Detecting broken Reciprocating Compressor Valves in the pV-diagram

Kurt Pichler; Edwin Lughofer; Markus Pichler; Thomas Buchegger; Erich Klement; Matthias Huschenbett

Detecting broken Reciprocating Compressor Valves in the pV-diagram

Kurt Pichler, Edwin Lughofer, Markus Pichler, Thomas Buchegger, Erich Klement, Matthias Huschenbett

Institute for Mathematical Methods in Medicine and Data Based Modeling

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

This paper presents a novel data-driven approach to detecting broken reciprocating compressor valves that is based on the idea that a broken valve will affect the shape of the pressurevolume (pV) diagram. This effect can be observed when the valves are closed. To avoid disturbances due to the load control we concentrate on the expansion phase linearized using the logarithmic pV diagram. The gradient of the expansion phase serves as an indicator of the fault state of the valves. Since the gradient is also affected by the pressure conditions, they are used as an additional indicator. After feature extraction and removing offset in the feature space by solving an optimization problem, classification of different valve types can be achieved with one support vector machine classifer. The performance of the method was validated by analyzing real-world measurement data. Our results show a very high classification accuracy for varying compressor load and pressure conditions.

Original language	English
Title of host publication	Proceedings of the ASME 2013 Conference on Smart Materials, Adaptive Structures and Intelligent Systems (SMAIS 2013)
Publisher	ASME
Number of pages	9
Publication status	Published - Sept 2013

Publication series

Name	SMASIS

Fields of science

101001 Algebra
101 Mathematics
102 Computer Sciences
101013 Mathematical logic
101020 Technical mathematics
102001 Artificial intelligence
102003 Image processing
202027 Mechatronics
101019 Stochastics
211913 Quality assurance

JKU Focus areas

Computation in Informatics and Mathematics
Mechatronics and Information Processing
Nano-, Bio- and Polymer-Systems: From Structure to Function

Cite this

@inproceedings{fdd93abef05e427c9a618837afc645c7,

title = "Detecting broken Reciprocating Compressor Valves in the pV-diagram",

abstract = "This paper presents a novel data-driven approach to detecting broken reciprocating compressor valves that is based on the idea that a broken valve will affect the shape of the pressurevolume (pV) diagram. This effect can be observed when the valves are closed. To avoid disturbances due to the load control we concentrate on the expansion phase linearized using the logarithmic pV diagram. The gradient of the expansion phase serves as an indicator of the fault state of the valves. Since the gradient is also affected by the pressure conditions, they are used as an additional indicator. After feature extraction and removing offset in the feature space by solving an optimization problem, classification of different valve types can be achieved with one support vector machine classifer. The performance of the method was validated by analyzing real-world measurement data. Our results show a very high classification accuracy for varying compressor load and pressure conditions.",

author = "Kurt Pichler and Edwin Lughofer and Markus Pichler and Thomas Buchegger and Erich Klement and Matthias Huschenbett",

year = "2013",

month = sep,

language = "English",

series = "SMASIS",

publisher = "ASME",

booktitle = "Proceedings of the ASME 2013 Conference on Smart Materials, Adaptive Structures and Intelligent Systems (SMAIS 2013)",

}

TY - GEN

T1 - Detecting broken Reciprocating Compressor Valves in the pV-diagram

AU - Pichler, Kurt

AU - Lughofer, Edwin

AU - Pichler, Markus

AU - Buchegger, Thomas

AU - Klement, Erich

AU - Huschenbett, Matthias

PY - 2013/9

Y1 - 2013/9

N2 - This paper presents a novel data-driven approach to detecting broken reciprocating compressor valves that is based on the idea that a broken valve will affect the shape of the pressurevolume (pV) diagram. This effect can be observed when the valves are closed. To avoid disturbances due to the load control we concentrate on the expansion phase linearized using the logarithmic pV diagram. The gradient of the expansion phase serves as an indicator of the fault state of the valves. Since the gradient is also affected by the pressure conditions, they are used as an additional indicator. After feature extraction and removing offset in the feature space by solving an optimization problem, classification of different valve types can be achieved with one support vector machine classifer. The performance of the method was validated by analyzing real-world measurement data. Our results show a very high classification accuracy for varying compressor load and pressure conditions.

AB - This paper presents a novel data-driven approach to detecting broken reciprocating compressor valves that is based on the idea that a broken valve will affect the shape of the pressurevolume (pV) diagram. This effect can be observed when the valves are closed. To avoid disturbances due to the load control we concentrate on the expansion phase linearized using the logarithmic pV diagram. The gradient of the expansion phase serves as an indicator of the fault state of the valves. Since the gradient is also affected by the pressure conditions, they are used as an additional indicator. After feature extraction and removing offset in the feature space by solving an optimization problem, classification of different valve types can be achieved with one support vector machine classifer. The performance of the method was validated by analyzing real-world measurement data. Our results show a very high classification accuracy for varying compressor load and pressure conditions.

M3 - Conference proceedings

T3 - SMASIS

BT - Proceedings of the ASME 2013 Conference on Smart Materials, Adaptive Structures and Intelligent Systems (SMAIS 2013)

PB - ASME

ER -