Virtual Sensors for On-line Wheel Wear and Part Roughness Measurement in the Grinding Process

Arriandiaga, Ander; Portillo, Eva; Sánchez, J.A.; Cabanes, Itziar; Pombo, I.

doi:10.3390/s140508756

Cited by 20 publications

(13 citation statements)

References 24 publications

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“…Besides, most of the published works provide a solution for a given wheel-workpiece combination. Although there are few cases where solutions for more than one wheel are provided, in few works the solution can be generalized to new wheels that have not been used during the training process of the ANN [11]. This is the main reason why industrial application of ANN is not widely extended in grinding yet.…”

Section: Introductionmentioning

confidence: 93%

“…Thus, for analysing the influence of the time characteristics and the number of points, three different net configurations (HU-D) have been selected (5HU-10D, 12HU-10D and 15HU-10D) due to the complexity of the task and experience gained from previous works [11]. These ANN configurations are trained ten times with time steps set to 5 mm 3 /mm (time series 1, see Table 2), 10 mm 3 /mm (time series 2, see Table 2) and 15 mm 3 /mm (time series 3, see Table 2).…”

Section: Time Characteristics Versus Number Of Pointsmentioning

confidence: 99%

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A new approach for dynamic modelling of energy consumption in the grinding process using recurrent neural networks

Arriandiaga

Portillo

Sánchez

et al. 2015

Neural Comput & Applic

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Grinding is a critical machining process because it produces parts of high precision and high surface quality. Due to the semi-artisan production of the wheel, it is not possible to know in advance the performance of the wheel. One of the most useful parameters to characterize the grinding process is the specific grinding energy, which varies with the wear of the grinding wheel during its lifecycle. Thus, it would be useful to model the specific grinding energy in order to get information about the performance of the wheel before buying it. Unlike the typical applications of time series forecasting, in this work, a totally different issue is presented: the prediction of new and complete time series bounded in time without initial or historic values. In this context, an analysis of the effect of the time characteristics and the number of points of the time series on the prediction capabilities of the ANN is presented. The results of the analysis show that 200 points are enough to predict a complete time series up to 2000 mm 3 /mm of specific volume of material removed. Actually, it is shown that modelling the evolution of the grinding specific energy up to 2000 mm 3 /mm is possible. The net shows good capability to generalize to new grinding conditions, with errors below 23.65 %, and to new wheel characteristics, with errors below 20.01 %, which are satisfactory from the grinding process perspective.

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Section: Introductionmentioning

confidence: 93%

Section: Time Characteristics Versus Number Of Pointsmentioning

confidence: 99%

A new approach for dynamic modelling of energy consumption in the grinding process using recurrent neural networks

Arriandiaga

Portillo

Sánchez

et al. 2015

Neural Comput & Applic

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“…Agustina et al evaluated the surface roughness obtained during robot-assisted polishing processes by the analysis of acoustic emission signals in the frequency domain [10] . Arriandiaga et al developed a virtual sensor for online monitoring of wheel wear and part roughness in the grinding process [11] . Santos et al investigated the relevance for the detection of surface and subsurface cracks in ceramic tiles by using ultrasonic techniques [12] .…”

Section: Introductionmentioning

confidence: 99%

Estimation of the surface roughness of K9 optical glass in precision grinding using the brittle material removal fraction based on an improved image processing algorithm

Jiang¹,

Wang²

2016

Insight

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Estimation of the surface roughness of K9 optical glass in precision grinding using the brittle material removal fraction based on an improved image processing algorithm In optical glass grinding, material removal of the workpiece surface generally consists of a simultaneous brittle and ductile removal mode. In previous work, the area fraction of brittle material removal on a machined surface, termed the brittle material removal fraction (BRF), was used to sense the surface roughness of optical glass during ultrasonic vibration-assisted grinding (UAG). In this work, to verify the significance of the BRF on material removal during traditional machining of optical glass, the BRF of K9 glass in precision grinding (PG) was investigated. By analysing the characteristics of a micro-topography image of the machined surface, an improved image processing algorithm was developed to calculate the BRF in PG, based on the previous image processing algorithm for UAG. A series of PG experiments were conducted to estimate the influence of machining conditions, including cutting depth, wheel speed and feed rate, on the BRF. Surface roughness and grinding forces were also measured to investigate the relationships between the BRF, surface quality and process parameters in PG of K9 glass. Experimental results show the improved image processing algorithm is valid to obtain the BRF of optical glass during PG and the BRF is also a reasonable variable to sense surface quality during PG of optical glass.

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“…Ito et al [8] used a laser displacement sensor (LDS) to measure the surface form of ceramics parts. Due to the limitation of its accuracy, however, this kind of method is commonly used for form measurement but not dimension inspection, such as in [9,10,11,12]. The main reason is understandable as the coordinates offered by the NC machines are less accurate, and thus the final measuring accuracy is not comparable to that of the CMM yet.…”

Section: Introductionmentioning

confidence: 99%

A Fast and in-Situ Measuring Method Using Laser Triangulation Sensors for the Parameters of the Connecting Rod

Zhong

2016

Sensors

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The connecting rod is a critical part inside the marine engine. The inspection of its important parameters is directly related to the assembly and quality of the marine engine. A coordinate measuring machine (CMM) is a conventional choice to measure the parameters of a connecting rod. However, CMM requires significant resources in time and cost, which leads researchers into in-situ measurement. This article presents a fast and in-situ measuring method by using a laser-based measuring head. Two measuring strategies are adopted in the inspection process. For positional measurements (such as the hole–center distance), whose accuracy requirement is generally low, the coordinate system of the numerical control (NC) machine is combined with the measuring head to acquire the positional parameters. For dimensional measurements (such as inner diameters), whose accuracy requirement is rather high, the NC machine is used just as transportation. Note that the measuring head has the ability to perform the dimension inspection independently. The accuracy of the measuring head is high enough to meet the dimensional accuracy requirements. Experiments are performed to validate the proposed method. The measuring error of the inner diameters is from 5 μm to 7 μm. The measuring error of hole–center distance is within 15 μm. The measurement of all these parameters can be done within 1 min.

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Virtual Sensors for On-line Wheel Wear and Part Roughness Measurement in the Grinding Process

Cited by 20 publications

References 24 publications

A new approach for dynamic modelling of energy consumption in the grinding process using recurrent neural networks

A new approach for dynamic modelling of energy consumption in the grinding process using recurrent neural networks

Estimation of the surface roughness of K9 optical glass in precision grinding using the brittle material removal fraction based on an improved image processing algorithm

A Fast and in-Situ Measuring Method Using Laser Triangulation Sensors for the Parameters of the Connecting Rod

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