance is thus responsible for the necessary increase in drive power. For the design of belt conveyor systems, it is essential to gain knowledge of the movement resistances that occur. The main resistance comprises indentation rolling resistance (IRR), idler running resistance, vibration bending resistance, bulk material rolling resistance, and camber resistance. The IRR represents the most significant component of the movement resistance for horizontal belt conveyors. Due to the resulting particular importance for the design of belt conveyor systems, a test method for determining the IRR was developed at Iinstitute of Transport and Automation Technology (ITA) and standardized in DIN EN 16 974. This established measurement method is costly and time-consuming, which is why investigations are being carried out at ITA to determine the ERW by simulation. The material parameters required for the simulation are determined from small samples, which support the development of energy-optimized conveyor belts and make them more efficient. The validation of the simulation results bases on the previous metrological determination. Therefore, the statistical proof of the established measurement procedure is of particular interest. SN - 2192-9084 UR - http://nbn-resolving.de/urn:nbn:de:0009-14-54396 DO - 10.2195/lj_Proc_kanus_en_202112_01 ID - kanus2021 ER -Download
Wordbib
<?xml version="1.0" encoding="UTF-8"?> <b:Sources SelectedStyle="" xmlns:b="http://schemas.openxmlformats.org/officeDocument/2006/bibliography" xmlns="http://schemas.openxmlformats.org/officeDocument/2006/bibliography" > <b:Source> <b:Tag>kanus2021</b:Tag> <b:SourceType>ArticleInAPeriodical</b:SourceType> <b:Year>2021</b:Year> <b:PeriodicalTitle>Logistics Journal : Proceedings</b:PeriodicalTitle> <b:Volume>2021</b:Volume> <b:Issue>17</b:Issue> <b:Url>http://nbn-resolving.de/urn:nbn:de:0009-14-54396</b:Url> <b:Url>http://dx.doi.org/10.2195/lj_Proc_kanus_en_202112_01</b:Url> <b:Author> <b:Author><b:NameList> <b:Person><b:Last>Kanus</b:Last><b:First>Malte</b:First></b:Person> <b:Person><b:Last>Schmidt</b:Last><b:First>Carsten</b:First></b:Person> <b:Person><b:Last>Overmeyer</b:Last><b:First>Ludger</b:First></b:Person> </b:NameList></b:Author> </b:Author> <b:Title>Statistical analysis of the indentation rolling resistance measurement according to DIN EN 16 974 for the validation of simulation models</b:Title> <b:Comments>The most significant challenges in belt conveyor technology are continuously increasing mass flows and conveying distances. The resulting increase in movement resistance is thus responsible for the necessary increase in drive power. For the design of belt conveyor systems, it is essential to gain knowledge of the movement resistances that occur. The main resistance comprises indentation rolling resistance (IRR), idler running resistance, vibration bending resistance, bulk material rolling resistance, and camber resistance. The IRR represents the most significant component of the movement resistance for horizontal belt conveyors. Due to the resulting particular importance for the design of belt conveyor systems, a test method for determining the IRR was developed at Iinstitute of Transport and Automation Technology (ITA) and standardized in DIN EN 16 974. This established measurement method is costly and time-consuming, which is why investigations are being carried out at ITA to determine the ERW by simulation. The material parameters required for the simulation are determined from small samples, which support the development of energy-optimized conveyor belts and make them more efficient. The validation of the simulation results bases on the previous metrological determination. Therefore, the statistical proof of the established measurement procedure is of particular interest.</b:Comments> </b:Source> </b:Sources>Download
ISI
PT Journal AU Kanus, M Schmidt, C Overmeyer, L TI Statistical analysis of the indentation rolling resistance measurement according to DIN EN 16 974 for the validation of simulation models SO Logistics Journal : Proceedings PY 2021 VL 2021 IS 17 DI 10.2195/lj_Proc_kanus_en_202112_01 DE CO2 emissions; indentation rolling resistance (IRR); belt conveyor systems; energy optimization; CO2 reduction; DIN22101; DIN EN 16 974 AB The most significant challenges in belt conveyor technology are continuously increasing mass flows and conveying distances. The resulting increase in movement resistance is thus responsible for the necessary increase in drive power. For the design of belt conveyor systems, it is essential to gain knowledge of the movement resistances that occur. The main resistance comprises indentation rolling resistance (IRR), idler running resistance, vibration bending resistance, bulk material rolling resistance, and camber resistance. The IRR represents the most significant component of the movement resistance for horizontal belt conveyors. Due to the resulting particular importance for the design of belt conveyor systems, a test method for determining the IRR was developed at Iinstitute of Transport and Automation Technology (ITA) and standardized in DIN EN 16 974. This established measurement method is costly and time-consuming, which is why investigations are being carried out at ITA to determine the ERW by simulation. The material parameters required for the simulation are determined from small samples, which support the development of energy-optimized conveyor belts and make them more efficient. The validation of the simulation results bases on the previous metrological determination. Therefore, the statistical proof of the established measurement procedure is of particular interest. ERDownload
Mods
<mods>
<titleInfo>
<title>Statistical analysis of the indentation rolling resistance measurement according to DIN EN 16 974 for the validation of simulation models</title>
</titleInfo>
<name type="personal">
<namePart type="family">Kanus</namePart>
<namePart type="given">Malte</namePart>
</name>
<name type="personal">
<namePart type="family">Schmidt</namePart>
<namePart type="given">Carsten</namePart>
</name>
<name type="personal">
<namePart type="family">Overmeyer</namePart>
<namePart type="given">Ludger</namePart>
</name>
<abstract>The most significant challenges in belt conveyor technology are continuously increasing mass flows and conveying distances. The resulting increase in movement resistance is thus responsible for the necessary increase in drive power. For the design of belt conveyor systems, it is essential to gain knowledge of the movement resistances that occur. The main resistance comprises indentation rolling resistance (IRR), idler running resistance, vibration bending resistance, bulk material rolling resistance, and camber resistance. The IRR represents the most significant component of the movement resistance for horizontal belt conveyors. Due to the resulting particular importance for the design of belt conveyor systems, a test method for determining the IRR was developed at Iinstitute of Transport and Automation Technology (ITA) and standardized in DIN EN 16 974. This established measurement method is costly and time-consuming, which is why investigations are being carried out at ITA to determine the ERW by simulation. The material parameters required for the simulation are determined from small samples, which support the development of energy-optimized conveyor belts and make them more efficient. The validation of the simulation results bases on the previous metrological determination. Therefore, the statistical proof of the established measurement procedure is of particular interest.</abstract>
<subject>
<topic>CO2 emissions</topic>
<topic>indentation rolling resistance (IRR)</topic>
<topic>belt conveyor systems</topic>
<topic>energy optimization</topic>
<topic>CO2 reduction</topic>
<topic>DIN22101</topic>
<topic>DIN EN 16 974</topic>
</subject>
<classification authority="ddc">620</classification>
<relatedItem type="host">
<genre authority="marcgt">periodical</genre>
<genre>academic journal</genre>
<titleInfo>
<title>Logistics Journal : Proceedings</title>
</titleInfo>
<part>
<detail type="volume">
<number>2021</number>
</detail>
<detail type="issue">
<number>17</number>
</detail>
<date>2021</date>
</part>
</relatedItem>
<identifier type="issn">2192-9084</identifier>
<identifier type="urn">urn:nbn:de:0009-14-54396</identifier>
<identifier type="doi">10.2195/lj_Proc_kanus_en_202112_01</identifier>
<identifier type="uri">http://nbn-resolving.de/urn:nbn:de:0009-14-54396</identifier>
<identifier type="citekey">kanus2021</identifier>
</mods>
Download
Full Metadata
| Bibliographic Citation | Logistics Journal : referierte Veröffentlichungen, Vol. 2021, Iss. 17 |
|---|---|
| Title |
Statistical analysis of the indentation rolling resistance measurement according to DIN EN 16 974 for the validation of simulation models (eng) |
| Author | Malte Kanus, Carsten Schmidt, Ludger Overmeyer |
| Language | eng |
| Abstract | The most significant challenges in belt conveyor technology are continuously increasing mass flows and conveying distances. The resulting increase in movement resistance is thus responsible for the necessary increase in drive power. For the design of belt conveyor systems, it is essential to gain knowledge of the movement resistances that occur. The main resistance comprises indentation rolling resistance (IRR), idler running resistance, vibration bending resistance, bulk material rolling resistance, and camber resistance. The IRR represents the most significant component of the movement resistance for horizontal belt conveyors. Due to the resulting particular importance for the design of belt conveyor systems, a test method for determining the IRR was developed at Iinstitute of Transport and Automation Technology (ITA) and standardized in DIN EN 16 974. This established measurement method is costly and time-consuming, which is why investigations are being carried out at ITA to determine the ERW by simulation. The material parameters required for the simulation are determined from small samples, which support the development of energy-optimized conveyor belts and make them more efficient. The validation of the simulation results bases on the previous metrological determination. Therefore, the statistical proof of the established measurement procedure is of particular interest. Die größten Herausforderungen in der Gurtfördertechnik stellen kontinuierlich steigende Massenströme sowie Förderstrecken dar. Die hieraus resultierende Erhöhung der Bewegungswiderstände ist somit für eine notwendige Steigerung der Antriebsleistung verantwortlich. Für die Auslegung von Gurtförderanlagen ist es deshalb von besonderer Wichtigkeit, Kenntnis über die sich einstellenden Bewegungswiderstände zu erlangen. Der Hauptwiderstand setzt sich aus Eindrückrollwiderstand (ERW), Tragrollenlaufwiderstand, Schwingbiegewiederstand, Schüttgutwalkwiderstand und Sturzwiderstand zusammen. Der stellt ERW den größten Bestandteil des Bewegungswiderstandes für horizontale Gurtförderanlagen dar. Aufgrund der daraus resultierenden besonderen Wichtigkeit für die Auslegung von Gurtförderanlagen wurde am Institut für Transport- und Automatisierungstechnik (ITA) ein Prüfverfahren zur Ermittlung des ERW entwickelt und in DIN EN 16?974 genormt. Dieses etablierte Messverfahren ist kosten- und zeitaufwendig, weshalb am ITA Untersuchungen zur simulativen Bestimmung des ERW durchgeführt werden. Die hierfür notwendigen Materialparameter werden aus kleinen Proben ermittelt, wodurch die Entwicklung energieoptimierter Fördergurte unterstützt und effizienter gestaltet wird. Die Validierung der Simulationsergebnisse basiert auf die bisherige messtechnische Ermittlung. Deshalb ist die statistische Absicherung des etablierten Messverfahrens von besonderem Interesse. |
| Subject | CO2 emissions, indentation rolling resistance (IRR), belt conveyor systems, energy optimization, CO2 reduction, DIN22101, DIN EN 16 974 |
| DDC | 620 |
| Rights | fDPPL |
| URN: | urn:nbn:de:0009-14-54396 |
| DOI | https://doi.org/10.2195/lj_Proc_kanus_en_202112_01 |