Accurate performance prediction model for impact hammer developed using customized evolutionary algorithm

•The performance of two impact hammers were recorded.•RQD, UCS, and Schmidt hammer rebound values were measured along the tunnel.•Gene expression programming and particle swarm optimization were used for analysis.•The proposed model legitimately described performance under different circumstances.•T...

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Bibliographic Details
Published in:Tunnelling and underground space technology 2021-03, Vol.109, p.103773, Article 103773
Main Authors: Hojjati, Shahabedin, Tumac, Deniz, Jeon, Seokwon
Format: Article
Language:English
Subjects:
Algorithms
Compressive strength
Customization
Evolutionary algorithms
Gene expression
Gene expression programming
Hammers
Impact hammer
Impact prediction
Mathematical models
Nonlinear analysis
Parameters
Particle swarm optimization
Performance prediction
Prediction models
Regression analysis
Rock properties
Subway tunnels
Subways
Tunnel construction
Tunnels
Underground construction
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Summary:•The performance of two impact hammers were recorded.•RQD, UCS, and Schmidt hammer rebound values were measured along the tunnel.•Gene expression programming and particle swarm optimization were used for analysis.•The proposed model legitimately described performance under different circumstances.•The proposed model was successfully tested against some previously developed models. In past decades, impact hammers have played a key role in underground construction. Simply in Istanbul, impact hammers have been used to excavate more than 20 km of metro tunnels. Thus, determining the instantaneous breaking rate (IBR) of an impact hammer is attracting increasing attention. A number of IBR prediction models have been developed for impact hammers. However, there is still a demand for models that require a smaller number of easy-to-obtain rock properties as inputs and provide a reasonable level of accuracy, a wide range of applications, and high reliability. This study had the goal of developing such a prediction model based on an investigation of two subway tunnels built in Istanbul. In order to enhance the results generated by multiple linear regression analysis, a customized tool was developed for the non-linear analysis of a relatively large set of data collected for the present research. Gene expression programming (GEP) and particle swarm optimization (PSO) were merged to create a non-linear analysis tool. The GEP–PSO algorithm was trained using 80% of the available data, with the remaining 20% reserved to validate the results. The output of the algorithm was presented in the form of a mathematical equation that predicted the IBR using the uniaxial compressive strength, rock quality designation, Schmidt hammer rebound value, and machine power as input parameters. The predicted IBR values were in remarkable agreement with the recorded values. In order to verify the efficiency of the proposed prediction model, it was successfully tested against previously developed models for which input parameters were available. In addition, the proposed model was investigated under hypothetical circumstances to ensure that it legitimately described the performance changes due to changes in the input parameters. The model developed in this research is proposed as an accurate and reliable tool for predicting the performance of impact hammers over a wide application range.
ISSN:0886-7798
1878-4364
DOI:10.1016/j.tust.2020.103773