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Journal articles on the topic 'High-Turning'

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1

Drlička, R., V. Kročko, and M. Matúš. "Machinability improvement using high-pressure cooling in turning." Research in Agricultural Engineering 60, Special Issue (2014): S70—S76. http://dx.doi.org/10.17221/38/2013-rae.

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Process fluids are used primarily for their cooling and lubricating effect in machining. Many ways to improve their performance have been proposed; the analysis of some of them is provided in the paper. The effect of high pressure cooling has been investigated with regard to chip formation and tool life. Standard and for high pressure application particularly designed indexable cutting inserts were used with fluid pressure 1.5 and 7.5 MPa. The pressure effect on tool life at different feed rates was observed as well. Not each cooling pressure value or machined material showed favourable chip formation. Tool life though has improved significantly while machining with a lower feed rate. 
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2

Ruchti, Randy, and Mitchell Wayne. "Turning High Schoolers into High-Energy Physicists." Optics and Photonics News 19, no. 11 (2008): 16. http://dx.doi.org/10.1364/opn.19.11.000016.

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3

Crocker, J. C. "Turning Away from High Symmetry." Science 327, no. 5965 (2010): 535–36. http://dx.doi.org/10.1126/science.1184457.

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4

SHIBATA, Toru, and Toru MIYASAKA. "Development of page turning roller for high reliable page turning machine." Transactions of the JSME (in Japanese) 84, no. 860 (2018): 17–00448. http://dx.doi.org/10.1299/transjsme.17-00448.

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5

SHIBATA, Toru, and Toru MIYASAKA. "Study on Page Turning Machine for High Reliable Page Turning Process." Proceedings of the Conference on Information, Intelligence and Precision Equipment : IIP 2016 (2016): D—1–2. http://dx.doi.org/10.1299/jsmeiip.2016.d-1-2.

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6

Vasilko, Karol. "Integrated Tool for High-Feed Turning." Manufacturing Technology 19, no. 5 (2019): 880–85. http://dx.doi.org/10.21062/ujep/388.2019/a/1213-2489/mt/19/5/880.

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7

UTO, Seiichi, Takashi UEDA, Eiji SHAMOTO, and Yuki Hatano. "High speed turning in titanium alloy." Proceedings of Conference of Tokai Branch 2018.67 (2018): 704. http://dx.doi.org/10.1299/jsmetokai.2018.67.704.

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8

Nikolaenko, A. A. "Thermodynamic model of high-speed turning." Russian Engineering Research 35, no. 5 (2015): 339–43. http://dx.doi.org/10.3103/s1068798x15050184.

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9

Zhang, Chang-Ming, An-Le Mu, Yong-Xin Wang, Yun Wang, and Yu Zhang. "Influence of Turning Parameters on Turning Performance of Ultra-High Strength Steel." Integrated Ferroelectrics 209, no. 1 (2020): 110–18. http://dx.doi.org/10.1080/10584587.2020.1728817.

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10

Uhlmann, Eckart, Karsten Flögel, Michael Kretzschmar, and Fabian Faltin. "Abrasive Waterjet Turning of High Performance Materials." Procedia CIRP 1 (2012): 409–13. http://dx.doi.org/10.1016/j.procir.2012.04.073.

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11

Chen, Hua-Feng. "Research on high power servo turning control." IOP Conference Series: Earth and Environmental Science 508 (July 1, 2020): 012165. http://dx.doi.org/10.1088/1755-1315/508/1/012165.

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12

KIMURA, Hiroyuki, Tokio KITAHARA, and Kimiyuki Mitsui. "4220 Turning using High-Speed Micro-spindle." Proceedings of the JSME annual meeting 2007.7 (2007): 343–44. http://dx.doi.org/10.1299/jsmemecjo.2007.7.0_343.

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13

Sørby, Knut, and Einar Sundseth. "High-accuracy turning with slender boring bars." Advances in Manufacturing 3, no. 2 (2015): 105–10. http://dx.doi.org/10.1007/s40436-015-0112-7.

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14

MURAKI, Toshiyuki, Toshihito OKUDA, and Hiromasa YAMAMOTO. "High Speed Turning of High-Temperature Alloys by using INTEGREX." Proceedings of The Manufacturing & Machine Tool Conference 2004.5 (2004): 145–46. http://dx.doi.org/10.1299/jsmemmt.2004.5.145.

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15

Du, Guo Chen, Ying Chen, Jin Feng Zhang, and Zhi Zhen Wei. "Finite Element Simulation of High-Speed Hard Turning." Advanced Materials Research 308-310 (August 2011): 1465–70. http://dx.doi.org/10.4028/www.scientific.net/amr.308-310.1465.

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The results reported in this paper pertain to the simulation of high speed hard turning when using the finite element method. In recent years high speed hard turning has emerged as a very advantageous machining process for cutting hardened steels. Among the advantages of this modern turning operation are final product quality, reduced machining time, lower cost and environmentally friendly characteristics. For the finite element modelling a commercial programme, namely the Third Wave Systems AdvantEdge, was used. This programme is specially designed for simulating cutting operations, offering to the user many designing and analysis tools. In the present analysis orthogonal cutting models are proposed, taking several processing parameters into account; the models are validated with experimental results from the relevant literature and discussed. Additionally, oblique cutting models of high speed hard turning are constructed and discussed. From the reported results useful conclusions may be drawn and it can be stated that the proposed models can be used for industrial application.
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16

He, Juan Juan, Hong Jie Pei, Yang Chu, Shi Wei Wang, and Gui Cheng Wang. "MQL Application in High-Speed Turning Bearing Steel." Applied Mechanics and Materials 490-491 (January 2014): 306–10. http://dx.doi.org/10.4028/www.scientific.net/amm.490-491.306.

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Green high-speed cutting is one of the main development directions of advanced processing technology.The defects of the traditional cooling and lubrication conditions and the deficiencies of external MQL (Minimum Quantity Lubrication) were analyzed in this paper. A new way of cooling and lubrication named internal MQL was highlighted, and an internal MQL system applied to turning was researched and designed. By high-speed turning of bearing steel GCr15 under different cooling lubrication conditions as dry turning, external and internal MQL, the comparative study of cutting force and surface roughness was carried out systematically. The results showed that the internal MQL has a comparative advantage, showing a good application prospect.
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17

Albagachiev, A. Yu, A. S. Krasko, and E. S. Stramtsova. "Optimization of the High-Speed Turning of High-Temperature Nickel Alloy." Russian Engineering Research 38, no. 10 (2018): 776–79. http://dx.doi.org/10.3103/s1068798x18100040.

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18

MATSUMURA, Taisuke, and Takahiro SHIRAKASHI. "204 High Precision and High Productivity Turning Based on Error Prediction." Proceedings of Yamanashi District Conference 2007 (2007): 50–51. http://dx.doi.org/10.1299/jsmeyamanashi.2007.50.

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19

Wada, Tadahiro, Junsuke Fujiwara, and Shinsaku Hanasaki. "Tool Wear in High Speed Turning of SCr420." Journal of the Japan Society of Powder and Powder Metallurgy 46, no. 9 (1999): 935–41. http://dx.doi.org/10.2497/jjspm.46.935.

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20

Adesta, Erry Yulian Triblas, and Muataz H. F. Al Hazza. "Machining Time Simulation in High Speed Hard Turning." Advanced Materials Research 264-265 (June 2011): 1102–6. http://dx.doi.org/10.4028/www.scientific.net/amr.264-265.1102.

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High speed hard turning is an advanced manufacturing technology that reduces the machining time because of two reasons; reducing the manufacturing steps and increasing the cutting speed. This new approach needs an economical justification; one of the main economical factors is the machining time. The machining time was breaking down into three main parts; productive time, non productive time, and preparation time. By using matlab Simulink, a new program was developed for machining time allowing the manufacturer to find rapidly the values of cutting time parameters and gives the management the opportunity to modify the processing parameters to achieve the optimum time by using the optimum cutting parameters. Table 1: Nomenclature d Depth of cut M T total machining time pmv t Total movement time D Work piece diameter h t handling time pch t Total Tool changing time f Feed rate tc t tool changing time pre t Total preparing time z e Engagement distance on Z-axis ch t Tool changing time per piece, prg t Programming time x e Degagement distance on X-axis am t Machine allowance time su t Set up time k Number of passes ao t Operator allowance time sum t Machine set up L Tool life a t Allowance time sut t Tool set up l Work piece length o t Tool movement at the rapid speed suw t Work piece set up N Spindle speed oA t From zero point to cutting point TH Tool hardness tool n No. of tool posts in the turret p t Total productive time o X tidy of the O t point o1 p Initial position of the turret. o Z = abciss of the O t point w Work piece weigh o2 p Position of the used tool c V Cutting speed c w Width of cutting speed r Rotation speed of the turret f V Feeding speed tool n no. of tool in the turret c t Cutting time o V Rapid speed speed r : Turret rotation speed
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21

Balaji, J. H., V. Krishnaraj, and S. Yogeswaraj. "Investigation on High Speed Turning of Titanium Alloys." Procedia Engineering 64 (2013): 926–35. http://dx.doi.org/10.1016/j.proeng.2013.09.169.

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22

Yang, Peng, Ke Tang, and Xin Yao. "Turning High-Dimensional Optimization Into Computationally Expensive Optimization." IEEE Transactions on Evolutionary Computation 22, no. 1 (2018): 143–56. http://dx.doi.org/10.1109/tevc.2017.2672689.

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23

Iuliano, L., L. Settineri, and A. Gatto. "High-speed turning experiments on metal matrix composites." Composites Part A: Applied Science and Manufacturing 29, no. 12 (1998): 1501–9. http://dx.doi.org/10.1016/s1359-835x(98)00105-5.

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24

Szweda, Roy. "High-power diode lasers turning up the heat." III-Vs Review 14, no. 6 (2001): 48–51. http://dx.doi.org/10.1016/s0961-1290(01)80531-7.

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25

Bigerelle, M., A. Van Gorp, A. Gautier, and P. Revel. "Multiscale morphology of high-precision turning process surfaces." Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 221, no. 10 (2007): 1485–97. http://dx.doi.org/10.1243/09544054jem777.

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The characterization of functional surfaces is done mainly by roughness which can be quantified by many parameters. In order to select relevant roughness parameters, a multiscale discriminant method is proposed and applied to characterize high-precision turned surfaces. First, surfaces are characterized by a single roughness parameter and secondly by a pair of roughness parameters. In all cases, the most relevant evaluation length is also determined for each parameter. The results obtained on four different samples show that the most relevant roughness parameter is Rk estimated on a 10μm evaluation length. The best pair of parameters is Δa and Ri, estimated respectively on 20μm and 100μm evaluation lengths. Rk well characterizes the microroughness, which seems to be mainly representative of the roughness of high-precision machined surfaces. However, only multiscale analyses with a pair of roughness parameters can characterize both the macroscopic and microscopic morphologies of machined surfaces.
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26

Mu¨ller, Bernhard, Ulrich Renz, Stefan Hoppe, and Fritz Klocke. "Radiation Thermometry at a High-Speed Turning Process." Journal of Manufacturing Science and Engineering 126, no. 3 (2004): 488–95. http://dx.doi.org/10.1115/1.1763188.

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A fiber-optic two-color pyrometer with high spatial and temporal resolution has been applied to measure temperatures at an external turning process. Different measurement positions have been realized at the chip and the workpiece. The measurements have been performed at three different workpiece materials: carbon steel AISI 1045, aluminum alloy AA 7075, and titanium alloy Ti6Al4V. The influences of different parameters like cutting speed, feed, and position of the measurement spot on the temperatures have been investigated. The cutting speed has been increased from conventional values up to 100 m/s for AISI 1045, 117 m/s for AA 7075, and 10 m/s for Ti6Al4V. Additionally, a review of radiation thermometry techniques and applications regarding time resolved temperature measurements in metal cutting will be presented.
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27

Javam, Navid. "The Study of High Speed Turning Using MQL." Indian Journal of Science and Technology 6, no. 2 (2013): 1–5. http://dx.doi.org/10.17485/ijst/2013/v6i2.15.

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28

Zhu, Zhaolong, Dietrich Buck, Xiaolei Guo, Mats Ekevad, Pingxiang Cao, and Zhenzeng Wu. "Machinability investigation in turning of high density fiberboard." PLOS ONE 13, no. 9 (2018): e0203838. http://dx.doi.org/10.1371/journal.pone.0203838.

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29

Singh, N., and S. R. Prabhakar. "Performance Appraisal of High Speed Steel Turning Tools." Materials Technology 18, no. 4 (2003): 218–24. http://dx.doi.org/10.1080/10667857.2003.11753046.

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30

Faizi Al-H, Muataz Hazza, Erry Yulian T Adesta, Afifah Mohd Ali, Delvis Agusman, and Mohammad Yuhan Supr. "Energy Cost Modeling for High Speed Hard Turning." Journal of Applied Sciences 11, no. 14 (2011): 2578–84. http://dx.doi.org/10.3923/jas.2011.2578.2584.

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31

Erenkov, O. Yu, and M. A. Sigitova. "New Concept for High-Throughput Turning of Polymers." Chemical and Petroleum Engineering 51, no. 9-10 (2016): 636–39. http://dx.doi.org/10.1007/s10556-016-0099-3.

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32

Engstrom, Del, and Lorri Engstrom. "Turning a Department into a High-Performing Team." Department Chair 28, no. 2 (2017): 11–12. http://dx.doi.org/10.1002/dch.30158.

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33

Song, Bo, Wing Ng, Toyotaka Sonoda, and Toshiyuki Arima. "Loss Mechanisms of High-Turning Supercritical Compressor Cascades." Journal of Propulsion and Power 24, no. 3 (2008): 416–23. http://dx.doi.org/10.2514/1.30579.

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34

Luo, Meng, Li Qiu Zhang, and Ming Chen. "Machinability and Tool Wear Behavior in Turning High Nickel-Base Alloy-G3." Advanced Materials Research 69-70 (May 2009): 485–89. http://dx.doi.org/10.4028/www.scientific.net/amr.69-70.485.

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High nickel-base alloy, such as G3, is famous for its corrosion resistant, high intensity and other characteristic, which is popular in petroleum extraction and other heavy industry. However its poor machinability is a big obstacle to launching this material in its application. This paper introduces the poor machinability and tool wear behavior in turning high nickel-base alloy-G3. Based on rough and finished turning, turning experiments were carried out according on cutting speed, cutting depth, coolant and etc. some improved processes were suggested. This paper will be beneficial and guidable in turning high nickel-base alloy and other similar high nickel-base alloy or stainless steel.
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35

SULAIMAN, Mohd Amri, Che Hasan CHE HARON, Jaharah Abd GHANI, Effendi MOHAMAD, and Teruaki ITO. "2306 Tool Performance of Uncoated Carbide in High-speed Turning of Titanium Ti-6Al-4V ELI." Proceedings of Design & Systems Conference 2014.24 (2014): _2306–1_—_2306–10_. http://dx.doi.org/10.1299/jsmedsd.2014.24._2306-1_.

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36

Pawade, Raju, Avinash Khadtare, Dhanashree Dhumal, and Vishal Wankhede. "Machinability Assessment in High Speed Turning of High Strength Temperature Resistant Superalloys." Journal of Advanced Manufacturing Systems 18, no. 04 (2019): 595–623. http://dx.doi.org/10.1142/s021968671950032x.

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The paper discusses the effect of cutting parameters and cutting tool material on chip compression ratio, cutting forces and surface roughness in turning of high strength temperature resistant superalloys (HSTR). The experiments were performed in dry cutting environment on precision CNC lathe with fixed depth of cut of 0.5[Formula: see text]mm. Analytical model is developed to determine chip segmentation frequency, shear angle and shear strain and it is correlated with the machining parameters. The machinability of the selected superalloys is assessed in terms of cutting force, chip compression ratio and surface roughness. It is found from the experimental analysis cutting force magnitude is less at higher cutting speed for all the superalloys. Chip compression ratio is found maximum in case of Inconel 718 due to precipitation hardening of alloy and followed by Inconel 600 and Inconel 800. The chip segmentation frequency is high at lower cutting speed for Inconel 600 due significant strain hardening. Serrated chips are produced during machining of three selected superalloys and it is found that serrated tooth spacing decreases with cutting speed. Shear plane angle increases on cutting speed increases which effect tool workpiece contact length during machining resulted thin, short and snarled chips was produced. From analytical modeling it shows that shear strain decreases with cutting speed which indicate that at higher cutting speed material deformed elastically than plastically. The effect of cutting tool material is observed on the surface roughness. The better surface finish is obtained with coated carbide inserts as compared to ceramic inserts for all the selected superalloys. However, Inconel 800 shows higher surface roughness due to combination of (Ni–Cr–Fe) alloying element which is responsible for carburization of surface layer during machining.
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37

Wang, Xue Feng, Shi Gang Wang, and Zi Jing Wu. "High Temperature Alloy of Turning Processing Characteristic and Process Analysis." Materials Science Forum 800-801 (July 2014): 71–75. http://dx.doi.org/10.4028/www.scientific.net/msf.800-801.71.

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High temperature alloy is the key hot end parts' material, which is often used in the modern aircraft, spacecraft and the rocket engines, as well as naval vessels and industry gas turbine. And it's also used in the nuclear reactor, chemical equipment, coal conversion technologies etc. as the very important high temperature structural materials. High temperature alloy of turning processing is the technical difficulties in mechanical cutting work, this paper introduces the high temperature alloy turning processing features, turning processing tool, cutting parameters, the choice of the cutting fluid and machining notice proceedings, etc.
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38

Liu, Zhan Qiang, Peng Zhang, Peng Guo, and Xing Ai. "Surface Roughness in High Feed Turning with Wiper Insert." Key Engineering Materials 375-376 (March 2008): 406–10. http://dx.doi.org/10.4028/www.scientific.net/kem.375-376.406.

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Surface roughness in a turning operation is affected by a great number of factors. Two of the most important factors are feed rate and the size of the corner radius. Surface roughness can be roughly determined to increase with the square of the feed rate and decrease with increased size of the corner radius. However, wiper insert geometries changed this relationship with the capability to generate good surface roughness at relatively higher feeds by transferring small part of the round insert edges into the straight cutting edges of the pointed insert. The principle of how wiper inserts behave different from conventional inserts as to the effects on the surface roughness is explored in this paper. Experimental study of the surface roughness produced in the turning of hardened mild steels using coated carbide tools with both conventional and wiper inserts is conducted. The test results prove the effectiveness of the wiper inserts in providing excellent surface roughness. The results also suggest that the use of the wiper insert is an effective way that significantly increases cutting efficiency without changing the machined surface roughness in high feed turning operations.
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39

Pei, Hong Jie, Wen Jie Zheng, Gui Cheng Wang, and Hu Qiang Wang. "Application of Biodegradable Cutting Fluids in High Speed Turning." Advanced Materials Research 381 (November 2011): 20–24. http://dx.doi.org/10.4028/www.scientific.net/amr.381.20.

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Large quantities of coolant-lubricants are still widely used in metal working industry, generating high consumption and discard costs and impacting the environment. An alternative to current practices is to use biodegradable cutting fluids that doesn’t pollute environment or require new setups. In current study, biodegradable base oils, synthetic ester and castor oil, are chosen and compounded into cutting fluids which correspond with the national standards. The tests have been performed to high speed turn AISI 1045 steel in ester-based fluid, castor-based emulsion, kerosene and dry condition. The results indicate that the application of cutting fluids is inevitable in metal machining and can not be replaced by dry machining. The lubricating and cooling properties of the ester-based fluid and castor-based emulsion are better than kerosene and can wholly replace mineral oil.
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40

Revel, Philippe, Nabil Jouini, Guillaume Thoquenne, and Fabien Lefebvre. "High precision hard turning of AISI 52100 bearing steel." Precision Engineering 43 (January 2016): 24–33. http://dx.doi.org/10.1016/j.precisioneng.2015.06.006.

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41

Uhlmann, Eckart, Felix Kaulfersch, and Martin Roeder. "Turning of High-performance Materials with Rotating Indexable Inserts." Procedia CIRP 14 (2014): 610–15. http://dx.doi.org/10.1016/j.procir.2014.03.028.

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42

Sitek, Libor, and Petr Hlavacek. "TURNING OF MATERIALS WITH HIGH-SPEED ABRASIVE WATER JET." MM Science Journal 2016, no. 04 (2016): 1160–65. http://dx.doi.org/10.17973/mmsj.2016_10_201692.

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43

Klocke, F., and H. Kratz. "Advanced Tool Edge Geometry for High Precision Hard Turning." CIRP Annals 54, no. 1 (2005): 47–50. http://dx.doi.org/10.1016/s0007-8506(07)60046-8.

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44

Hara, Keisuke, Daisuke Hashikai, Hiromi Isobe, Jun Ishimatsu, Yoshihiro Take, and Toshihiko Koiwa. "Investigation of Cutting Phenomena in High Speed Ultrasonic Turning." Key Engineering Materials 523-524 (November 2012): 209–14. http://dx.doi.org/10.4028/www.scientific.net/kem.523-524.209.

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This study investigated phenomena of ultrasonic cutting in case of high speed conditions. Ultrasonically assisted cutting techniques were developed by Kumabe in 1950’s. He found “critical cutting speed” that limits cutting speed to obtain ultrasonically assisted effects and is calculated by frequency and amplitude of oscillation. In general, ultrasonically assisted cutting is not suitable for high speed cutting conditions because the effects of ultrasonically applying are canceled due to tool contacts with workpiece during cutting operation. Present ultrasonically assisted cutting cannot increase cutting speed because cutting speed is limited by above reason. And ultrasonically assisted cutting cannot improve productivity due to long processing time. We conducted high speed ultrasonic cutting, maximum cutting speed of this research was 160m/min which is higher than general critical cutting speed. Workpiece material is JIS SUS304 stainless steed and cemented carbide tool inserts were employed in this research. In ordinary cutting, generate terrible built up edge on to tool rake face. In case of low amplitude ultrasonic cutting, tool rake face hasn’t built up edge and periodically marks by ultrasonic oscillation were remained on the surface. Cutting phenomena of ultrasonic cutting is different compared with ordinary cutting conditions.
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45

Wang, Mu Lan, Yong Feng, Xiao Xia Li, and Bao Sheng Wang. "Experiment of Temperature Field for High Speed Orthogonal Turning." Applied Mechanics and Materials 117-119 (October 2011): 594–97. http://dx.doi.org/10.4028/www.scientific.net/amm.117-119.594.

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An experimental system used for temperature measurement is designed by the K-type thermocouple thermometry to achieve a direct measurement of cutting temperature in high speed orthogonal turning. The general regularity of temperature distribution is concluded, and the corresponding influences of cutting speed and cutting depth on the maximum temperature value are discussed in detail. Experimental data and simulating results are comparative analyzed to demonstrate the feasibility and correctness of Finite Element Method (FEM) model simulation and analytical solution. The verified model of temperature field can be applied to develop an effective non-contact soft-sensing method for high speed cutting temperature.
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46

Cieloszyk, Janusz. "Face rotary turning tools (FRTT) in high productivity process." Mechanik 92, no. 11 (2019): 736–38. http://dx.doi.org/10.17814/mechanik.2019.11.100.

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The article presents an unconventional method of machining rolling surfaces. This method is called face rotary turning tools (FRTT) or spinning tools technology. Advantages and limitations of the method were discussed and its effectiveness in modern machining processes was shown, based on the proposed simple models.
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47

Rollins, Thomas. "Turning employee survey results into high-impact business improvements." Employment Relations Today 21, no. 1 (1994): 35–44. http://dx.doi.org/10.1002/ert.3910210105.

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48

Dupéré, Véronique, Tama Leventhal, Eric Dion, Robert Crosnoe, Isabelle Archambault, and Michel Janosz. "Stressors and Turning Points in High School and Dropout." Review of Educational Research 85, no. 4 (2015): 591–629. http://dx.doi.org/10.3102/0034654314559845.

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49

Umer, Usama. "Simulation of Oblique Cutting in High Speed Turning Processes." International Journal of Materials Forming and Machining Processes 3, no. 1 (2016): 12–21. http://dx.doi.org/10.4018/ijmfmp.2016010102.

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A Finite Element Model is developed for Oblique cutting process in high speed turning of H-13 tool steel. The material model used for workpiece is elastic-thermoplastic including the strain rate sensitivity effect. In order to predict the tool performance, tool is considered as non-rigid and direct stresses are determined around the tool tip. Lagrangian approach is utilized along with adaptive meshing to minimize element distortion around the tool tip. The model predicts cutting forces in 3-directions at different inclination angles. The results are compared with experimental data and found to be in good agreement. The model is also able to predict stress and temperature contours in the workpiece and the cutting tool which help in predicting workpiece surface integrity and performance of the cutting tool.
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50

Yilong Zhu, Hongqi Fan, Jianpeng Fan, Zaiqi Lu, and Qiang Fu. "Target Turning Maneuver Detection using High Resolution Doppler Profile." IEEE Transactions on Aerospace and Electronic Systems 48, no. 1 (2012): 762–79. http://dx.doi.org/10.1109/taes.2012.6129669.

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