Characterizing the Vibro-acoustic Signals of Electromechanical Transmissions for Online Monitoring 3D Printing Process of FDM

Xinfeng Zou; Zhen Li; Chunhua Yang; Fengshou Gu; Andrew D. Ball

doi:10.1007/978-3-031-49421-5_50

Characterizing the Vibro-acoustic Signals of Electromechanical Transmissions for Online Monitoring 3D Printing Process of FDM

Xinfeng Zou, Zhen Li^*, Chunhua Yang, Fengshou Gu, Andrew D. Ball

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摘要

Currently, the 3D printing process is characterized by a prolonged printing time, unstable printing quality, and susceptibility to a variety of disruptions. Consequently, it is necessary to propose a method of condition monitoring during the 3D printing process to assure the stable quality of the printed model and to replace operators’ constant observation during the 3D printing process. Since fused deposition modelling (FDM) is one of the most widely used 3D printing techniques, this research focuses on the relationship between the printing process of FDM and vibro-acoustic signals from the electromechanical transmission system, improves coupled equations to illustrate the relationship between the printing velocity and step motor frequencies based on the electromechanical transmission kinematics, and develops an online condition monitoring method as a result. Based on theoretical analysis and data processing, the enhanced coupled equations are proposed to initiate the research. Afterwards, the coupled equations have been validated through experimentation. Lastly, this research investigates whether the vibro-acoustic signal characteristics can be utilized for online monitoring of the FDM 3D printing process. Current studies indicate that vibration signals are more effective than acoustic signals for online condition monitoring of the FDM 3D printing process, and that the proposed technique can be used to effectively monitor the 3D printing process.

源语言	英语
主期刊名	Proceedings of the UNIfied Conference of DAMAS, IncoME and TEPEN Conferences (UNIfied 2023) - Volume 2
编辑	Andrew D. Ball, Zuolu Wang, Huajiang Ouyang, Jyoti K. Sinha
出版商	Springer Science and Business Media B.V.
页	615-627
页数	13
ISBN（印刷版）	9783031494208
DOI	https://doi.org/10.1007/978-3-031-49421-5_50
出版状态	已出版 - 2024
活动	UNIfied Conference of International Workshop on Defence Applications of Multi-Agent Systems, DAMAS 2023, International Conference on Maintenance Engineering, IncoME-V 2023, International conference on the Efficiency and Performance Engineering Network, TEPEN 2023 - Huddersfield, 英国期限: 29 8月 2023 → 1 9月 2023

出版系列

姓名	Mechanisms and Machine Science
卷	152 MMS
ISSN（印刷版）	2211-0984
ISSN（电子版）	2211-0992

会议

会议	UNIfied Conference of International Workshop on Defence Applications of Multi-Agent Systems, DAMAS 2023, International Conference on Maintenance Engineering, IncoME-V 2023, International conference on the Efficiency and Performance Engineering Network, TEPEN 2023
国家/地区	英国
市	Huddersfield
时期	29/08/23 → 1/09/23

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10.1007/978-3-031-49421-5_50

其它文件与链接

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引用此

Zou, X., Li, Z., Yang, C., Gu, F., & Ball, A. D. (2024). Characterizing the Vibro-acoustic Signals of Electromechanical Transmissions for Online Monitoring 3D Printing Process of FDM. 在 A. D. Ball, Z. Wang, H. Ouyang, & J. K. Sinha (编辑), Proceedings of the UNIfied Conference of DAMAS, IncoME and TEPEN Conferences (UNIfied 2023) - Volume 2 (页码 615-627). (Mechanisms and Machine Science; 卷 152 MMS). Springer Science and Business Media B.V.. https://doi.org/10.1007/978-3-031-49421-5_50

Zou, Xinfeng ; Li, Zhen ; Yang, Chunhua 等. / Characterizing the Vibro-acoustic Signals of Electromechanical Transmissions for Online Monitoring 3D Printing Process of FDM. Proceedings of the UNIfied Conference of DAMAS, IncoME and TEPEN Conferences (UNIfied 2023) - Volume 2. 编辑 / Andrew D. Ball ; Zuolu Wang ; Huajiang Ouyang ; Jyoti K. Sinha. Springer Science and Business Media B.V., 2024. 页码 615-627 (Mechanisms and Machine Science).

@inproceedings{c6dda150ddb743be84b8225a10674610,

title = "Characterizing the Vibro-acoustic Signals of Electromechanical Transmissions for Online Monitoring 3D Printing Process of FDM",

abstract = "Currently, the 3D printing process is characterized by a prolonged printing time, unstable printing quality, and susceptibility to a variety of disruptions. Consequently, it is necessary to propose a method of condition monitoring during the 3D printing process to assure the stable quality of the printed model and to replace operators{\textquoteright} constant observation during the 3D printing process. Since fused deposition modelling (FDM) is one of the most widely used 3D printing techniques, this research focuses on the relationship between the printing process of FDM and vibro-acoustic signals from the electromechanical transmission system, improves coupled equations to illustrate the relationship between the printing velocity and step motor frequencies based on the electromechanical transmission kinematics, and develops an online condition monitoring method as a result. Based on theoretical analysis and data processing, the enhanced coupled equations are proposed to initiate the research. Afterwards, the coupled equations have been validated through experimentation. Lastly, this research investigates whether the vibro-acoustic signal characteristics can be utilized for online monitoring of the FDM 3D printing process. Current studies indicate that vibration signals are more effective than acoustic signals for online condition monitoring of the FDM 3D printing process, and that the proposed technique can be used to effectively monitor the 3D printing process.",

keywords = "Condition monitoring, Electromechanical transmissions, FDM 3D printer, Vibro-acoustic signal",

author = "Xinfeng Zou and Zhen Li and Chunhua Yang and Fengshou Gu and Ball, {Andrew D.}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Switzerland AG 2024.; UNIfied Conference of International Workshop on Defence Applications of Multi-Agent Systems, DAMAS 2023, International Conference on Maintenance Engineering, IncoME-V 2023, International conference on the Efficiency and Performance Engineering Network, TEPEN 2023 ; Conference date: 29-08-2023 Through 01-09-2023",

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doi = "10.1007/978-3-031-49421-5_50",

language = "English",

isbn = "9783031494208",

series = "Mechanisms and Machine Science",

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pages = "615--627",

editor = "Ball, {Andrew D.} and Zuolu Wang and Huajiang Ouyang and Sinha, {Jyoti K.}",

booktitle = "Proceedings of the UNIfied Conference of DAMAS, IncoME and TEPEN Conferences (UNIfied 2023) - Volume 2",

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Zou, X, Li, Z, Yang, C, Gu, F & Ball, AD 2024, Characterizing the Vibro-acoustic Signals of Electromechanical Transmissions for Online Monitoring 3D Printing Process of FDM. 在 AD Ball, Z Wang, H Ouyang & JK Sinha (编辑), Proceedings of the UNIfied Conference of DAMAS, IncoME and TEPEN Conferences (UNIfied 2023) - Volume 2. Mechanisms and Machine Science, 卷 152 MMS, Springer Science and Business Media B.V., 页码 615-627, UNIfied Conference of International Workshop on Defence Applications of Multi-Agent Systems, DAMAS 2023, International Conference on Maintenance Engineering, IncoME-V 2023, International conference on the Efficiency and Performance Engineering Network, TEPEN 2023, Huddersfield, 英国, 29/08/23. https://doi.org/10.1007/978-3-031-49421-5_50

Characterizing the Vibro-acoustic Signals of Electromechanical Transmissions for Online Monitoring 3D Printing Process of FDM. / Zou, Xinfeng; Li, Zhen; Yang, Chunhua 等.
Proceedings of the UNIfied Conference of DAMAS, IncoME and TEPEN Conferences (UNIfied 2023) - Volume 2. 编辑 / Andrew D. Ball; Zuolu Wang; Huajiang Ouyang; Jyoti K. Sinha. Springer Science and Business Media B.V., 2024. 页码 615-627 (Mechanisms and Machine Science; 卷 152 MMS).

科研成果: 书/报告/会议事项章节 › 会议稿件 › 同行评审

TY - GEN

T1 - Characterizing the Vibro-acoustic Signals of Electromechanical Transmissions for Online Monitoring 3D Printing Process of FDM

AU - Zou, Xinfeng

AU - Li, Zhen

AU - Yang, Chunhua

AU - Gu, Fengshou

AU - Ball, Andrew D.

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Switzerland AG 2024.

PY - 2024

Y1 - 2024

N2 - Currently, the 3D printing process is characterized by a prolonged printing time, unstable printing quality, and susceptibility to a variety of disruptions. Consequently, it is necessary to propose a method of condition monitoring during the 3D printing process to assure the stable quality of the printed model and to replace operators’ constant observation during the 3D printing process. Since fused deposition modelling (FDM) is one of the most widely used 3D printing techniques, this research focuses on the relationship between the printing process of FDM and vibro-acoustic signals from the electromechanical transmission system, improves coupled equations to illustrate the relationship between the printing velocity and step motor frequencies based on the electromechanical transmission kinematics, and develops an online condition monitoring method as a result. Based on theoretical analysis and data processing, the enhanced coupled equations are proposed to initiate the research. Afterwards, the coupled equations have been validated through experimentation. Lastly, this research investigates whether the vibro-acoustic signal characteristics can be utilized for online monitoring of the FDM 3D printing process. Current studies indicate that vibration signals are more effective than acoustic signals for online condition monitoring of the FDM 3D printing process, and that the proposed technique can be used to effectively monitor the 3D printing process.

AB - Currently, the 3D printing process is characterized by a prolonged printing time, unstable printing quality, and susceptibility to a variety of disruptions. Consequently, it is necessary to propose a method of condition monitoring during the 3D printing process to assure the stable quality of the printed model and to replace operators’ constant observation during the 3D printing process. Since fused deposition modelling (FDM) is one of the most widely used 3D printing techniques, this research focuses on the relationship between the printing process of FDM and vibro-acoustic signals from the electromechanical transmission system, improves coupled equations to illustrate the relationship between the printing velocity and step motor frequencies based on the electromechanical transmission kinematics, and develops an online condition monitoring method as a result. Based on theoretical analysis and data processing, the enhanced coupled equations are proposed to initiate the research. Afterwards, the coupled equations have been validated through experimentation. Lastly, this research investigates whether the vibro-acoustic signal characteristics can be utilized for online monitoring of the FDM 3D printing process. Current studies indicate that vibration signals are more effective than acoustic signals for online condition monitoring of the FDM 3D printing process, and that the proposed technique can be used to effectively monitor the 3D printing process.

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KW - Electromechanical transmissions

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KW - Vibro-acoustic signal

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ER -

Zou X, Li Z, Yang C, Gu F, Ball AD. Characterizing the Vibro-acoustic Signals of Electromechanical Transmissions for Online Monitoring 3D Printing Process of FDM. 在 Ball AD, Wang Z, Ouyang H, Sinha JK, 编辑, Proceedings of the UNIfied Conference of DAMAS, IncoME and TEPEN Conferences (UNIfied 2023) - Volume 2. Springer Science and Business Media B.V. 2024. 页码 615-627. (Mechanisms and Machine Science). doi: 10.1007/978-3-031-49421-5_50

Characterizing the Vibro-acoustic Signals of Electromechanical Transmissions for Online Monitoring 3D Printing Process of FDM

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