Ferromagnetic shape memory flapper for remotely actuated propulsion systems

Kanner, Oren Y; Shilo, Doron; Sheng, Jian; James, Richard D.; Ganor, Yaniv

doi:10.1088/0964-1726/22/8/085030

Cited by 27 publications

(17 citation statements)

References 28 publications

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“…Thus, in one quarter of the beam volume, the crystallographic c-axis is perpendicular to the beam axis (hence parallel to the current magnetic field) and in the rest of the sample volume, the c-axis is parallel to the beam axis (hence perpendicular to the magnetic field). The smooth curvature of the beam implies that many twin boundaries are present because an isolated twin boundary would cause a distinct kink [15,16]. At field angles slightly below and slightly above 90°, the torque is strong and causes bending strain which competes with axial strain.…”

Section: Magnetic Field Induced Deformationmentioning

confidence: 99%

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Magnetic-field-induced bending and straining of Ni–Mn–Ga single crystal beams with high aspect ratios

et al. 2015

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a b s t r a c tSmall monocrystalline beams of the magnetic shape-memory alloy (MSMA) Ni-Mn-Ga, with a square 1Â1 mm 2 cross section and length between 2 and 10 mm, with the 10M martensite structure and all faces parallel to {100}, were subjected to rotating magnetic fields while being held at one end. The beams deform by both magnetic-field-induced straining (MFIS) and magnetic-torque-induced bending (MTIB), in directions parallel and perpendicular to the beam's longitudinal axis, respectively. With the field parallel to the beam axis, the beams were straight and short. Upon field rotation, the beam elongated and bent in the direction of the field. When the field reached 90°, the beam deflected rapidly and took a bent shape oriented in the opposite direction. Upon further field rotation, bending strain and axial strain decreased until the beam was short and straight again with the field at 180°. With an increase in beam aspect ratio, the bending component increases while the total axial strain remains constant. MTIB -a natural but so far neglected response of long MSMA samples exposed to a transversal magnetic fieldoccurs during switching of current linear (one-dimensional) actuators, thus causing friction losses, wear, and fatigue. However, MTIB provides the opportunity to actuate high aspect ratio MSMA continuously and smoothly in all directions (in three dimensions), thus mimicking slender biological actuating structures such as microorganism flagella tails and fins of fish, heart valves, leaves and petals of plants, and wings of birds or insects.

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Section: Magnetic Field Induced Deformationmentioning

confidence: 99%

“…Most literature of magnetic-field-induced deformation addresses linear, uniaxial magnetic-field-induced strain (MFIS). In contrast, Ganor et al [15] and Kanner et al [16] proposed propulsion mechanisms for remotely activated micro-robots in water and fluids. They suggested mechanisms based on shearing and kinking associated with twinning.…”

Section: Introductionmentioning

confidence: 99%

Magnetic-field-induced bending and straining of Ni–Mn–Ga single crystal beams with high aspect ratios

et al. 2015

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“…In particular, there have been a lot of development in the smart applications of Ni-Mn-Ga single crystals in the past few years (e.g. [52][53][54]). Also the works concerned with appearance of Type 1 and Type 2 interfaces in Ni-Mn-Ga thin films (e.g.…”

Section: Esomat 2015mentioning

confidence: 99%

Highly mobile interfaces in shape memory alloys

Seiner

2015

MATEC Web of Conferences

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Abstract. Macro-twin interfaces in single crystals of 10 M modulated Ni-Mn-Ga martensite have recently attracted a lot of attention due to the extraordinarily low twinning stress required to set them into motion; depending on the particular twinning mode, this stress can range between 0.05 and 1 MPa, and can be either strongly temperature dependent, or nearly temperature independent. The understanding to these effects is still not satisfactory, mainly due to the high complexity of these interfaces at the micro-scale (higher-order lamination) as well as at the atomistic scale (modulations of martensite). This paper brings a brief review of the recent experimental and theoretical achievements related to these highly mobile interfaces. The uniqueness of the behavior of 10 M martensite is shown by its comparison with other shape memory alloys with relatively low twinning stresses; then, this behavior is discussed in terms of its temperature dependence, strain rate dependence and the effect of the micromorphology of the interfaces.

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“…In the ternary phase diagram of Co-Ni-Al, the equilibrium phase is consist by β phase and γ phase. Thereinto, the β phase can be transform into twin martensite undergo martensitic phase transition when temperature cool down below martensitic phase transformation point [11,12]. The γ phase, which has excellent ductility, exist at the grain boundary can be greatly improved the brittleness of alloy [13,14].…”

Section: Introductionmentioning

confidence: 99%

Microstructure and Machine Properties of Co37+xNi34-xAl29(x=0,1,2,3) Ferromagnetic Shape Memory Alloys

Ju¹,

Chen²,

Liu³

2017

dtmse

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Abstract. In this paper, the microstructure, phase structure, hardness and micro-hardness of Co 37+x Ni 34-x Al 29 (x=0,1,2,3) alloys studied by optical micrograph, X-ray diffraction, hardness test and compressive test. The results show that the β phase and γ phase coexist within Co 37+x Ni 34-x Al 29 (x=0,1,2,3) alloys. The γ phase at the grain boundary became coarse with Co content increasing. Meanwhile, the grain size of alloy decreases with Co content increasing. The hardness of Co-Ni-Al alloy decrease first and then increase with Co content rising. The micro-hardness of γ and β phase in Co 38 Ni 33 Al 29 alloy is 454 HV and 713 HV, respectively.

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Ferromagnetic shape memory flapper for remotely actuated propulsion systems

Cited by 27 publications

References 28 publications

Magnetic-field-induced bending and straining of Ni–Mn–Ga single crystal beams with high aspect ratios

Magnetic-field-induced bending and straining of Ni–Mn–Ga single crystal beams with high aspect ratios

Highly mobile interfaces in shape memory alloys

Microstructure and Machine Properties of Co37+xNi34-xAl29(x=0,1,2,3) Ferromagnetic Shape Memory Alloys

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