TY  - CHAP
AU  - Singh, Rajeev Kumar
AU  - Phanden, Rakesh Kumar
AU  - Jacsó, Ádám
AU  - Gupta, Ankur
ED  - Davim, J. Paulo
ED  - Sikarwar, Basant Singh
ED  - Phanden, Rakesh Kumar
ED  - Singh, Rajeev Kumar
TI  - Introduction to MEMS and Microfluidics
T2  - Advances in MEMS and Microfluidic Systems
PB  - IGI Global
CY  - Hershey (PA)
SN  - 9781668469545
T3  - Advances in Mechatronics and Mechanical Engineering, ISSN 2328-8205
PY  - 2023
SP  - 1
EP  - 10
PG  - 10
DO  - 10.4018/978-1-6684-6952-1.ch001
UR  - https://m2.mtmt.hu/api/publication/34022109
ID  - 34022109
N1  - Department of Mechanical Engineering, Amity University, Noida, India            
            Budapest University of Technology and Economics, Hungary            
            Indian Institute of Technology, Jodhpur, India            
            Export Date: 14 August 2023
AB  - Microelectromechanical systems (MEMS) refer to systems with characteristic length ranging between 1 µm and 1 mm, fabricated by integrated circuits batch processing technologies and unite mechanical and electrical components. MEMS devices and systems have wide applications in multifarious medical and industrial applications with worldwide market of billions of dollars. Examples of MEMS devices are accelerometers for automobile airbags; micropumps for inkjet printing, electronic cooling, and environmental testing; infrared detectors, digital light processing chip for projection display, etc. Microfluidics refers to fluid flow at a small size scale that causes change in fluid behavior. Microfluidic devices/systems handle a small quantity (micro- or nanoliter) of fluids (liquid or gas). The major application for handling fluids in microfluidics relates to chemical and biomedical analyses. The benefit of application of microfluidics in chemical and biomedical analysis is that they provide a total solution from sample utilization to display of analytical results.
LA  - English
DB  - MTMT
ER  - 

TY  - JOUR
AU  - Jacsó, Ádám
AU  - Szalay, Tibor
AU  - Sikarwar, Basant Singh
AU  - Phanden, Rakesh Kumar
AU  - Singh, Rajeev Kumar
AU  - Ramkumar, Janakarajan
TI  - Investigation of conventional and ANN-based feed rate scheduling methods in trochoidal milling with cutting force and acceleration constraints
JF  - INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY
J2  - INT J ADV MANUFACT TECHNOL
VL  - 127
PY  - 2023
SP  - 487
EP  - 506
PG  - 20
SN  - 0268-3768
DO  - 10.1007/s00170-023-11506-x
UR  - https://m2.mtmt.hu/api/publication/33834311
ID  - 33834311
N1  - Funding Agency and Grant Number: Budapest University of Technology and Economics; NRDI Fund (TKP2020 NC) under Ministry for Innovation and Technology [BME-NC]; European Commission [739592]; Hungarian National Research, Development and Innovation Office (NKFIH) [20171.3.1-VKE-201700029]; Hungarian State Eoetvoes Scholarship
            Funding text: Open access funding provided by Budapest University of Technology and Economics. The research reported in this paper and carried out at BME has been supported by the NRDI Fund (TKP2020 NC, Grant No. BME-NC) based on the charter of bolster issued by the NRDI Office under the auspices of the Ministry for Innovation and Technology. The work for this paper was supported by the European Commission through the H2020 project EPIC under grant No. 739592, the 2017-1.3.1-VKE-2017-00029 grant of the Hungarian National Research, Development and Innovation Office (NKFIH), and the Hungarian State Eoetvoes Scholarship.
AB  - In CNC milling, the feed rate scheduling is a frequently used method to increase machining quality and efficiency. Among the benefits of feed rate scheduling, this paper focuses on controlling the tool load and optimizing the machining time. Although the advantages of feed rate scheduling are undeniable, some areas remain still to be addressed. In order to control the tool load, geometric methods are often used, which are based on keeping a specific parameter, such as chip thickness or material removal rate (MRR) constant. However, a high level of tool load control can only be provided if cutting force models or experimental-based techniques are used. Besides traditional methods, this paper presents an artificial neural network (ANN)-based feed rate scheduling method to keep the tool load constant, using data gained by preliminary cutting experiments. A case study demonstrates that a significantly higher level of tool load control can be achieved with this method as compared to the geometric models. Besides controlling the tool load, the present feed rate scheduling method also addresses the consideration of acceleration limits which is of great importance for practical uses. The application of feed rate scheduling in trochoidal milling is also discussed in detail in this paper. This area has not received enough attention, as due to the limited fluctuation of cutter engagement, the tool load was considered as well-controlled. However, experiments have shown that in the case of trochoidal milling, the introduction of feed rate scheduling can still further increase the machining efficiency. Using the developed ANN-based feed rate scheduling method, significant progress could be made as compared to conventional technologies in controlling the cutting force and optimizing the machining time. In the present case study, a reduction of 50% in machining time was achievable by adjusting the feed rate without increasing the peak value of cutting force.
LA  - English
DB  - MTMT
ER  - 

TY  - JOUR
AU  - Jacsó, Ádám
AU  - Ladó, Zoltán
AU  - Phanden, Rakesh Kumar
AU  - Sikarwar, Basant Singh
AU  - Singh, Rajeev Kumar
TI  - Bézier curve-based trochoidal tool path optimization using stochastic hill climbing algorithm
JF  - MATERIALS TODAY: PROCEEDINGS
J2  - MATER TOD PROC
VL  - 78
PY  - 2023
IS  - Part 3
SP  - 633
EP  - 639
PG  - 7
SN  - 2214-7853
DO  - 10.1016/j.matpr.2022.12.056
UR  - https://m2.mtmt.hu/api/publication/33539414
ID  - 33539414
N1  - Department of Manufacturing Sciences and Engineering, Faculty of Mechanical Engineering, Budapest University of Technology and Economics, Budapest, Hungary            
            Department of Mechanical Engineering, Amity School of Engineering & Technology, Amity University, Uttar Pradesh, Noida, India  
            Correspondence Address: Jacso, A.; Department of Manufacturing Sciences and Engineering, Hungary; email: jacso.adam@gpk.bme.hu
AB  - Trochoidal milling is a widely used technique in high-speed machining. In the recent period, several theoretical and experimental studies have been performed to analyze the cutting process in trochoidal milling of slot-like geometries. However, these works typically focused only on cycloid- and circular-shaped trochoidal strategies and did not consider the possibilities of path shape optimization. This is because optimizing the trochoidal tool path is a double challenge: (1) modelling of material removal process is necessary to satisfy the geometrical and technological conditions, and (2) the relationship between tool path shape and machining efficiency is highly complex; therefore, direct optimization solutions cannot be applied.

This paper presents a new Bézier curve-based tool path modelling technique and a new stochastic hill climbing algorithm-based optimization method to increase the efficiency of trochoidal strategy. During the tool path shape optimization, the limiting factors of cutter engagement and path curvature radius were also considered to meet the criteria of high-speed machining. The simulation experiments proved that the machining efficiency could be increased significantly by optimizing the trochoidal tool path by up to 40%, compared to the traditional cycloid strategy. The cutting experiments verified that the tool load remained well controlled, and productivity could be improved without increasing the tool load. The paper also discusses the appropriate settings to ensure the best functioning of the stochastic hill climbing algorithm. The industrial application of the developed algorithm can result in significant cost, energy and time savings for manufacturers when machining slot-like geometries.
LA  - English
DB  - MTMT
ER  - 

TY  - JOUR
AU  - Jacsó, Ádám
AU  - Sikarwar, Basant Singh
AU  - Phanden, Rakesh Kumar
AU  - Singh, Rajeev Kumar
AU  - Ramkumar, Janakarajan
AU  - Sahu, Govind N.
TI  - Optimisation of tool path shape in trochoidal milling using B-spline curves
JF  - INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY
J2  - INT J ADV MANUFACT TECHNOL
VL  - 121
PY  - 2022
SP  - 3801
EP  - 3816
PG  - 16
SN  - 0268-3768
DO  - 10.1007/s00170-022-09527-z
UR  - https://m2.mtmt.hu/api/publication/32915679
ID  - 32915679
N1  - Funding Agency and Grant Number: Budapest University of Technology and Economics; NRDI Fund [BME-NC]; Ministry for Innovation and Technology; European Commission [739592]; Hungarian National Research, Development and Innovation Office (NKFIH) [2017-1.3.1-VKE-2017-00029]; Hungarian State Eotvos Scholarship
            Funding text: Open access funding provided by Budapest University of Technology and Economics. The research reported in this paper and carried out at BME has been supported by the NRDI Fund (TKP2020 NC, grant no. BME-NC) based on the charter of bolster issued by the NRDI Office under the auspices of the Ministry for Innovation and Technology. Work for this paper was supported by the European Commission through the H2020 project EPIC under grant no. 739592, the 2017-1.3.1-VKE-2017-00029 grant of the Hungarian National Research, Development and Innovation Office (NKFIH), and the Hungarian State Eotvos Scholarship.
LA  - English
DB  - MTMT
ER  - 

TY  - JOUR
AU  - Geier, Norbert
AU  - Póka, György
AU  - Jacsó, Ádám
AU  - Pereszlai, Csongor
TI  - A method to predict drilling-induced burr occurrence in chopped carbon fibre reinforced polymer (CFRP) composites based on digital image processing
JF  - COMPOSITES PART B-ENGINEERING
J2  - COMPOS PART B-ENG
VL  - 242
PY  - 2022
PG  - 9
SN  - 1359-8368
DO  - 10.1016/j.compositesb.2022.110054
UR  - https://m2.mtmt.hu/api/publication/32897330
ID  - 32897330
N1  - Export Date: 4 August 2022            
            CODEN: CPBEF            
            Correspondence Address: Geier, N.; Budapest University of Technology and Economics, Műegyetem rkp. 3, Hungary; email: geier.norbert@gpk.bme.hu
AB  - Mechanical drilling-induced burr in carbon fibre reinforced polymer (CFRP) composites is one of the most significant macro-geometrical failures of CFRP composites; nevertheless, burr prediction in quasi-randomly oriented chopped fibre reinforced composites is not supported yet. To explore this issue, the main aim of the present research work was to develop a method to predict drilling-induced burrs in chopped CFRPs based on digital image processing. First, an indexable light source captured digital images of a chopped CFRP plate in different lighting conditions. Then, the fibre orientation of each visible chopped fibre group was determined in each image through digital image processing algorithms. These images were then associated based on the superposition principle. Finally, the burr-dangerous regions were predicted by the local properties of chopped fibres. The prediction accuracy of the algorithm is tested by drilling experiments in chopped CFRP plates using solid carbide drills. The experimental results show that the mechanical drilling-induced burr prediction accuracy is 64–97%. By applying the proposed method, burrs can be estimated without machining experiments in chopped CFRPs.
LA  - English
DB  - MTMT
ER  - 

TY  - CHAP
AU  - Jacsó, Ádám
AU  - Ladó, Zoltán
ED  - Barabás, István
TI  - Trochoidális szerszámpályák tervezése Bézier-görbék alkalmazásával. Trochoidal tool path planning by using Bézier curves
TS  - Trochoidal tool path planning by using Bézier curves
T2  - XXX. Nemzetközi Gépészeti Konferencia - OGÉT 2022
PB  - Erdélyi Magyar Műszaki Tudományos Társaság (EMT)
C1  - Kolozsvár
T3  - Nemzetközi Gépészeti Találkozó (OGÉT), ISSN 2068-1267 ; 30.
PY  - 2022
SP  - 53
EP  - 56
PG  - 4
UR  - https://m2.mtmt.hu/api/publication/32797003
ID  - 32797003
AB  - A  trochoidális  marási  technológia  rendkívül  hatékonyan  alkalmazható  a  horonyszerű  alaksajátosságok nagysebességű  megmunkálására.   Az   elmúlt   évtizedekben   számos   tanulmány   született   a   hagyományos pályaalakok  kísérleti  és  elméleti  vizsgálatával  kapcsolatosan,  azonban  a  probléma  komplexitása  miatt  kevés figyelem fordult a pálya alakjának optimalizálására. A cikkben egy olyan Bézier-görbe alapú új szerszámpálya modellezési technika kerül bemutatásra, amely segítségével a nagysebességű megmunkálás követelményeinek kielégítése mellett lehetőség nyílik a termelékenység adott szerszámterhelés melletti maximalizálására is.
LA  - Hungarian
DB  - MTMT
ER  - 

TY  - CHAP
AU  - Balázs, Barnabás Zoltán
AU  - Jacsó, Ádám
AU  - Takács, Márton
ED  - Barabás, István
TI  - Trochoidális marás alkalmazása edzett acél mikromegmunkálása esetén
T2  - XXX. Nemzetközi Gépészeti Konferencia - OGÉT 2022
PB  - Erdélyi Magyar Műszaki Tudományos Társaság (EMT)
C1  - Kolozsvár
T3  - Nemzetközi Gépészeti Találkozó (OGÉT), ISSN 2068-1267 ; 30.
PY  - 2022
SP  - 355
EP  - 358
PG  - 4
UR  - https://m2.mtmt.hu/api/publication/32794446
ID  - 32794446
LA  - Hungarian
DB  - MTMT
ER  - 

TY  - JOUR
AU  - Phanden, Rakesh Kumar
AU  - Aditya, S.V.
AU  - Sheokand, Aaryan
AU  - Goyal, Kapil Kumar
AU  - Gahlot, Pardeep
AU  - Jacsó, Ádám
TI  - A state-of-the-art review on implementation of digital twin in additive manufacturing to monitor and control parts quality
JF  - MATERIALS TODAY: PROCEEDINGS
J2  - MATER TOD PROC
VL  - 56
PY  - 2022
SP  - 88
EP  - 93
PG  - 6
SN  - 2214-7853
DO  - 10.1016/j.matpr.2021.12.217
UR  - https://m2.mtmt.hu/api/publication/32572411
ID  - 32572411
AB  - Both, Additive Manufacturing (AM) and Digital Twin (DT) are emerging technologies. DT is helping AM in process simulation, monitoring and controlling as well as to develop insights on process parameters relation to achieve high parts quality. Therefore, the implementation of DT technology in AM is highly desirable and fruitful. In the current state, DT application on AM has been explored by various researchers for education, manufacturing, maintenance and quality area from the theoretical and practical viewpoints. This paper presents the state-of-the-art literature review on the implementation of DT in AM to monitor and control the parts quality from theoretical and practical viewpoints. Based on the literature, a representation scheme has been extracted to implement DT in AM successfully, and various future research directions are given.
LA  - English
DB  - MTMT
ER  - 

TY  - JOUR
AU  - Najm, Sherwan Mohammed
AU  - Paniti, Imre
AU  - Trzepieciński, T
AU  - Nama, S A
AU  - Viharos, Zsolt János
AU  - Jacsó, Ádám
TI  - Parametric Effects of Single Point Incremental Forming on Hardness of AA1100 Aluminium Alloy Sheets
JF  - MATERIALS
J2  - MATERIALS
VL  - 14
PY  - 2021
IS  - 23
PG  - 19
SN  - 1996-1944
DO  - 10.3390/ma14237263
UR  - https://m2.mtmt.hu/api/publication/32514462
ID  - 32514462
N1  - Cited By :8            
            Export Date: 7 December 2022            
            Correspondence Address: Najm, S.M.; Department of Manufacturing Science and Engineering, Műegyetem rkp 3, Hungary; email: sherwan.mohammed@gpk.bme.hu
AB  - When using a unique tool with different controlled path strategies in the absence of a punch and die, the local plastic deformation of a sheet is called Single Point Incremental Forming (SPIF). The lack of available knowledge regarding SPIF parameters and their effects on components has made the industry reluctant to embrace this technology. To make SPIF a significant industrial application and to convince the industry to use this technology, it is important to study mechanical properties and effective parameters prior to and after the forming process. Moreover, in order to produce a SPIF component with sufficient quality without defects, optimal process parameters should be selected. In this context, this paper offers insight into the effects of the forming tool diameter, coolant type, tool speed, and feed rates on the hardness of AA1100 aluminium alloy sheet material. Based on the research parameters, different regression equations were generated to calculate hardness. As opposed to the experimental approach, regression equations enable researchers to estimate hardness values relatively quickly and in a practicable way. The Relative Importance (RI) of SPIF parameters for expected hardness, determined with the partitioning weight method of an Artificial Neural Network (ANN), is also presented in the study. The analysis of the test results showed that hardness noticeably increased when tool speed increased. An increase in feed rate also led to an increase in hardness. In addition, the effects of various greases and coolant oil were studied using the same feed rates; when coolant oil was used, hardness increased, and when grease was applied, hardness decreased.
LA  - English
DB  - MTMT
ER  - 

TY  - THES
AU  - Jacsó, Ádám
TI  - Egyenletes szerszámterhelést biztosító szerszámpályák tervezése zsebek megmunkálásához
PB  - Budapesti Műszaki és Gazdaságtudományi Egyetem
PY  - 2021
SP  - 159
UR  - https://m2.mtmt.hu/api/publication/32080937
ID  - 32080937
LA  - Hungarian
DB  - MTMT
ER  -