Machines,and,Robots,Driven,Mus education Machines and Robots Driven by Muscle Like Acting NiTi Alloys


Translation jobs are undertaken by professional translators who are well versed with at least two languages.Translation can work at two levels: inter-state or regional language translation and inter-national or foreign language translation. Some forms of parent involvement with the school such as communications with school, volunteering, attending school events and parent--parent connections appeared to have little effect on student achievement, especially in high school. Helpi


Introduction A The research presented has the aim to show that better optimized systems based on Shape Memory Alloys (SMAs) can be designed using muscles working as biomimetic model. In particular the Skeletal muscles and the antagonistic pairs have been used as biomechanical model, they are the voluntary muscles that allow the body to move and they make up 40% of an organism’s body mass (Lindstedt, 2016).Skeletal muscles are held to the bones by tendons, which role is to transfer the force generated by the muscles contraction to the bone joint. Tendons are made of robust tissue and they work as special viscoelastic connectors between bone and muscle. For an adduction movement in a joint, contraction and shortening of the muscle generates a force that is applied on a lever system that causes the joint adduction movements. To recover its initial position, the reciprocal muscle on the other side of the joint contracts and shortens. As described by Biewener and Roberts (2000), muscles are normally coupled in opposition so that movements of joints are driven by a mechanism in which one group of muscles contracts while another group relaxes or lengthens (Aversa et al., 2017 a-e, 2016 a-o; Petrescu et al., 2017, 2016 a-e; Petrescu and Petrescu; Petrescu).Basically antagonistic pairs are muscles where one moves the bone in one direction and the other moves it back the other way in transmission of nerve impulses to the muscles. In the adduction movement of a human arm, the agonist biceps shortens and bends the forearm on the elbow joint, conversely, on arm abduction movement; the antagonist triceps shortens and returns the forearm to its original position. In general, the muscle that applies the force needed for a movement is only one of agonist-antagonistic pairs and, in particular, there is always a selective stimulation driven by the brain that acts on the muscle that contracts or shortens (agonist), while the behaviour of the reciprocal is passive, it works roughly like a brake (antagonist). The active muscle for a specific movement is always the one that contracts (Yang et al., 2013).A unique class of Smart Materials that has in common with muscles the capability to react to an impulse (thermal in this case) with a change of shape and thus also with a contracting movement if necessary is that of Shape Memory Alloys (Van Humbeeck, 2010; Meisel et al., 2014; Melton and Mercier, 1980).This analogy between muscles contraction and extension and the ability of this class of intermetallic alloys to undergo contraction and extension (superelasticity) under the effect of thermal and mechanical stimulation, allow us to derive a biomechanically inspired machine based on these materials.U.S. Naval Ordnance Laboratory discovered shape Memory Effect for the first time during 1960s. The researcher of the Laboratory found this effect in a 1 to 1 alloy of Nickel and Titanium, but only nowadays, a higher spread for biomedical field, actuators, couplings and surgical instruments. Anyhow, applications of SMAs for industrial or product design are still so poorly spread and SMAs potentialities are only rarely and weakly exploited.Nickel-Titanium alloys are intermetallic compounds (Otsuka and Ren, 1999) and they able to show thermal shape memory effect, namely, to return to their original shape on heating even when largely deformed (up to 10%).The Stress-Strain-Temperature diagram of Fig. 1 resumes the thermo-mechanical behaviour of these NiTi based materials.The NiTi alloy assumes, at higher temperatures, an interpenetrating simple body centred cubic structure known as Austenite (Meisel et al., 2014).When brought at lower temperatures (treatment A in Fig. 1 and 2), this intermetallic alloy freely solid-solid transforms to a constrained and more complex face-centred tetragonal crystalline structure identified as Martensite.The Body-Centred Cubic (BCC) crystal structure of Austenite (Xiangyang et al., 2003) shows only one possible crystallographic habit that can be got at equilibrium (high temperatures state 1 in Fig. 1) that is identified as B2 type (Fig. 2). On cooling, Austenite crystals undergo a constrained solid-solid diffusionless transformation to metastable Martensite. After Otsuka and Ren (1999) it has been recognized that, in binary TiNi transformation proceeds from the parent BCC structure (B2 type in Fig. 2) to martensitic FCC lattices. The body-centred cubic parent austenitic phase (B2) may transform by a diffusionless local shear mechanism into an orthorhombic or monoclinic martensite phases. The later martensite lattice is a monoclinic B19′ phase (Otsuka et al., 1971; Knowles and Smith, 1981; Miyazaki et al., 1984; Matsumoto et al., 1987), which has been justified as a monoclinic alteration of the B19 orthorhombic structure (Fig. 2).The transition amongst these structures needs small thermal activation because involves diffusionless transformation and easily results in the restrained and rapid rearrangement of atomic positions.For this crystalline conformation, however, two differently oriented crystallographic variants with small energetic differences exist. These two configurations consist of the twinned (B19 in Fig. 2) and detwinned (B19’ in Fig. 2) rearrangements of atomic planes without crystal plane slip (states 2 and 6 of Fig. 1). Due to thermodynamic considerations, the twinned structure freely occurs in unstressed conditions (state 2).The Martensite is described to be crystallographically reversible, which involves that a given plate undergo a backward reverse shear upon heating.Normally, the Martensite forms, on cooling, only under Ms, however, it could even occur at temperatures higher than Ms if a stress is applied (Yang and Wayman, 1999).The Martensite formed in these conditions is named Stress-Induced Martensite (SIM).It can be deduced that the prevailing driving force for Martensitic transformation above Ms is not thermal but mechanical (transformations B in Fig. 1 and 2). Above the temperature where Martensitic transformation starts (Ms), the stress required to produce SIM progressively increases with increasing temperature (Šittner et al., 2014).where, P is the pressure, T is the temperature and ΔH is the latent heat of phase change (that can be determined by DSC analysis) and ΔV is the volume change of the phase change (the volume change for NiTi Austenitic to Martensitic phases may be calculated from the dimension of the crystalline units, namely a cube of 0.3015 nm for Austenite to the 0.4622×0.4120×0.3015 nm for the Martenisite (orthotrombic or nonoclinic).Moreover, it has been theoretically predicted (Clasius Claypeiron Equation 2) and experimentally determined (Šittner et al., 2014) that the level of mechanical loading necessary to create Stress Induced Martensite (SIM) growths linearly with temperature. These reversible solid-state phase transformations are known as a martensitic transformation that requires to occur, depending on temperature, mechanical loading stresses between 70 to 140 MPa (Duerig et al., 1990).According to Equation 2 the stress drops to zero at the temperature Ms.The difficulty to stress induce Martensite continues to increase with temperature until Md, above which the critical stress required to induce Martensite is greater than the stress required to move the dislocations (not reversible plastic deformation).Therefore the temperature range for SIM is from Ms to Md. For a number of SMA systems, the agreement in the temperature dependence of the stress to form SIM according to the Clausius-Clayperon equation is quite striking.The equation works equally well for the non-isothermal case, i.e., the case where temperature was held constant while the stress needed to form Martensite was measured.Super-elasticity occurs when a material is deformed above As, but still below Md. In this range, Martensite could be stabilized with the application of stress, but becomes unstable upon removal of stress.By mechanical stretching (treatment B in Fig. 1 and 2), in fact, the SMA is deformed to a larger extent (states 3 to 4 in Fig. 1 and structures B19 and B19’ in Fig. 2). This pseudo-plastic deformation is enabled by reorientation of crystallographic variants in the cold temperature phase following twinned (B19) to de-twinned (B19’) martensite transformations. Consequently, the deformation persists after load removal (from state 2 to 3 in Fig. 1). On re-heating, process C in Fig. 1 and 2, the material progressively transforms to Austenite B2 crystal lattice (from state 6 to intermediate state 7 and final state 1 in Fig. 1) recovering its initial shape.During this shape recovery, large strain changes and large forces are generated that are of particular benefit for the development of temperature-activated actuators.As reported on the temperature axis of Fig. 1, the four characteristic temperatures of SMAs are Mf (Martensite finish), Ms (Martensite start) on cooling and As (Austenite start) and Af (Austenite finish) on heating.When SMA is heated, it starts to change into Austenite phase at As and it completes the transition at Af temperature; similarly, on cooling, it starts the transformation to Martensite at Ms temperature and it completes the transition at Mf temperature.However, for some NiTi alloy compositions, an intermediate phase, called R-phase with rhombohedral structure, could also manifest, in this case the characteristics temperatures are indicated as Rs and Rf. This event manifests itself by thermal events that can be measured in Differential scanning Calorimetry. The calorimetric analysis has been run on our samples to identify not only austenitic than martensitic characteristic temperatures but also the occurrence of the intermediate rhombohedral lattices.The SMAs can exhibit two kind of Shape Memory Effect (SME), defined as one-way and two-way effects. For one-way effect we mean the SMAs ability to remember and resume the macroscopic shape associated with austenitic phase when heated up to Af temperature; for two-way effect, instead, we mean the first ability described added to the capability to recover also the macroscopic shape associated with martensitic phase when cooled up to Mf temperature.To get one or two-way memory effect, in order to program pre-set shapes for martensitic and austenitic phases, thermo-mechanical treatments are required (Naresh et al., 2016).The basic idea of this paper on how and why to use the biomechanical model of muscles working is discussed in the next paragraphs.  Materials, Methods and Procedures MaterialsIn order to experiment and develop the biomimetic model aimed to the optimization of systems based on SMAs wires Dinalloy Inc.Flexinol is a SMA with Nickel and Titanium as main chemical constituents.Apparatus and ProceduresDifferential Scanning Calorimetry (DSC)Thermocalorimetric analyses have been carried out on NiTi alloys. The DSC technique determines the temperature and the heat flows associated with material transitions as a function of time and temperature. It also provides quantitative data on endothermic (heat absorption) and exothermic (heat evolution) processes of materials during physical transitions (Ziólkowski, 2012; Shaw et al., 2008).The thermocalorimetric characterization has been carried out in a nitrogen atmosphere by a Mettler ADSC Differential Scanning Calorimeter equipped with a liquid nitrogen cooling unit in the range of temperatures between -30 and 120°C. Temperature scans were carried out at 5°C/min. For sample stabilization, isothermal scan were run at 500°C, heat flux were recorded up the final apparent equilibrium (heat flux = 0). The high temperature treatment induces the crystal structure atoms to re-arrange into the most compact and regular pattern possible finally resulting in a rigid cubic austenite phase (Kauffman and Mayo, 1993). A typical DSC thermogram performed on a specimen of Flexinol wire (0.25 mm of diameter, 4,00 mg) has been reported in Fig. 3.  ReferencesAversa, Raffaella; Petrescu, Relly Victoria V.; Apicella, Antonio; Petrescu, Florian Ion T.; 2017a Nano-Diamond Hybrid Materials for Structural Biomedical Application, American Journal of Biochemistry and Biotechnology, 13(1).Aversa, Raffaella; Petrescu, Relly Victoria; Akash, Bilal; Bucinell, Ronald B.; Corchado, Juan M.; Berto, Filippo; Mirsayar, MirMilad; Chen, Guanying; Li, Shuhui; Apicella, Antonio; Petrescu, Florian Ion Tiberiu; 2017b Kinematics and Forces to a New Model Forging Manipulator, American Journal of Applied Sciences 14(1):60-80.Aversa, Raffaella; Petrescu, Relly Victoria; Apicella, Antonio; Petrescu, Florian Ion Tiberiu; Calautit, John Kaiser; Mirsayar, MirMilad; Bucinell, Ronald; Berto, Filippo; Akash, Bilal; 2017c Something about the V Engines Design, American Journal of Applied Sciences 14(1):34-52.Aversa, Raffaella; Parcesepe, Daniela; Petrescu, Relly Victoria V.; Berto, Filippo; Chen, Guanying; Petrescu, Florian Ion T.; Tamburrino, Francesco; Apicella, Antonio; 2017d Processability of Bulk Metallic Glasses, American Journal of Applied Sciences 14(2):294-301.Aversa, Raffaella; Petrescu, Relly Victoria V.; Akash, Bilal; Bucinell, Ronald B.; Corchado, Juan M.; Berto, Filippo; Mirsayar, MirMilad; Chen, Guanying; Li, Shuhui; Apicella, Antonio; Petrescu, Florian Ion T.; 2017e Something about the Balancing of Thermal Motors, American Journal of Engineering and Applied Sciences 10(1).Aversa, R., F.I.T. Petrescu, R.V. Petrescu and A. Apicella, 2016a. Biomimetic FEA bone modeling for customized hybrid biological prostheses development. Am. J. Applied Sci., 13: 1060-1067. DOI: 10.3844/ajassp.2016.1060.1067Aversa, R.; Parcesepe, D.; Petrescu, R.V.; Chen, G.; Petrescu, F.I.T.; Tamburrino, F.; Apicella, A. 2016b Glassy Amorphous Metal Injection Molded Induced Morphological Defects, Am. J. Applied Sci. 13(12):1476-1482.Aversa, R.; Petrescu, R.V.; Petrescu, F.I.T.; Apicella, A.; 2016c Smart-Factory: Optimization and Process Control of Composite Centrifuged Pipes, Am. J. Applied Sci. 13(11):1330-1341.Aversa, R.; Tamburrino, F.; Petrescu, R.V.; Petrescu, F.I.T.; Artur, M.; Chen, G.; Apicella, A.; 2016d Biomechanically Inspired Shape Memory Effect Machines Driven by Muscle like Acting NiTi Alloys, Am. J. Applied Sci. 13(11):1264-1271.Aversa, R.; Buzea, E.M.; Petrescu, R.V.; Apicella, A.; Neacsa, M.; Petrescu, F.I.T.; 2016e Present a Mechatronic System Having Able to Determine the Concentration of Carotenoids, Am. J. of Eng. and Applied Sci. 9(4):1106-1111.Aversa, R.; Petrescu, R.V.; Sorrentino, R.; Petrescu, F.I.T.; Apicella, A.; 2016f Hybrid Ceramo-Polymeric Nanocomposite for Biomimetic Scaffolds Design and Preparation, Am. J. of Eng. and Applied Sci. 9(4):1096-1105.Aversa, R.; Perrotta, V.; Petrescu, R.V.; Misiano, C.; Petrescu, F.I.T.; Apicella, A.; 2016g From Structural Colors to Super-Hydrophobicity and Achromatic Transparent Protective Coatings: Ion Plating Plasma Assisted TiO2 and SiO2 Nano-Film Deposition, Am. J. of Eng. and Applied Sci. 9(4):1037-1045.Aversa, R.; Petrescu, R.V.; Petrescu, F.I.T.; Apicella, A.; 2016h Biomimetic and Evolutionary Design Driven Innovation in Sustainable Products Development, Am. J. of Eng. and Applied Sci. 9(4):1027-1036.Aversa, R., Petrescu, R.V., Apicella, A., and Petrescu, F.I.T., 2016i Mitochondria are Naturally Micro Robots - A review, Am. J. of Eng. and Applied Sci. 9(4):991-1002.Aversa, R.; Petrescu, R.V.; Apicella, A.; Petrescu, F.I.T.; 2016j We are Addicted to Vitamins C and E-A Review, Am. J. of Eng. and Applied Sci. 9(4):1003-1018.Aversa, R., Petrescu, R.V., Apicella, A., and Petrescu, F.I.T., 2016k Physiologic Human Fluids and Swelling Behavior of Hydrophilic Biocompatible Hybrid Ceramo-Polymeric Materials, Am. J. of Eng. and Applied Sci. 9(4):962-972.Aversa, R.; Petrescu, R.V.; Apicella, A.; Petrescu, F.I.T.; 2016l One Can Slow Down the Aging through Antioxidants, Am. J. of Eng. and Applied Sci. 9(4):1112-1126.Aversa, R.; Petrescu, R.V.; Apicella, A.; Petrescu, F.I.T.; 2016m About Homeopathy or jSimilia Similibus Curenturk, Am. J. of Eng. and Applied Sci. 9(4):1164-1172.Aversa, R.; Petrescu, R.V.; Apicella, A.; Petrescu, F.I.T.; 2016n The Basic Elements of Life's, Am. J. of Eng. and Applied Sci. 9(4):1189-1197.Aversa, R.; Petrescu, F.I.T.; Petrescu, R.V.; Apicella, A.; 2016o Flexible Stem Trabecular Prostheses, Am. J. of Eng. and Applied Sci. 9(4):1213-1221.Biewener, A.A. and T.J. Roberts, 2000. Muscle and tendon contributions to force, work and elastic energy savings: A comparative perspective. Exerc. Sport Sci. Rev., 28: 99-107. PMID: 10916700Duerig, T.W., K.N. Melton, D. Stockel and C.M. Wayman, 1990. Engineering Aspects of Shape Memory Alloys. Books on Demand, England, ISBN-10: 0608049980, pp: 511.Hanlon, J.E., S.R. Butler and R.J. Wasilewski, 1967. Effect of martensitic transformation on the electrical and magnetic properties of NiTi. Trans. Metallurgical Society AIME, 239: 1323-1327.Harrison, J.D. and D.E. Hodgson, 1975. Use of TiNi in Mechanical and Electrical Connectors. In: Shape Memory Effects in Alloys, Perkins, J. (Ed.), Plenum Press, New York, ISBN-10: 0306308916, pp: 583.Huang, X., G.J. Ackland and K.M. Rabe, 2003. Crystal structures and shape-memory behaviour of NiTi. Nature Mater., 2: 307-311. DOI: 10.1038/nmat884Kauffman, G. and I. Mayo, 1993. Memory Metal. Chem. Matters, 381: 130-136.Knowles, K.M. and D.A. Smith, 1981. The crystallography of the martensitic transformation in equiatomic nickel-titanium. Acta Metall., 29: 101-110. DOI: 10.1016/0001-6160(81)90091-2Kus, K. and T. Breczko, 2010. DSC-investigations of the effect of annealing temperature on the phase transformation behaviour in Ni-Ti shape memory alloy. Mater. Phys. Mechan., 9: 75-83. http://www-proxy.ipme.ru/e-journals/MPM/no_1910/kus.pdfLahoz, R. and J.A. Puértolas, 2004. Training and two-way shape memory in NiTi alloys: Influence on thermal parameters. J. Alloys Compounds, 381: 130-136. DOI: 10.1016/j.jallcom.2004.03.080Lindstedt, S., 2016 Skeletal muscle tissue in movement and health: Positives and negatives. J. Experim. Biol., 219: 183-188. DOI: 10.1242/jeb.124297Matsumoto, O., S. Miyazaki, K. Otsuka and H. Tamura, 1987. Crystallography of martensitic transformation in Ti-Ni single crystals. Acta Metall., 35: 2137-2144. DOI: 10.1016/0001-6160(87)90042-3Meisel, N.A., A.M. Elliott and C.B. Williams, 2014. A procedure for creating actuated joints via embedding shape memory alloys in PolyJet 3D printing. J. Intelli. Mater. Syst. Structures, 26: 1498-1512. DOI: 10.1177/1045389X14544144Melton, K.N. and O. Mercier, 1980. The mechanical properties of NiTi-based shape memory alloys. Acta Metallurg. 29: 393-398. DOI: 10.1016/0001-6160(81)90165-6Miyazaki, S., S. Kimura, K. Otsuka and Y. Suzuki, 1984. The habit plane and transformation strains associated with the martensitic transformation in Ti-Ni single crystals. Scripta Metallurg., 18: 883-888. DOI: 10.1016/0036-9748(84)90254-0Naresh, C., P.S.C. Bose and C.S.P. Rao, 2016. Shape memory alloys: A state of art review. IOP Conf. Mater. Sci. Eng. DOI: 10.1088/1757-899X/149/1/012054Otsuka, K. and X. Ren, 1999. Recent developments in the research of shape memory alloys. Intermetallics, 7: 511-528. DOI: 10.1016/S0966-9795(98)00070-3Otsuka, K., C.M. Wayman, K. Nakay, H. Sakamoto and K. Shimizu, 1976. Superelasticity effects and stress-induced martensitic transformations in CuAlNi alloys. Acta Metallurg., 24: 207-226. DOI: 10.1016/0001-6160(76)90071-7Otsuka, K., T. Sawamura and K. Shimizu, 1971. Crystal structure and internal defects of equiatomic TiNi martensite. Phys. Stat. Sol., 5: 457-470. DOI: 10.1002/pssa.2210050220Petrescu, F.I.T. and Calautit, K.J., 2016a About Nano Fusion and Dynamic Fusion, Am. J. Applied Sci. 13(3):261-266.Petrescu, F.I.T. and Calautit, K.J., 2016b About the Light Dimensions, Am. J. Applied Sci. 13(3):321-325.Petrescu, Relly Victoria Virgil; Aversa, Raffaella; Apicella, Antonio; Petrescu, Florian Ion Tiberiu; 2017 ENERGIA VERDE PARA PROTEGER O MEIO AMBIENTE, Geintec, 7(1):3722-3743. Retrieved from: http://www.revistageintec.net/portal/index.php/revista/article/view/971/747Petrescu, F.I.T., Apicella, A., Aversa, R., Petrescu, R.V., Calautit, J.K., Mirsayar, M., et al., 2016a Something about the Mechanical Moment of Inertia, Am. J. Applied Sci. 13(11):1085-1090.Petrescu, R.V.; Aversa, R.; Apicella, A.; Li, S.; Chen, G.; Mirsayar, M.; Petrescu, F.I.T.; 2016b Something about Electron Dimension, Am. J. Applied Sci. 13(11):1272-1276.Petrescu, R.V., Aversa, R., Apicella, A., Berto, F., Li, S., and Petrescu, F.I.T., 2016c Ecosphere Protection through Green Energy, Am. J. Applied Sci. 13(10):1027-1032.Petrescu, F.I.T., Apicella, A., Petrescu, R.V., Kozaitis, S.P., Bucinell, R.B., Aversa, R., and Abu-Lebdeh, T.M., 2016d Environmental Protection through Nuclear Energy, Am. J. Applied Sci. 13(9):941-946.Petrescu, R.V., Aversa, R., Apicella, A., Petrescu, F.I.T., 2016e Future Medicine Services Robotics, Am. J. of Eng. and Applied Sci. 9(4):1062-1087.Petrescu F.I., Petrescu R.V., (2011) Perspective energetice globale (Romanian Edition) – December 26, 2011, 80 pages, Publisher: CreateSpace Independent Publishing Platform, ISBN-10: 146813082X, ISBN-13: 978-1468130829; Retrieved from:http://www.amazon.com/Perspective-energetice-globale-Romanian-Petrescu/dp/146813082XPetrescu F.I., Petrescu R.V., (2012) Green Energy, Paperback – November 5, 2012, Books On Demand, 118 pages, ISBN-13: 978-3848223633; Retrieved from:http://www.amazon.com/Green-Energy-Florian-Tiberiu-Petrescu/dp/3848223635/ref=la_B006T2UHJM_1_25?s=books&ie=UTF8&qid=1432305411&sr=1-25Petrescu, F.I., Petrescu, R.V., (2014) Nuclear Green Energy, IJAP, 10(1):3-14; Retrieved from:http://www.iasj.net/iasj?func=fulltext&aId=88317Petrescu, F.I., Petrescu, R.V., 2011a The Battle For Energy, In CONFERENG 2011, November 2011, Târgu-Jiu, in Annals of the “Constantin Brâncu_i” University, Engineering Series, Vol. 5, n. 3, 2011, p. 176-186, ISSN 1842-4856.Petrescu, F.I., Petrescu, R.V., 2011b The Battle for Energy, In Alternative Energy eMagazine, August / September 2011. Retrieved from:http://altenergymag.com/emagazine.php?art_id=1767Petrescu, F.I. and R.V. Petrescu, 2013. Cinematics of the 3R Dyad. J. Engevista, 15: 118-124. http://journaldatabase.info/articles/cinematics_3r_dyad.htmlPetrescu, F.I. and R.V. Petrescu, 2012. Mecatronica-Sisteme Seriale si Paralele. 1st Edn., Create Space Publisher, USA, ISBN-10: 1475066139, pp: 128.Petrescu, F.I and R.V. Petrescu, 2011. Mechanical Systems, Serial and Parallel. 1st Edn., Lulu.com, ISBN-10: 1446600394, pp: 124.Petrescu, F.I., Petrescu, R.V., 2010 The Energies of Today and Tomorrow In CONFERENG 2010, November 2010, Târgu-Jiu, in Annals of the “Constantin Brâncu_i” University, Engineering Series, Vol. 4, n. 3, 2010, p. 112-123, ISSN 1842-4856.Petrescu, F.I., B. Grecu, A. Comanescu and R.V. Petrescu, 2009. Some mechanical design elements. Proceedings of the 3rd International Conference on Computational Mechanics and Virtual Engineering, (MVE’ 09), Bra_ov, pp: 520-525.Petrescu, F.I., 2015a Geometrical Synthesis of the Distribution Mechanisms, American Journal of Engineering and Applied Sciences, 8(1):63-81.Petrescu, F.I., 2015b Machine Motion Equations at the Internal Combustion Heat Engines, American Journal of Engineering and Applied Sciences, 8(1):127-137.Petrescu, F.I., 2015c New in Cold Nuclear Fusion, (2015) Alternative Energy Magazine. Retrieved from: http://www.altenergymag.com/content.php?post=21223Petrescu, F.I., 2014 Nuclear Fusion, In journal Infinite Energy, Vol. 20, No. 1 (2014), Issue 113, January 2014, ISSN 1081-6372, p. 44-47, USA.Petrescu, F.I., 2012 Teoria mecanismelor – Curs si aplicatii (editia a doua), Create Space publisher, USA, September 2012, ISBN 978-1-4792-9362-9, 284 pages, Romanian version.Petrescu, F.I., 2011 Some New Elements in Physics, Create Space publisher, USA, November 2011, ISBN 978-1-4679-4880-7, 72 pages, English version.Petrescu, F.I., 2010 Some Applications in Laser Field, In the 3rd International Conference “Advanced Composite Materials Engineering”, COMAT 2010, October 2010, Brasov, Romania, and International Conference “Research & Innovation in Engineering”, Vol. 2, p. 187-192, ISSN 1844-9336.Petrescu, FIT, 2009 About the Ionic Engines. Annals of the “Constantin Brâncu_i” University, Engineering Series, ISSUE 3/2009, Târgu-Jiu, November 2009, “ACADEMICA BRÂCU^I” PUBLISHER, ISSN 1842-4856, vol. 3, nr. 3, 2009, p. 301-312.Shaw JA, Churchill CB and Iadicola MA, 2008, Tips and tricks for characterizing shape memory alloy wire: Part 1-Differential Scanning Calorimetry and basic phenomena. Society Experim. Mechan., 32: 55-62. DOI: 10.1111/j.1747-1567.2008.00410.xŠittner, P., L. Heller, J. Pilch, C. Curfs and A. Thiery et al., 2014. Young's modulus of austenite and martensite phases in superelastic NiTi wires. J. Mater. Eng. Perform., 23: 2303-2314. DOI: 10.1007/s11665-014-0976-xSofla, A.Y.N., D.M. Elzey and H.N.G. Wadley, 2008. Two-way antagonistic shape actuation based on the one-way shape memory effect. J. Intelli. Mater. Syst. Struct., 19: 1017-1027. DOI: 10.1177/1045389X07083026Dinalloy, Inc. Technical characteristics of Flexinol actuators wires. Dinalloy, Inc. http://www.dynalloy.com/pdfs/TCF1140.pdfVan Humbeeck, J., 2010. Introduction to shape memory alloys. Proceedings of the School and Symposium on Smart Structural Systems Technologies, (SST’ 10), Porto, Portugal, pp: 3-23. DOI 10.1007/978-0-387-47685-8_1Velázquez, R. and E.E. Pissaloux, 2012. Modelling and temperature control of Shape Memory Alloys with fast electrical heating. Int. J. Mechan. Control, 13: 3-10. http://www.robotica-up.org/PDF/JoMaC12B04.pdfXiangyang, H., Graeme J, Ackland and Rabe KM, 2003, Crystal structures and shape-memory behaviour of NiTi. Nature Mater., 2: 307-311. PMID: 12704381Yang, H.Z., X.G. Duan and H. Deng, 2013. A study on the force distribution for artificial antagonistic muscles. Mechanics and Materials pag 278-280 and pag 105-110Yang, J.H. and C.M. Wayman, 1992a. Self-accomodation and shape memory mechanism of ε-martensite—I. Experimental observations. Mater. Characterizat., 28: 23-35. DOI: 10.1016/1044-5803(92)90026-EYang, J.H. and C.M. Wayman, 1992b. Self-accomodation and shape memory mechanism of e-martensite — II. Theoretical considerations. Mater. Characterizat., 28: 37-47. DOI: 10.1016/1044-5803(92)90027-FZiólkowski, A., 2012. On analysis of DSC curves for characterization of intrinsic properties of NiTi shape memory alloys. Proceedings of the 12th International Symposium on Physics of Materials, Sept. 4-8, Prague, pp: 601-605. DOI: 10.12693/aphyspola.122.601 See the full article at:  http://mcaf.ee/plgfqy

Machines,and,Robots,Driven,Mus

education

8 Great Tips for Successful Studying

Very few things induce panic and stress like an approaching academic exam. As long as you focus and study productively, youll be able to experience great success. The following eight tips will help you study more effectively, giving you the ...

education

Steps and stages of new drug development

New drug discovery research starts with the discovery and confirmation of drug targets, followed by screening using various screening libraries like activity-based libraries, fragment libraries and design, optimization of lead compounds, and ...

education

Best Institute For Digital Marketing Course In Mumbai

To help build a career in Digital Marketing, we are educating many individuals to build their dream careers with an internship on live projects and a 100% job guarantee.We are one of the best institutes for Digital Marketing Courses in Mumb ...

education

Data science trends in 2020

Data science trends in 2020Presently, data science is a common term. That was not the case at that time five years ago, because only a few people knew about it. Do you need to know what it is before moving on further? It is nothing else but ...

education

Effective tips to crack IIT JEE Mains

JEE Mains i.e. Joint Entrance Examination is a national level entrance examination conducted for admission to engineering courses. JEE aspirants demand immense patience, hard work, consistency, and determination.To crack this extremely compe ...

education

5 Easy Conclusion Writing Hacks for Students

Do you know why most students search for a conclusion generator online? We will tell you why! Every assignment has 5 paragraphs the introduction, three main body paragraphs, and lastly the conclusion. While you have stumbled upon several ti ...

education

Couplings

Couplings are mechanical components that couples two drive components that empower a movement to be moved to start with one component then onto the next. The drive components are regularly shafts.We will, in general, observe part of utilizat ...

education

Flexible couplings

Flexible couplings are utilized to transmit torque starting with one shaft then onto the next when the two shafts are marginally misaligned.Flexible couplings can oblige fluctuating degrees of misalignment up to 3° and some parallel misali ...

education

How to Study Revision Notes for Class 8 Effectively?

Revision Notes For Class 8 MathsStrengthening of maths in crucial for ones further career in terms of engineering or a professional course.To many students, maths could not turn very seamless, so here we at Entrancei to bring maximum benefit ...

education

CMA Course - Fees | Subject | Classes

CMA CourseIn this course, you will be taught Concepts of Taxation in a scientific and well-defined manner. Also, you will learn, how to prepare for CMA Course Inter Taxation where you will get guidance by Sanjeev Varshney Sir. The CMA Inter ...

education

http://www.articlesfactory.com/myaccount/profile/

Parul University very famously called as PU in Vadodara, Gujarat, is one of the well-known private universities of the state. The university was established in 2015 under the Gujarat Private Universities Act, 2009. The university is approved ...

education

How To Write An Effective Dissertation Abstract?

Each part holds an important significance in the whole piece of art. So, it is advised by dissertation abstract writing help experts to pay equal heed on every part. This write-up is solely dedicated to offering information regarding one of ...